H.M.S. PALLAS: HISTORICAL RECONSTRUCTION OF AN 18th-CENTURY
ROYAL NAVY FRIGATE
A Thesis
by
PETER ERIK FLYNN
Submitted to the Office of Graduate Studies of
Texas A&M University
in partial fulfillment of the requirements for the degree of
MASTER OF ARTS
May 2006
Major Subject: Anthropology
H.M.S. PALLAS: HISTORICAL RECONSTRUCTION OF AN 18th-CENTURY
ROYAL NAVY FRIGATE
A Thesis
by
PETER ERIK FLYNN
Submitted to the Office of Graduate Studies of
Texas A&M University
in partial fulfillment of the requirements for the degree of
MASTER OF ARTS
Approved by:
Chair of Committee,
Committee Members,
Head of Department,
Kevin J. Crisman
James C. Bradford
Felipe Vieira de Castro
David L. Carlson
May 2006
Major Subject: Anthropology
iii
ABSTRACT
HMS Pallas: Historical Reconstruction of an 18th-Century Royal Navy Frigate.
(May 2006)
Peter Erik Flynn, B.A., University of Manitoba
Chair of Advisory Committee: Dr. Kevin J. Crisman
A 1998 joint survey undertaken by the Institute of Nautical Archaeology and Portuguese
authorities located and identified the sunken remains of the Royal Navy frigate HMS Pallas
(1757-1783) off of the Azorean island of São Jorge. Physical remains are so limited as to suggest
that excavation would likely yield little new information. However, much documentary evidence
has been preserved in Admiralty archives.
Contemporary treatises about 18th-century British ship construction focus on glossaries
of terms, scantling lists and design theory, and include only short sections on frigates insofar as
they apply to those topics. They rarely address specific construction aspects. Most current works
address individual aspects of ship construction for the period, but provide little significant detail
about the frigate as a ship type. All of these works are useful and reliable, however none attempt
to combine the ship with the crew, or pursue the complete history of one ship.
As the flagship of a prototypical class, intended to address French superiority in cruiser
design, it is reasonable to expect that a history of Pallas would exist with some analysis of how
successfully these new frigates fulfilled the Royal Navy’s perceived need. However, to date
there has been no attempt to consolidate the evidence of her 26-year career. This study provides
a comprehensive history of a single ship from perceived need and conceived solution through
design and construction. The ship’s logbooks and additional primary sources made it possible to
iv
accurately document and analyze Pallas’ activities, maintenance, modifications, and ultimately
to draw conclusions about the overall effectiveness of the frigate type.
I began with basic background information to establish the perceived need for a new
frigate type, followed by an examination of the conceived design solution. A partial set of
admiralty drafts served as a foundation from which to develop a more complete set of
construction plans, a spar plan, and rigging plans. Comprehensive research into life aboard Royal
Navy warships of the period provided a social context within which to examine the service
history of Pallas. Finally, a review of the maintenance record and the events leading up to her
sinking enabled an informed assessment of how well HMS Pallas fulfilled the perceived need
for which she was developed.
v
For Sam
vi
ACKNOWLEDGEMENTS
I gratefully acknowledge the support of my committee chair, Dr. Kevin J. Crisman for his
encouragement and financial assistance, and Drs. James Bradford and Felipe Vieira de Castro for
serving on my thesis committee. I would like to express my gratitude for the additional funding
provided by the Institute of Nautical Archaeology. I would also like to thank the research staff
and librarians of the Public Record Office in London and the librarians at the National Maritime
Museum, Greenwich. Finally, I wish to express my thanks and appreciation to the Nautical
Archaeology Program faculty and staff.
vii
TABLE OF CONTENTS
Page
ABSTRACT ............................................................................................................................ iii
DEDICATION ........................................................................................................................ v
ACKNOWLEDGEMENTS .................................................................................................... vi
TABLE OF CONTENTS ....................................................................................................... vii
LIST OF FIGURES ................................................................................................................ x
LIST OF MAPS ...................................................................................................................... xiii
LIST OF TABLES .................................................................................................................. xvi
CHAPTER
I
INTRODUCTION.........................................................................................
1
II
HISTORICAL OVERVIEW .........................................................................
4
Geo-Political Context: Emergence of the Royal Navy in the 17th
Century .............................................................................................
The Royal Navy as a Tool of Empire...............................................
4
6
III
DEVELOPMENT OF THE 18th-CENTURY FRIGATE FORM ................. 10
British Cruiser Development............................................................
The Establishments...........................................................................
French Influence on Royal Navy Cruiser Development ..................
Establishment Reforms.....................................................................
The Slade Era ...................................................................................
The True Frigate Form .....................................................................
IV
11
14
15
17
18
19
CONSTRUCTION ............................................................................... 21
Hull Construction .............................................................................
A. Keel Assembly ...............................................................
B. Stem Assembly...............................................................
C. Sternpost Assembly ........................................................
D. Deadwood.......................................................................
E. Frames ............................................................................
F. Keelson...........................................................................
G. Internal Planking ............................................................
H. Deck Beams, Knees, Carlings, Ledges and Hooks.........
24
24
26
27
30
31
35
36
41
viii
CHAPTER
Page
I. External Planking ...........................................................
J. Bitts, Partners, Capstans and Mast Steps........................
K. Decking ..........................................................................
L. Hatches, Gratings, Ladder Ways and Scuttles................
M. Pillars or Stanchions .......................................................
N. Quarter Galleries ............................................................
O. Rudder and Tiller Assembly...........................................
P. Head................................................................................
Finishing and Fittings.......................................................................
A. Bulkheads .......................................................................
B. Magazine ........................................................................
C. Shot Lockers...................................................................
D. Ordnance ........................................................................
E. Pumps .............................................................................
F. Ground Tackle ................................................................
G. Navigation and Communication.....................................
H. Galley .............................................................................
I. Other Permanent Fixtures...............................................
J. Ballast.............................................................................
K. Ships’ Boats....................................................................
L. Hull Protection ...............................................................
Spar Plan and Rigging Plan..............................................................
A. Masts and Spars..............................................................
B. Standing Rigging............................................................
C. Running Rigging ............................................................
V
46
49
53
56
57
58
59
61
63
63
65
66
67
69
71
71
73
73
74
75
77
78
79
81
83
LIFE ABOARD AN 18TH-CENTURY ROYAL NAVY FRIGATE ............ 93
Entering the Service .........................................................................
Shipboard Hierarchy, Duties and Responsibilities ...........................
Pay and Benefits...............................................................................
Discipline and Punishment ...............................................................
Accommodations..............................................................................
Food..................................................................................................
Dress.................................................................................................
Health and Hygiene ..........................................................................
Leisure ..............................................................................................
93
94
101
102
103
105
106
108
110
VI
HMS PALLAS: SERVICE HISTORY........................................................... 113
VII
ARCHAEOLOGY OF PALLAS SITE .......................................................... 135
VIII
CONCLUSIONS ........................................................................................... 138
REFERENCES
.......................................................................................................... 141
ix
Page
APPENDIX A: FIGURES....................................................................................................... 149
APPENDIX B: MAPS ............................................................................................................ 185
APPENDIX C: HMS PALLAS HISTORICAL TIMELINE.................................................... 190
VITA ........................................................................................................................................ 215
x
LIST OF FIGURES
FIGURE
Page
1
Frigate believed to be Pallas. Painted by Charles Brooking, 1759 ............... 149
2
Frigate entering Portsmouth. Painted by Thomas Mitchell, 1780 ................. 149
3
Ship’s lines for frigate HMS Pallas .............................................................. 150
4
Keel and keelson assembly detail.................................................................. 151
5
Interior profile for frigate HMS Pallas ......................................................... 152
6
Various types of scarfs used in construction of Pallas.................................. 153
7
Detail of stem assembly ................................................................................ 154
8
Bow construction detail of frigate Pandora .................................................. 154
9
Stern construction detail of frigate Pandora. ................................................ 155
10
Stem boxing detail......................................................................................... 155
11
Interior construction detail for frigate HMS Pallas....................................... 156
12
Frame assembly detail ................................................................................... 157
13
Hawse pieces detail ....................................................................................... 157
14
Midship section detail frigate HMS Pallas ................................................... 158
15
Spirketting and quickwork detail................................................................... 159
16
Gun deck construction detail for frigate HMS Pallas ................................... 160
17
Lower deck construction detail for frigate HMS Pallas................................ 161
18
Fore and aft orlop construction detail for frigate HMS Pallas...................... 162
19
Quarterdeck and forecastle construction detail for frigate HMS Pallas........ 163
20
Detail of capstan ............................................................................................ 164
21
Wheel and tiller detail ................................................................................... 165
xi
FIGURE
Page
22
Contemporary engraving of gun founding process ....................................... 166
23
Gun carriage .................................................................................................. 167
24
Detail of gun tackle and operation from the late 18th century ....................... 167
25
Mid 18th-century chain-pump detail .............................................................. 168
26
Overhead view of chain-pump ...................................................................... 168
27
Contemporary engraving of anchor making process..................................... 169
28
Iron stove from HMS Dorsetshire,................................................................ 170
29
Copper sheathing on hull of Pandora ........................................................... 171
30
Spar plan for frigate HMS Pallas.................................................................. 172
31
Rigging plan detail for frigate HMS Pallas................................................... 173
32
Draft of 1745 Establishment, 44-gun ship showing spar details ................... 174
33
Watercolor of 50-gun ship HMS Lion showing rigging details .................... 174
34
The Isle of Man Action, 1760. Painted by Richard Wright........................... 175
35
Two British frigates off the African coast. The one on the left is probably
Pallas. Watercolor by Lt. Gabriel Bray......................................................... 175
36
Fishing from the anchor on board Pallas in Senegal Road. Watercolor Lt.
Gabriel Bray .................................................................................................. 176
37
Sail-maker ticketing hammocks on board Pallas. Watercolor by Lt.
Gabriel Bray .................................................................................................. 176
38
Wardroom leisure on board Pallas. Watercolor by Lt. Gabriel Bray............ 176
39
Marines mess on board Pallas. Watercolor by Lt. Gabriel Bray................... 176
40
Lower deck on board Pallas (note pump handle) Watercolor by Lt.
Gabriel Bray .................................................................................................. 176
41
Gun deck onboard Pallas. Watercolor by Lt. Gabriel Bray .......................... 177
42
Marine sentinel on board Pallas. Watercolor by Lt. Gabriel Bray................ 177
xii
FIGURE
Page
43
Fishing off a gun onboard Pallas. Watercolor by Lt. Gabriel Bray .............. 177
44
A Homeward-bound West India convoy September 1782 by Robert
Dodd, with the merchantman Lady Juliana in the foreground, in the tow
of the frigate Pallas. ...................................................................................... 178
45
Site plan of Pallas Wreck, Calheta harbor, São Jorge, Azores ..................... 179
46
One of two concreted 6-pound cannon in situ at the site............................... 179
47
Drawings of the 6-pound cannon found at the site........................................ 180
48
Concreted cast iron ingots from ballast ......................................................... 180
49
Copper nails and a possible wedge from a forelock bolt found at the site .... 181
50
Copper sheathing found in test trench at the site........................................... 181
51
Lead sounding weight (CAL/ 00-191) found at the site................................ 182
52
Lead sounding weight (CAL/ 00-12) found at the site.................................. 182
53
Lead musket shot found at the site ................................................................ 183
54
Iron shot found at the site .............................................................................. 183
55
Four types of pottery found in test trench at the site ..................................... 184
56
A variety of copper coins found at the site.................................................... 184
xiii
LIST OF MAPS
MAP
Page
1
The Central Azores and the Island of Sao Jorge in the North Atlantic. ........ 185
2
British home waters and western approaches................................................ 186
3
Theatre of operations: July 1760 – Dec. 1763 and Dec. 1771 – Mar. 1773. . 187
4
Theatre of operations: Jan. – Apr. 1775, Dec. 1775 – May 1776
and Mar. – June 1777. ................................................................................... 188
5
Theatre of operations: May – July 1775, June – Oct. 1776,
July – Dec. 1777 and Aug. – Jan. 1783. ........................................................ 189
xiv
LIST OF TABLES
TABLE
Page
1
Depicting the progression of standardization in Royal Navy Cruisers
through the Establishment Period. ................................................................ 13
2
Depicting the standard watch schedule aboard Royal Navy Warships. ........ 100
3
Showing the list of clothing provided to Royal Navy seaman and boys by
the Marine Society......................................................................................... 107
1
CHAPTER I
INTRODUCTION
On January 26, 1783, a small British convoy of eight military transports sailed out of
Halifax harbor bound for England. 1 It was accompanied by the captured French 64-gun man-ofwar Le Caton, and escorted by the veteran 36-gun frigate HMS Pallas. 21In what had begun
nearly eight years earlier as a seemingly minor colonial uprising, Britain found itself isolated and
at war, not only with the fledgling United States, but with France, Spain and Holland as well.
The war in America was lost but not officially over and privateers continued to prowl the
Atlantic with the hope of snatching up one last rich prize. 3 Captain Christopher Parker of Pallas
had received routine orders to escort the convoy across the North Atlantic to England. First
launched in 1757, Pallas was long past her prime despite numerous upgrades and refits (Fig. 1
and 2). It is almost certain that this would have been her last voyage had she reached England. 4
Le Caton probably sailed with little more than a prize crew—the absolute minimum crewmen
required to sail the ship—and would have been little help in defending the convoy. Nevertheless,
the profiles of a 64-gun capital ship and a frigate seen from a distance would have been more
than enough to deter all but the most daring of privateers.
Numerous leaks appeared in Pallas’ hull soon after sailing. On January 31st a storm
scattered the convoy, heavy seas worsened the leaks, and by February 5th, despite round the
clock pumping by the crew, Pallas was shipping six inches (15.2 cm.) of water per hour and
eight feet (2.44 m.) of water had accumulated in the hold. 5 Guns, shot and heavy stores were
thrown overboard to ease the strain and lighten the ship. On the advice of the carpenter and after
consulting his officers, Captain Parker decided to make for the nearest port, the city of Horta on
This thesis will conform to the style and format of The American Neptune.
2
the island of Fayal in Portugal’s Azores Islands (Map 1). They made landfall off Fayal on
February 10th but were driven back out to sea by another violent storm before Pallas could be
brought to anchor. The crew was nearing exhaustion when the storm abated on the following
morning. But while the sea conditions had changed they had not improved. Pallas’ crewmen
found themselves becalmed and unable to make any significant headway. The second storm had
further stressed the hull, and despite the dead calm, the pumps were no longer able to keep up
with the rising water in the hold. Driven eastward beyond Fayal by the storm, Parker decided to
seek any port of opportunity. On the morning of February 12th luck returned long enough to slip
the stricken frigate through a gauntlet of surrounding rocks and run her aground near the town of
Calheta on the island of São Jorge. Examination of the hull by the ship’s carpenter confirmed
that the garboard strake and the rabbet of the keel were so worm eaten as to be almost nonexistent. 6 The fortnight from February 12th to the 24th was spent removing what provisions,
stores and fittings could be salvaged and on February 24th the hulk of HMS Pallas was burnt by
her crew. 7
This study began with an archaeological examination of the scant remains of HMS
Pallas. The subsequent review of existing primary sources pertaining to her construction and
service history—most of which are preserved in the Public Record Office and The National
Maritime Museum in London—has contributed significantly to our understanding of the frigate
type and its application by the Royal Navy. Furthermore, this study has conclusively established
Pallas’ role as a prototype for all subsequent Royal Navy frigate designs and as a developmental
test bed for numerous innovations introduced to Royal Navy warships during the late 18th
century. Finally, a brief overview of the conditions and organization aboard Royal Navy
warships will give substance and personality to a period of the Royal Navy’s history which is
often neglected in favor of the more glamorous Napoleonic era.
Notes
1
The Royal Navy did not officially apply the prefix HMS to its warships until the 1790’s however for the
purpose of clarity HMS will be applied on the first occasion each Royal Navy warship is named.
2
The 64-gun Le Caton was a prize taken at the Battle of the Saintes the previous April.
3
Miller, Sea of Glory, 520. Britain officially proclaimed an end to hostilities with the United States on
February 4, 1783. The 64-gun Le Caton was a prize taken at the Battle of the Saintes the previous April.
4
TNA: PRO ADM 1/5322. The carpenter’s testimony at Captain Parker’s court martial makes it clear that
the Pallas was too weak to be ‘heaved down’ for maintenance while at Halifax.
5
Ibid., Unfortunately, the ship’s logs for the last six months of Pallas’ career have gone missing. However,
the official transcript of Captain Parker’s court martial for losing Pallas do provide a good description of
the final voyage.
6
Ibid., Again, the carpenter’s testimony at Captain Parker’s courts martial made it clear that Pallas had
been found too weak to careen at Halifax prior to her final voyage.
7
Ibid., Captain Parker’s letter to the Admiralty reporting the loss of Pallas.
4
CHAPTER II
HISTORICAL OVERVIEW
Geo-Political Context: Emergence of the Royal Navy in the 17th Century
The role of England in Europe’s social, political and economic development can be
largely attributed to its geographic location. Traditionally England has relied upon its position—
an island nation separated from the European mainland—for a defensive advantage. The English
Channel has provided the inhabitants of the British Isles with a natural barrier against all but the
most determined invaders. As economic conditions improved throughout western Europe during
the 15th, 16th and 17th centuries, English channel ports increasingly exploited their position as
natural trade centers and trans-shipping points for goods passing between the Mediterranean,
France and the newly developing markets in the Lowlands and the Baltic. Furthermore, England
was ideally situated to control the passage of shipping through the narrow Channel and
consequently in a position to exert considerable political and economic influence upon
continental Europe. 1 It was during this period that England first embraced naval supremacy both
for defense and as a tool of foreign policy.
The period from 1650-1815 was one of intense imperial rivalry between the western
European powers. Economic and colonial disputes, dynastic conflict, and revolution all
contributed to an era of almost continuous tension and conflict which stimulated military and
naval development, and led to unprecedented shipbuilding programs.
Although Spain was the dominant power at the beginning of the 17th century, the second
half of the century witnessed the precipitous decline of Spanish influence; its navy fell into a
state of complacent decay, and its ability to project political influence was consequently
diminished. 2 As Spanish fortunes waned, those of Holland expanded to fill the growing void.
5
Dutch commercial and colonial success increasingly attracted the jealous attention of both
France and England. 3 Holland’s economic strength derived primarily from commercial shipping
(by mid-century the majority of European goods were shipped in Dutch bottoms) and from its
dominance of far-east trade. However, independence from Spain in 1648 left Holland exposed to
predations by both France and England. Crippling trade restrictions and high-handed treatment
of Dutch shipping by the English in the North Sea and the Channel (culminating in the
Navigation Act of 1651) led to open defiance by the Dutch. The three Anglo-Dutch wars during
the third quarter of the 17th century (First Anglo-Dutch War, 1652 to 1654; Second Anglo-Dutch
War, 1664 to 1667; Third Anglo-Dutch War, 1672 to 1674), although militarily largely
inconclusive, essentially broke the Dutch monopolies on commercial shipping and far-eastern
trade. With the Dutch colonial empire effectively dismantled, England’s only remaining serious
rival was France.
The second half of the 17th century had also witnessed the emergence of French sea
power. However, the continental ambitions of Louis XIV often meant that the needs of the army
superceded those of the navy. Consequently the French Navy rarely had the money to maintain
more than a portion of its fleet and generally elected to pursue a naval policy of regional
superiority and commerce raiding. 4
The naval battles of the Anglo-Dutch wars were typically fought within sight of land;
crews and vessels rarely remained at sea for more than a few days. The Royal Navy’s primary
function remained the protection of the British Isles against foreign aggression. However
England’s growing colonial interests compelled the navy to accept much broader responsibilities.
It was increasingly called upon to defend overseas colonies, to enforce imperial regulations, and,
most importantly, to protect merchant shipping throughout the growing empire from the
predation of trading rivals, political enemies and pirates. By the beginning of the 18th century the
6
Royal Navy’s influence had expanded into the Mediterranean. England played an active role in
the War of Spanish Succession 1702-1713 and it was there that the Royal Navy was first
employed as a strategic weapon, raiding shore installations and supporting the army’s campaigns
on the European mainland. England also gained a permanent strategic position in the
Mediterranean by seizing the vital ports of Gibraltar and Port Mahon and in doing so gained
control of maritime traffic between the Mediterranean and the Atlantic. 5 The War of Jenkins Ear
and the War of Austrian Succession in 1739-1748 required that the Royal Navy operate for
extended periods in the Caribbean. The Seven Years’ War 1756-1763, which ranged from
Canada to India was the world’s first truly global conflict and Britain’s ultimate victory
established Royal Navy supremacy for years to come. 6
The Royal Navy as a Tool of Empire
It was from the Anglo-Dutch wars that the Royal Navy truly emerged as a cohesive,
homogenous entity capable of projecting global influence. This period witnessed the
development of formalized tactics, standardized ship design, a recognizable strategic doctrine,
and the foundations of a permanent naval administration.
Shipbuilding technology had progressed considerably during the previous centuries, but
naval tactics had not. Prior to the 16th century naval battles were little more than infantry battles
at sea with ships being employed to carry infantry into combat. Purpose-built state-owned
warships were rare; in time of war, merchant vessels were conscripted or hired by the state and
hastily refitted for military service. 7 Fleet formations typically entered battle in line abreast or
echelon formations, but once engaged battles degenerated into clusters of individual duels with
ships seeking out opponents of comparable size, or several smaller ships engaging a single larger
one. Long range weapons such as catapults, and later cannon, were employed only until the
7
opposing vessel could be grappled and boarded. Early cannon were primarily used to destroy
rigging, clear enemy decks of defenders prior to boarding. 8 Ship design of the period reflected
this form of warfare. High fore and aft castles were incorporated to gain both a height advantage
and provided a secure keep from which to engage enemy boarders.
It was not until the introduction of the smaller, more agile, English race-built galleons of
the late 16th century that ships began to be viewed as pure gun platforms. The success of these
types against the much larger ships of the Spanish Armada in 1588 clearly demonstrated the
superiority of heavily armed warships that were capable of battering enemy ships into
submission from a distance. 9
During the 1630’s Charles I established England’s first permanent navy. By levying
‘ship-money,’ from the counties he was able to build, and maintain a small purpose-built fleet of
warships year round. This also enabled the development of a professional cadre of officers and
sailors. Furthermore, this marked the beginning of English naval influence upon the balance of
power in Western Europe. 10 England’s Parliamentarian government of the 1650’s expanded
upon Charles’ naval program, increasing naval spending and initiating substantial new
shipbuilding projects. Permanent dockyards and logistical facilities had been established by
1600, but it was the Commonwealth government after 1649 that was largely responsible for
establishing the foundations of the navy’s permanent professional administrative machinery,
command structure, and extensive shore facilities that would eventually support English naval
operations on a global scale. 11
Improvements in guns and gunnery throughout the 17th century facilitated a fundamental
change in naval doctrine. Tactical requirements shifted from crew capacity and defense to
maneuverability and gun-power. The high defensive works were cut down or completely
removed, and a large portion of the personnel was re-allocated as gun crews. Predictably during
8
this period warships grew in size and tonnage as more and larger guns were introduced; the
largest carrying up to 100 guns on three gun decks. 12
Almost exclusively naval conflicts, the Anglo-Dutch wars were the setting for some of
the largest fleet engagements in history and resulted in fundamental changes in naval tactics and,
consequently, ship design. In 1653, following the first Anglo-Dutch War, English Admiral
Robert Blake introduced his Fighting Instructions in an attempt to impose order upon the
disorganized melees that had, up until then, characterized naval warfare. In this milestone of
naval doctrine he outlined the use of a rigid line-of-battle that revolutionized naval tactics and
ultimately ship design. He proposed that ships enter battle in line-ahead formation so as to
minimize exposure of the vulnerable bow and stern, and to maximize the broadside firepower of
all of the ships in the formation. Only as strong as its weakest link, a line-ahead formation
increased the interdependency of the ships within the formation, thereby dictating the need for
greater homogeneity of construction. Vessels exhibiting similar sailing qualities were better able
to maintain station within the formation and thus not compromise the integrity of the unit as a
whole. 13
As a direct result of Blake’s innovations, in 1706, the Royal Navy instituted the first
Establishment system in an attempt to standardize warship construction. A system of ship ratings
was introduced based on tonnage and number of guns carried. For each rating the Establishment
defined a list of scantlings or basic dimensions to be observed by shipwrights. The line of battle
was made up of first-, second- and third-rate ships of between 70 and 100 guns. Cruisers and
small two-decked ships–fourth to sixth-rates–were no longer deemed suitable to stand in the
line-of-battle and were assigned duties for which they were better suited. 14
Finally, this period witnessed the emergence of a recognizable and consistent strategic
doctrine. Buttressing its continental allies with subsidies allowed England to sap the military
9
resources of its enemies. With little need for a land army England was able to consolidate naval
superiority. A policy emerged of blockading enemy fleets within their ports, attacking maritime
commerce, and seizing undefended colonial possessions abroad. 15
In little more than 100 years, naval warfare evolved from disorganized regional scuffles
fought by part-time navies, to a means of projecting economic and political policy around the
globe. This change in the use of naval power demanded a new kind of warship. While the battle
fleet remained the core of the Navy, emphasis had shifted. The new requirement was for a
cruiser capable of operating independently; capacious, rugged and weatherly enough to remain at
sea for long periods; a ship more economical to build and operate than a ship-of-the-line yet
powerful enough protect itself and project authority.
Notes
1
McKee, “Influence of British Naval Strategy”, 226.
Mahan, Infuence of Sea Power, 94.
3
Ibid., 97-8.
4
Ibid., 93-5.
5
Ibid., 219-20.
6
Howarth Sovereign of the Seas, 208-9.
7
Notable 16th and 17th-century exceptions include the ships Grace Dieu, Mary Rose, Sovereign of the
Seas, and Vasa.
8
Perrin, Boeteler’s Dialogues, 296-8
9
McKee, “Influence of British Naval Strategy”, 227-32.
10
Wheeler, Making of a World Power, 35-7.
11
ibid, 38-46.
12
Wheeler, Making of a World Power, 36, and Lavery, Ship of the Line vol. 1, 22-3.
13
McKee, “Influence of British Naval Strategy”, 234, Wheeler, Making of a World Power, 48, Tunstall,
Naval Warfare, 17-21, and Lavery, Ship of the Line vol. 1, 22-27.
14
McKee, “Influence of British Naval Strategy”, 234 and Gardiner, Line of Battle, 17.
15
Mahan, Mahan on Naval Warfare, 142-43.
2
10
CHAPTER III
DEVELOPMENT OF THE 18TH-CENTURY FRIGATE FORM
The origin of the 18th century frigate is a broad, subjective and, at times, contentious
topic. The most common arguments focus on two questions: what constitutes a ‘true frigate,’ and
where did the concept originate? Because the primary focus of this study is a particular frigate,
HMS Pallas, the evolution of the frigate as a ship type will be examined only to the extent
necessary to establish a clear historical and developmental lineage.
To most, the word ‘frigate’ conjures images of great battles between massive wooden
warships, yardarm to yardarm, blazing away with row upon row of cannon. The term is often
given incorrectly to describe any large wooden warship from the period 1650-1850. It is
imperative to correct this misnomer. The origins of the word can be found in the Greek
aphraktos and later in the Latin form fragata. The term frigate to identify a type or class of ship
has been used by mariners and navies alike for thousands of years. For most of this period the
term was used in general way to identify a small vessel, long and slender, propelled by one or
more banks of oars. 1 Unlike larger galleys, they were not suited for warfare and served
primarily as light, fast dispatch vessels. Not until the 17th century is a noticeable change evident
in the form and use of the ‘frigate’ type. Early in that century shipwrights at the French port of
Dunkirk began to build a small warship that combined the agility of the oared galley with the
deep round hull and broadside firepower of the northern European fighting ship. 2
In his treatise on French frigates, Jean Boudriot has compiled a list of dictionary
definitions for the term ‘frigate’ from the period 1643-1847. Although they differ greatly and
evolved as time passed, they include these qualities and characteristics in common: a small,
11
lightly framed warship, ship-rigged, designed to be propelled by either sail or sweeps, built long
and low in the water so as to be a fast and agile sailor, and usually armed on a single deck. 3
For the first century of this period, frigates were not viewed as ‘cruisers.’ They typically
worked close to shore performing dispatch or scouting duties. They were maneuverable under
sail, and the addition of sweeps enabled them to work against light currents in the mouths of
rivers and up estuaries, and the ability to bring broadside guns to bear without the use of a
spring. 4 Britain’s acquisition of a global colonial empire imposed greater demands on the Royal
Navy, increasing the need for an effective yet economical vessel to help administer and police
overseas possessions exert naval influence, act as advanced scout and pass signals for the battle
fleet, carry dispatches, gather intelligence, interdict enemy maritime commerce, perform escort
duty and suppress piracy and privateers. Such duties called for a swift warship, small yet
powerful, capable of operating independently and remaining at sea for long periods. 5
British Cruiser Development
At the beginning of the 18th century the Royal Navy employed a vast variety of 5th and
6th-rate ships differing widely in design, layout and armament. It continued to rely upon small
two-deckers, single-deck 6th-rates and assorted smaller vessels to protect commerce. Small, one
and a half decked 5th-rates were not considered to be an acceptable solution and were
discontinued following the 1713 Peace of Utrecht. Subsequently no warship types existed
between the two-deck, 40-gun ships and single-deck, 20 and 24-gun ships, usually referred to as
sloops-of-war, until the Admiralty began experimenting with captured French types in the
middle of the century. 6
The initial Establishment of 1706-1718 attempted to standardize the dimensions of
larger warships and establish some degree of uniformity within the Royal Navy’s line of battle
12
(Table 1). However, Establishments did not dictate design until after 1745. Shipyard surveyors
were restricted in dimension and scantling but they were free to alter ships’ lines and styling as
long as the finished product was within the Establishment parameters. Furthermore, proposed
designs of smaller ships were subject to far fewer design constraints than those of their larger
counterparts. 7 The smallest ships included in the 1706-1718 Establishment were 40-gun, twodecked, 5th-rates. These were to be 118 feet (40 m.) long on the lower deck, 32 feet (9.7 m.) in
beam, 531 tons, and crewed by 130 to 190 men. 8 There were to be eighteen 9-pound guns on the
gun deck, twenty 6-pound guns on the upper deck and four 4-pound guns on the quarterdeck. 9
Smaller 32-gun 5th-rates were not built to an Establishment of dimensions but were
beginning to show some degree of uniformity. Ships of this class, built prior to the 1706
Establishment, were an eclectic mix ranging from 102 to 110 feet (31.1 to 33.5 m.) long on the
lower deck, 24 to 30 feet (7.3 to 9.1 m.) in beam, 350 to 390 tons, and were crewed by 100 to
145 men. The guns were arranged with four 9-pound guns on the gun deck, twenty to twenty-two
6-pound guns on the upper deck and four to six 4-pound guns on the quarterdeck. Those built
after the 1706 Establishment were 108 to 110 feet (32.9 to 33.5 m.) long, 29 feet (8.8 m.) in
beam, 416 to 423 tons, and carried 100 to 145 crewmen. The guns were arranged with either four
9-pound or eight 12-pound guns on the gun deck, twenty-two 6-pound guns on the upper deck
and six 4-pound guns on the quarterdeck. 10 Like the smaller 5th-rates, the 6th-rates of the early
Establishment period were not built to an Establishment of dimensions but were also beginning
to show a tendency towards uniformity. Ships of this class built prior to the 1706 Establishment
ranged from 92 to 98 feet (28 to 29.9 m.) long on the gun deck, 24 to 26 feet (7.3 to 7.9 m.) in
beam, 240 to 270 tons, and were crewed by 85 to 115 men. The main battery of twenty 6-pound
guns was mounted on the single gun deck with an additional four 4-pound guns mounted on the
quarterdeck of the 24-gun ships only. 11 Those built after the 1706 Establishment were 94 to 95
13
feet (28.6 to 28.9 m.) long, 25 to 26 feet (7.6 to 7.9 m.) in beam, 260 to 280 tons, and carried 85
to 115 crewmen. Gun weight and arrangement did not significantly change during this period. 12
Table1: Depicting the progression of standardization in Royal Navy Cruisers through the
Establishment Period. Compiled from Lyon, Sailing Navy List, 36-7, 47-52.
Length
Beam
Burthen
(Tons)
Crew*
Guns
LD/GD
Guns
UD
QD/F
C
1706 Establishment
5th-Rate, 40 guns
118’
32’
531
190
18 x 9
20 x 6
4x6
1706 Establishment
5th-Rate 32 guns†‡
108-110’
29’ 6” 29’ 8”
416 57/94 –
423 62/94
145
4 x 9‡
20 x 6
6x4
25’ 0” 26’ 6 1/2 ”
253 55/94 –
282 5/94
115
-
90’ 3
1706 Establishment
3/4”-95’
6th-Rate, 20-24 guns†
10”
20 x 6 0-4 x 6
1719 Establishment
5th-Rate, 40 guns
124’
33’ 2”
594 55/94
250
20 x 12
20 x 6
-
1719 Establishment
6th-Rate 20 guns
106’
28’ 4”
374 49/94
140
-
20 x 6
-
1733 Establishment
5th-Rate 40-44 guns
124’
35’ 8”
678
250
20 x 12
20 x 9
4x6
1733 Establishment
6th-Rate 20-guns
106’
30’ 6”
442 4/94
150
-
20 x 9
-
1741 Establishment
5th-Rate 44 guns
126’
36’
706 36/94
250
20 x 18
20 x 9
4x6
1741 Establishment
6th-Rate 24 guns
112’
32’
498 34/94
160
2x9
20 x 9
2x3
Notes:
*Maximum wartime figures given. Crew and guns were considerably reduced during
peacetime. Pure galley’s and foreign-built prizes omitted. Only British built cruiser types are
included.
†Not built to an Establishment
‡Mermaid and Dolphin were built as 36-gun ships armed GD 8 x 12, UD 22 x 6, QD 6 x 4.
After 1716 all were re-armed GD 8 x 9, UD 20 x 6, QD 2 x 4. 13
14
The Establishments
The Treaty of Utrecht in 1713 concluded almost sixty years of continuous war between
the major European powers, at the end of which Britain had become the dominant naval power.
Although French and Spanish designs were generally accepted as more advanced, the Royal
Navy established superiority in construction, management, logistics, and quality of crew. 14
However, the long peace that followed saw a dramatic decline in spending and stagnation in ship
development within the Royal Navy. The 1719 Establishment fixed the dimensions of all rated
warships down to 20-gun 6th-rates, but little effort was made to improve upon pre-existing
cruiser designs. All of the guns were mounted on the weather deck and a complete bank of oar
ports remained on the lower deck for rowing. 15 Ships continued to be designed by master
shipwrights of individual yards who retained some freedom of design as long as they worked
within the parameters fixed by the Establishment. 16
Myopic conservatism among the Navy Board continued to obstruct innovation in ship
design and resisted efforts to address existing design deficiencies. 17 The Navy Board was
conscious, perhaps overly so, that even small increases in ship size amounted to substantial
increases in construction and maintenance costs. Consequently, the 1733 and 1741
Establishments that followed were little more than conservative revisions of the scantlings and
dimensions fixed by the 1719 Establishment. These were primarily increases in size and strength
to accommodate increased battery size and to compensate for lost performance resulting from
added gun weight. 18 Nevertheless, throughout the Establishment period (1719-1745) the fleet
gradually attained a greater degree of standardization as older ships were retired, broken up and
replaced or rebuilt. 19
During the Establishment period, ship design and spending were the prerogative of the
Navy Board, a permanent bureaucracy of naval officers, that ran the dockyards and was
15
responsible for ship design, construction, maintenance, victualling and day-to-day operations of
the fleet. The Admiralty, a council of temporary, politically appointed members, petitioned
parliament for funding and dictated policy but exerted little influence over how the Navy Board
administered the Navy. 20 The conservatism of the Royal Navy during this period was largely due
to Sir Jacob Ackworth, surveyor of the Navy since 1715, who harbored a firm belief in the
superiority of the ships of the late 17th century. 21
The outbreak of war with Spain again in 1739 (The War of Jenkin’s Ear) did little to
change existing attitudes. Spain was not in a position to effectively pursue a guerre de course
(war on trade) and the Royal Navy saw no need to invest money and resources improving cruiser
designs. However, French entry into the war in 1740 (The War of Austrian Succession)
witnessed a dramatic increase in losses of British merchant shipping. The Royal Navy’s 20-gun
6th-rates found themselves increasingly outclassed not only by their French counterparts but by
French privateers as well. 22 Consequently, the Admiralty began to seriously examine French
cruiser design.
French Influence on Royal Navy Cruiser Development
Early French cruiser designs were either clumsy two-deckers similar to their British
equivalents or under-gunned single-deckers with their battery dangerously close to the waterline.
Like the British, French naval shipwrights sought to bring together the best qualities of both
designs into a successful new cruiser design. Their solution undertaken in the early 1740’s, was
to move the lower deck down to, or below, the waterline, reduce the headroom on the lower deck
to about four feet (1.2 m.), and place all of the battery on the upper deck. This reduced topside
profile while retaining sufficient freeboard to run out the main battery in all weather
conditions. 23 Blaise Ollivier, son of a master shipwright, gained considerable prestige as an
16
innovator in ship design throughout the early part of the 18th century. He was made Master
Shipwright at Brest in 1736 where he distinguished himself as France’s preeminent shipwright
until his death ten years later. Ollivier’s Medée, built in 1741, is widely credited as the first
genuine frigate but there remains little real evidence that this was in fact the case. Many French
privateers of the day exhibited similar design characteristics. 24 Medée featured two decks, the
upper strengthened to bear the weight of the main battery of twenty-six 8-pound guns, the lower
with reduced headroom and no ports was devoted entirely to berthing and storage. Ollivier’s
reputation within the French Navy promoted eventual acceptance of the type and it was the first
such design widely accepted for service in the French Navy. It was not the first French vessel to
incorporate these design features, but it became the prototype for a class that eventually
numbered 30 or more vessels. Ironically, Medée was also the first such vessel captured by the
British but for some reason she was not taken into Royal Navy service. It is unclear why the
Royal Navy failed to capitalize or, at the very least, carry out a detailed survey of this prize.
Renommée, a near-sister of Medée, was highly regarded and immediately taken into Royal Navy
service after she capture in 1747. During the same period Ollivier’s contemporary, Jacques-Luc
Coulomb undertook the parallel development of a smaller 20-gun version based upon the same
design concepts. His Panthère, built in 1744, was also taken into Royal Navy service when
captured in 1745. 25 While the Royal Navy greatly admired the design and sailing qualities of
these prizes, little effort was devoted to reproducing them. A year later, the French 40-gun
Embuscade, the largest frigate-built prize of her day, was renamed Ambuscade and taken into
Royal Navy service. The French 8-pound guns were replaced with British 12-pound guns and the
heavier broadside seems to have been the decisive factor in British cruiser development. Until
this point, the Royal Navy had been unwilling to commit resources to the development of what
was perceived to be an under-gunned warship. 26
17
Establishment Reforms
As previously stated, the Navy Board controlled the budget and, because of costs
involved, was disinclined to increase ship size or to impose any radical design changes. In 1744,
the Admiralty began to become involved in Navy Board business. Admiral George Anson, a sea
admiral with considerable influence, was appointed to the Admiralty. He in turn immediately
appointed Sir John Norris to investigate a complete revision of the Establishment system.
Dockyards were instructed to watch for ships with good sailing characteristics for evaluation and
technical analysis, and all surveys of French prizes were to be forwarded by the Navy Board for
Admiralty inspection. Eventually all proposed designs had to be authorized by the Admiralty
before being forwarded to the Navy Board for construction. In response to increasing demands
by its sea-officers, the Admiralty ordered a new, improved Establishment for 1745. What the
Navy Board drew up was once again little more than a conservative increase in dimensions of
the larger ships of the line. Upon returning from blockading the French coast during the winter
of 1747, Anson complained of a lack of quality cruisers. In fact, the upgraded French prize
Ambuscade had been his best ship. He required an improved all-weather cruiser to institute his
new strategy of blockading of French ports year round. Finally, in April 1747, displeased with
Navy Board conservatism, and in an unprecedented break with tradition, the Admiralty ordered a
draught of the captured 26-gun French privateer Tygre. A St. Malo privateer of French frigate
design, Tygre was not purchased by the Royal Navy due to poor quality construction, but it had
exhibited excellent performance and sailing characteristics. The Admiralty ordered two copies
built. Unicorn and Lyme were to be constructed “to the lines of the Tygre French privateer.” It is
interesting to note that some comparative experimentation is demonstrated by the fact that Lyme
was designed with a round bow and Unicorn with a beakhead bow; one in the French tradition
and one in the English tradition. 27
18
A second generation of Tygre-based vessels, Lowestoffe and Tartar, followed in 1755, to be
constructed “to the draught of the Lyme with such alterations as may tend to the better
accommodation of men and carrying of guns.” 28 Comparative experimentation is once again
evident in that Tartar was designed with a round bow and Lowestoffe was designed with a
beakhead.
The third generation of four vessels was ordered in 1756-7, to be constructed “by the
draught of the Tartar with such alterations withinboard as shall be judged necessary.” 29 The
success of these vessels is demonstrated by the fact that eighteen third generation Unicorn-class
frigates were eventually built. All were increased to 28 guns with the addition of four 3-pound
guns in September 1756 and were further furnished with twelve ½-pound swivel guns in
November of that same year. 30 All of the generations up to this point were in some way based
upon French designs and all carried main batteries of 9-pound guns.
The Slade Era
Sir Thomas Slade was born in 1703 or 1704 into a family with a long tradition of
shipbuilding. He worked his way up in the profession gaining prestige first as a timber broker,
then as Shipwright’s Assistant at Harwich and Woolwich. His talent and connections led to his
appointment as the Master Shipwright at Deptford where he was responsible for the design and
construction of five ships between 1749 and 1755. 31 In 1755, he and William Bately, the Deputy
Surveyor at Plymouth, were appointed joint Surveyors of the Navy to replace the retired Sir
Joseph Allen. Slade retained this title until his retirement in 1770, becoming the preeminent
Royal Navy ship designer and builder of his day. His Southampton-class frigates introduced in
1756 are generally regarded as the first ‘genuine frigates’ designed and built in England. They
were based on the same design principles as their French precursors but were completely original
19
designs. They were considerably larger than the Unicorn-class ships and carried a heavier main
battery of twenty-six 12-pound guns on their upper deck. The following year, 1757, Slade
introduced the Pallas class frigates, which were simply enlarged versions of the Southampton
design. When launched Pallas-class frigates were regarded as the best fighting cruisers fielded
by any navy of their day. 32
The True Frigate Form
It is clear that the first ‘true frigate’ of the Royal Navy was derived from a French design
that was ultimately perfected by the British. Whether French or English, the sailing frigate was
hereafter defined as a two-decked, square rigged warship with three masts (the traditional ship
rig), having the main battery on the upper deck and the secondary battery divided between the
quarterdeck and forecastle. It was self sufficient and capable of staying at sea for long periods
while carrying out a variety of duties. It was large enough to warrant a rating but generally not
large enough to stand in the line of battle. 33
Notes
1
Boudriot, French Frigates, 12.
Anderson, “Ancestry”, 158.
3
Ollivier, Remarks, 13-14.
4
Gardiner, Line of Battle, 30 and Falconer, Universal Dictionary, 274. Springs were only employed while
at anchor. A cable was passed from capstan or winch, through a stern port and forward to the anchor cable
allowing the stern of the ship to be pulled towards the anchor.
5
Henderson, Frigates, 3, Price, Eyes of the Fleet, 25 and Mckee, “Influence of British Naval Strategy,”
234. It is interesting to note that this new workman-like attitude was paralleled by the reduction and/or
elimination of decorative appointments and scrollwork. Royal Navy warships acquired a more utilitarian,
functional appearance.
6
Lyon, Sailing Navy List, 33.
7
Ibid., 39.
8
Mckee, “Influence of British Naval Strategy,” 234. All warship tonnages given in burthen tons or rough
cargo capacity not displacement tonnage.
9
Lyon, Sailing Navy List, 36. Note that warships frequently carried more guns than their rating during
wartime and fewer than their rating in peacetime. After 1716 the configuration was changed to twenty 12pound guns on the gun deck and twenty 6-pound guns on the upper deck with no guns on the quarter deck.
2
20
10
ibid., 26-7, 36, It is interesting to note here that even though dimensions had not yet been established,
the standard crew for each ship rating had. No matter how much ship size varied, all small 5th-rate, 32’s
carried 100 to 145 men, all 6th-rate 24’s carried 85 to 115 men, etc.
11
Ibid., 27-9.
12
Ibid., 36-7.
13
Ibid., 36.
14
McKee, “Influence of British Naval Strategy,” 234.
15
Gardiner, First Frigates, 7.
16
Ibid., 8.
17
Lyon, Sailing Navy List, 36.
18
Ibid., 39.
19
Lavery, “Rebuilding of British Warships,” 113-27. Provides a complete discussion of Royal Navy
policy and practice for rebuilding warships 1690-1740.
20
Baugh (ed.), Naval Administration, 1-8, Rodger, Admiralty, 53-67 and Gardiner, First Frigates, 9.
21
Lyon, Sailing Navy List, 39.
22
Gardiner, First Frigates, 9.
23
Ibid., 10.
24
Ibid., 11-12.
25
Ibid., 10-12.
26
Gardiner, First Frigates, 11. Ambuscade became the forerunner to the British 32 and 36-gun cruisers.
27
Gardiner, “First English Frigates,” 164, Gardiner, “Frigate Designs,” 51-2, Gardiner, Line of Battle, 37
and Gardiner, First Frigates, 9-16.
28
Gardiner, First Frigates, 16.
29
Ibid., 16.
30
Ibid., 16.
31
Jones, “Sir Thomas Slade,” 224-5. Weymouth 3rd-rate, Speedwell Brig, Dorset Bomb, Squirrel 6th-rate,
and Medway 3rd-rate.
32
Ibid., 224-6.
33
In small squadron engagements, several frigates might form up in a line with a single 3rd or 4th-rate
against a comparable force.
21
CHAPTER IV
CONSTRUCTION
A variety of sources are available pertaining to the hull design and construction of 18thcentury Royal Navy warships. Admiralty drafts, like most Royal Navy records of the period have
been preserved in the National Maritime Museum Archive. 1 Given the Royal Navy’s focus on
standardization during this period it is possible to make certain assumptions regarding the
construction of all British warships based on admiralty plans. Nevertheless, identical designs
submitted to different shipyards never resulted in identical ships. However, it was expected that
all contracted ships would conform to general admiralty standards. While lacking detail and
often containing inconsistencies, these plans do serve as a good starting point for a theoretical
reconstruction.
Unfortunately, a complete set of Pallas’ Admiralty plans has not survived. However, an
incomplete set of drafts includes Sir Thomas Slade’s individual deck and construction plans, and
these can be supplemented with the surviving lines for sister ship, Brilliant (Fig. 3). 2 These 1/48scale drafts define the major scantlings and provide the designer’s intent regarding structural
features, general layout, and use of space. Many of the key timbers of the keel, stem, sternpost,
and mast steps are prominently included in these drafts and should be consistent throughout the
class. Also, during the first half of the 18th century, the Navy Board produced a series of lists
giving basic measurements as construction guidelines for each rate of warship. These
Establishment lists provide specific dimensions for most major timbers and some iron hardware. 3
The shipwrights building Pallas would have been expected to conform to the 1745
Establishment, which gives dimensions for 44-gun two deck ships and 24-gun single deck ships,
but does not yet address the new 32 and 36-gun cruisers. Nevertheless, they do provide absolute
22
dimension parameters and allow for further refinement of the Admiralty drafts. These important
sources provide a strong foundation for a graphic reconstruction.
As much as possible the results of archaeological investigations will be applied.
However, little remains of Pallas herself therefore the majority of archaeological evidence must
be extrapolated from the closest parallels investigated to date—principally the remains of the 44gun ship HMS Charon sunk off Yorktown in 1781 and the 24-gun frigate HMS Pandora sunk
off the Australian coast in 1791.
To build upon this foundation, further details have been gathered from a variety of
reliable contemporary sources. The majority of period shipbuilding treatises focus primarily on
the increasingly complex mathematical design theories being applied to the derivation of ships’
lines. However, at times they do offer clues to actual shipbuilding practices. Fewer sources
provide a clear idea of the engineering method, actual construction processes and carpentry
techniques of English shipwrights of the period. Fewer still contain significant useful data.
Nevertheless, several indispensable works remain and augment the Admiralty drafts and
Establishment lists. One such work is Blaise Ollivier’s Remarks on the Navies of the English &
the Dutch (1737). As mentioned previously Ollivier was Master Shipwright for the French naval
shipyard at Brest from 1736 until his death in 1746. His credentials are strengthened by the fact
that he has been credited with the invention of the frigate. 4 In 1737, he was sent to spy on
English and Dutch naval shipbuilding facilities and report his findings. Ollivier’s Remarks
provide a highly informative narrative of English naval shipbuilding practices throughout the
country, including most notably those at Deptford where Pallas would be laid down less than 20
years later. Another invaluable primary source is the anonymous work The Shipbuilder’s
Repository (1789). It contains comprehensive scantling lists for every class of Royal Navy
warship from the period. Although anonymous, it is both authoritative and accurate, and has
23
been accepted by shipwrights and historians alike since its publication. However, because
warships of all classes continued to grow in dimensions throughout the period, the basic
scantlings given (length, beam, and tonnage) for a 32-gun ship from 1789 more closely represent
those of 36-gun Pallas and will be used for the purpose of this reconstruction. Further useful
primary sources include William Sutherland’s The Shipwright’s Assistant (1711), David Steel’s
The Shipwright’s Vade Mecum (1805), and Mungo Murray’s A Treatise on ship-building and
navigation (1754). All contain valuable procedural construction details unavailable elsewhere.
However, both Sutherland and Steel are too far removed chronologically for their specific timber
dimensions to be applicable.
Another useful source is found in contemporary ship models. Along with the Admiralty
drafts, 1/48-scale models were commonly submitted to the navy board for approval. Many of
these models have survived to the present in both Admiralty and private collections.
Examination of these models can often provide a great deal of insight into the rigging, fitting,
internal layout and structural engineering of English warships for a given period.
One final primary source found to be particularly useful occurs in contemporary
artwork. Small details can often be harvested from prints, paintings, watercolors, lithographs,
sketches, or even the simplest caricature.
Secondary sources found to be especially useful include: Peter Goodwin’s The
Construction and Fitting of the English Man of War 1650-1850, Brian Lavery’s Arming and
Fitting of English Ships of War 1600-1815, Robert Gardiner’s The First Frigates, and the
graphic reconstructions proposed in John McKay’s The 24-gun Frigate Pandora and David
White’s The Frigate Diana. These works are, for the most part, based upon analysis of the
previously mentioned treatises, artwork and Admiralty models but also provide detailed
drawings and descriptions for specific elements during specific timeframes. While primary
24
sources will be used wherever possible these works provide substantial information regarding the
fittings, accessories and finishing detail not otherwise addressed.
Hull Construction
Until the advent of modular construction in the 20th century, the keel assembly was the
backbone and principle source of longitudinal strength in wooden ships. 5 Consequently, the
integrity and fairness of the entire construction depended upon the laying of the keel being both
sound and true. Before the construction of the ship could begin, the master shipwright selected a
suitable slipway upon which a platform was erected to support the hull during the building
process. First, large pieces of timber called ground-ways were laid down as a base. On top of
this, heavy blocks of hard knotty stuff were placed at regular intervals along the length of the
proposed keel and capped with splitting blocks that could be easily cleaved away at a later time. 6
A. Keel Assembly
Construction began with the keel sections being placed end-to-end on top of the splitting
blocks and scarfed together (Fig. 4). 7 The Slade drafts provide the approximate length, and
molded and sided dimensions of the keel assembly for Pallas but unfortunately little else (Fig.3
and 5). Gardiner gives the length of her keel as 106 ft. 2-5/8 in. (32.37 m.) as designed and 106
ft. 4 in. (32.41 m.) as completed. 8 The keel was 14 in. (35.6 cm.) square at midship and the sided
dimensions tapered to between 9 and 11 in. (22.9-27.9 cm.) at the sternpost. 9 Ollivier concurs,
observing that English keels “…diminish greatly its breadth athwart ships towards the stern,
starting one third along its length….” 10 Goodwin states that the keel diminished in width towards
bow as well. 11 However, the drafts show no indication of the keel diminishing towards either
end. 12
25
The main keel was composed of five pieces of elm or oak scarfed together and secured
with six to eight 1 in. (2.5 cm.) diameter iron bolts driven through in pairs from opposite sides of
the keel and clenched over roves. 13 The exact type of scarfs employed on Pallas cannot be
conclusively determined but they were 47 to 66 in. (119.4-167.6 cm.) long and almost certainly a
type of coked or tabled diagonal scarf set in the vertical plane (Fig. 4 and 6). 14 Ollivier states that
unlike the French, English shipwrights arranged their keel scarfs side by side rather than one on
top of another. 15 The keel of Diana, 50 years later, employs the same method. 16 Goodwin states
that the butt and coke method was the most common (Figs. 6). The butt ends were sided 1/3 of
the total siding, the cokes were 2/3 the siding in length and half as wide as they were long (but
were never more than 1/2 the molded depth of the keel). 17 While the location of each scarf is
marked on some Admiralty drafts, they are not marked on the drafts for Pallas or her sister
ships. Most sources agree that the scarfs were lined with tarred flannel. 18 However, Ollivier
observed that “… English shipwrights line their keel scarfs neither with kersey nor any other
filling, they are content but to tar them.” 19 Presumably, the use of flannel was a practice that
emerged over the course of the century. A rabbet was cut several inches below the top of keel on
foreign ships but this did not occur on English warships until after Robert Seppings became
surveyor of the Navy in 1812-13. 20 Prior to this, Royal Navy practice was to cut the rabbet along
the top edge of the keel and then to build up the surface above with a ‘hog’ or additional
deadwood placed on top of the keel. 21 The keel of HMS Charon was constructed in exactly this
manner. 22
Once the main element of the keel was completed, the caps on the support blocks were
removed and a false keel was fitted to the underside of the keel assembly. The false keel was a
sacrificial element that protected the main keel in case of accidental grounding and increased the
keel depth, thereby reducing leeway and enhancing handling characteristics. Made of elm or
26
teak, the false keel was slightly longer than the main keel and projected a short distance beyond
the keel’s leading edge. Both the keel and false keel were seated into notches cut into the
underside of the gripe. The false keel was composed of five pieces, 4½ to 6 in. (11.4-15.2 cm.)
thick with the scarfs being given sufficient shift to avoid those of the keel. 23 The false keel’s
sided dimension was the same as that of the keel, and the depth was about one third of the
molded depth of the keel. The false keel on HMS Charon was 6 inches (15.2 cm.) thick, and
separated from the main keel by approximately ¼ in. (6 mm.) of oakum. 24 False keels may have
been assembled with flat scarfs in the horizontal plane, but more likely with flat scarfs in the
vertical plane to facilitate frequent repair and replacement. The false keel was not secured to the
main keel with iron bolts or nails but with copper staples, fastened into the sides of the false keel
and the keel. This allowed for the false keel to be torn away without causing major damage to
the main keel. 25
B. Stem Assembly
Once the keel assembly was complete, the stem and sternpost were erected. The stem
and apron were raised together; as was the entire sternpost, fashion piece and transom assembly
(Figs. 7, 8 and 9). This was more easily accomplished on smaller vessels. The stem and sternpost
assemblies were then trued with the keel, ensuring that the transoms were both perpendicular to
the keel and level, before being securely shored on timber foundations. 26
The shape and dimensions of the stem and apron can be accurately determined from
Slade’s construction drafts. 27 The stem was composed of two pieces scarfed together in a manner
similar to that of the keel. It was molded 16 in. (40.6 cm.) for its entire length and sided 17½ in.
(44.4cm.) at the head, diminishing to 13 in. (33 cm.) at the lower side of the cheek, and 10¼ in.
(26 cm.) at the keel. 28 It had the same siding as the keel at the boxing but increased as it neared
27
the bowsprit. The rabbet of the stem was cut flush with the inner surface of the stem, leaving no
portion of the stem projecting inside of the planking. 29 The scarfs were 40 in (1.02 m.) long and
were secured with six 1 in. (2.5 cm.) diameter iron bolts. Two of the scarf bolts went through the
false stem as well.
The false stem or ‘apron’ was composed of two or three pieces molded 9½ in. (24.1
cm.), sided 19½ in. (49.5 cm.), and fastened together with plain flat scarfs 10½ in. (26.7 cm.)
long. 30 The portion of the apron that exceeded the athwartship dimensions of the stem was
shaped to provide a landing for the wales and planking. Once this structure was completed, the
stem and apron assembly was raised into place by means of sheerlegs. 31 It was half lapped to the
top of the keel with a complex scarf called the boxing and, like the keel scarfs, the joint was
lined with tar and flannel and secured with six or eight iron or copper bolts driven from opposite
sides and clenched over roves. Goodwin suggests a variety of potential boxing techniques but
states that the slotted (mortised) type was the most commonly used after the first quarter of the
18th century (Fig. 10). As previously stated, the fore end of the keel and keelson extended
forward of the boxing scarf and butted against the aft edge of the gripe (Figs. 7 and 8). 32
C. Sternpost Assembly
The sternpost assembly served to support the aft body of the ship, the stern timbers and the
rudder (Fig. 9). The sternpost itself was cut from carefully selected oak and was mortised into the
top of the keel. The mortise was cut to 1/3 the molded depth and 1/3 the sided dimensions of the
keel. This joint was typically reinforced by bolting copper fishplates across the seams on either
side of the keel. 33 The sternpost was 18 in. (45.7 cm.) square at the head; the fore and aft
dimension at the heel, including the inner post, was 32 in. (81.3 cm.). The fore and aft dimension
of the inner post was 9 in. (22.9 cm.) at the head and 13 in. (33 cm.) at the heel. 34 The sternpost’s
28
athwartship dimension at the heel was the same as that of the aft end of the keel to which it was
fastened, or between 9 and 11 in. (22.9-27.9 cm.). The after edges of the sternpost and keel were
chamfered about 60 degrees to allow for the pivot of the rudder. The rake of the sternpost can be
accurately determined from Slade’s drafts as about 5.5 degrees. 35 The inner post served to
reinforce the main post and to support the wing transom. Also made of oak, the inner post was
mortised onto the top of the keel in the same manner as the main post, and secured to the forward
face of the main post with copper clench bolts. 36 The inner post was beveled to provide a landing
for the planking, and a rabbet was cut into the fore edge of the main post to receive the hood ends
of the planking.
Before the sternpost assembly was raised, the wing transom, lower deck transom, filling
transoms, and fashion pieces were fitted. The wing transom was the most important timber in the
stern structure, for it provided both lateral support and served as the foundation for the upper
works of the stern. It was made of a single piece of oak notched into the forward face of the
sternpost and mortised onto the top of the inner post. It was rabbetted on the upper and lower
surfaces to receive the planks of the counter and the tuck. 37 The wing transom was sided 13 in.
(33 cm.), molded 14 in. (35.6 cm.), and the athwartship arms spanned the breadth of the stern
just below the upper deck. The transoms were notched 1½ in. (3.8 cm.) into the sternpost in the
same manner as floors were notched into the keel. 38 They possessed a rising curvature towards
the middle of the ship, similar to the floors, called the ‘flight.’ The wing transom was also
rounded upward towards the midline of the ship. The deck transoms were similarly rounded
upwards to match the curvature of the associated deck beams. 39 Two copper clench bolts secured
the wing transom to the sternpost, two more secured it atop the inner post, and two more secured
each end to the aft faces of the fashion pieces. 40 The wing transom was secured firmly to the side
of the ship with large knees. The wing transom knees were sided 9 in. (22.9 cm.), the fore and aft
29
arms were 11 ft. 6 in. (3.51 m.) long, and the athwartship arms were 6 ft. 3 in. (1.9 m.) long.
Each was bolted to the transom and the ship’s sides with ten 1¼ in. (3.2 cm.) diameter iron
bolts. 41
Cut from carefully selected curved timber, fashion pieces were a continuation of the cant
frames aft. They terminated the breadth of the framing and formed the shape of the lower stern
(Fig. 9). 42 Most ships had two on each side. The forward most on Pallas finished about 3 ft. (9.1
cm.) above the upper edge of the wing transom, and the aftermost finished under the gun deck
transom. They were scored over the transoms and fixed in place with treenails and copper
bolts. 43 The lower deck transom was installed in a similar manner to the wing transom. However,
to compensate for the added molded dimension required to support the ends of the deck
planking, it was necessary to notch the lower deck transom 1½ in. (3.8 cm.) into the after face of
the aftermost fashion pieces as well. Next, two filling transoms were installed between the wing
transom and the lower deck transom, and two more below the lower deck transom. They were all
sided 10½ in. (26.7 cm.) and each molded to incrementally rise and narrow as they drew closer to
the top of the deadwood. 44 Like the stem assembly, the sternpost assembly was raised into place
by means of sheerlegs and shored on timber foundations. 45
Once the sternpost assembly was raised, the counter timbers were attached. Counter
timbers were a series of six upright timbers that defined the shape of the upper stern (Fig 9). The
two side counter timbers possessed complex curves in all three dimensions, defining the shape of
the stern from both the athwartship and sheer perspectives. The remaining counter timbers were
placed between the side counter timbers to form the sides of the window openings and stern
ports. Because of their complex shape, they were made from two or more scarfed and bolted
pieces. On Pallas they were sided 8 in. (20.3 cm.); the fore and aft dimensions of the heels were
the same as the upper edge of the wing transom and gradually diminished towards the heads
30
(Figs. 9 and 11). They were firmly fastened to the top of the wing transom with ¾ in. (1.9 cm.)
iron bolts. 46
D. Deadwood
The deadwood or rising wood was an assemblage of large pieces of timber laid upon one
another, on top of the main keel, to accommodate the rising of the frames towards the bow and
stern, and to form a foundation for the frames and the run of the keelson. (Figs. 7 and 9) 47 It was
fashioned 2 to 4 in. (5.1-10.2 cm.) wider than the corresponding keel and trimmed to match the
angle of the rabbet. 48 The bow deadwood consisted of a single timber cut to fill the space
between the apron and keelson forward of the foremost full frame. The stern deadwood
configuration is much more difficult to establish. Ollivier observed a variety of stern deadwood
configurations employing layered sections of straight timbers butted against the sternpost, both
with and without the addition of a deadwood knee. Furthermore, he observed three different
methods employed on three different ships at the same shipyard. 49 He reasonably concluded that
deadwood configuration was dependent upon the individual shipwright and the materials
available. The stern deadwood on HMS Charon was composed of as many as four timbers
stacked atop the keel. The lowest piece was tenoned into the forward face of the inner post and
the whole assembly was bolted through the keel with 1¼ in. (3.2 cm.) iron bolts. 50 Good
examples of deadwood on frigates can be seen on the reconstructions of Diana and Pandora. 51
Another good example can be seen on the construction drafts of a 60-gun ship built to 1745
establishment standards. 52 Despite the disparity in size of these examples, all employ a single
deadwood or ‘sternson’ knee integrated into a varied assemblage of straight timbers, securing
them firmly to the inner sternpost. It would be impossible to establish conclusively what Pallas’
deadwood would have looked like; however, a reasonable facsimile can be extrapolated from the
31
parallels available. The sternson knee is portrayed on Slade’s construction draft extending aft of
the keelson up the inner post to the base of the lowest filling transom. It was bolted through the
deadwood, keel, and sternpost with 1¼ in. (3.2 cm.) iron bolts spaced about every 22 in. (55
cm.). 53
E. Frames
Once the keel, stem, and sternpost assembly was completed, and trued and shored in
position, the frame timbers were installed. There were three general types; full or square frames,
cant frames, and filling frames. Full frames were solid units composed of two overlapping
courses of timber. They formed the sides of the gun ports and continued uninterrupted from the
keel assembly to the upper works. Cant frames were angled frames forward and aft that were
bolted to the sides of the deadwood and formed the bow and stern. Filling frames were
essentially the separated components of full frames. They extended up to the gun port sills and
then were continued above (Fig. 12).
The layout of the frames usually took place in large buildings called mold lofts where
full sized patterns were marked out on the floor and each frame component was cut from
compass oak to match its individual pattern. 54 Initially every second floor was placed across the
keel, beginning with the midship floor and moving forward and aft from there. 55 The top of the
keel or hog timber was notched to receive the floors, each of which was correspondingly
notched on its underside (Figs. 4 and 12). Careful attention was given to ensuring that the floors
were exactly perpendicular to the line of the keel before being bolted through the keel with 1¼
in. (3.2 cm.) diameter bolts. 56 At the bow, and especially at the stern, specially molded rising
floors were lofted to accommodate the rising and narrowing of the hull shape as it neared the
posts. Because of the acute angle of these frames they were usually assembled or ‘made’ from
32
two or three pieces with a variety of complex scarfs. 57 Once this was done, about every third or
fourth frame was raised. The frames were assembled on the ground adjacent to the slipways.
Each frame timber, or ‘futtock,’ overlapped by half its length the frame timbers below and above
(Fig. 12). The lower half of the second futtock was bolted in the fore and aft direction to the
upper half of the first futtock, the heel of the upper futtock butted against the head of the first
futtock, and its lower half was bolted in a like manner to the upper half of the second futtock.
The top-timbers were not attached until after the frames had been raised. To further reinforce the
joints between the frame timbers, seats were cut into the head and heel of each futtock (not at the
heads of the top-timbers) to receive cross chocks. The chocks were secured in place with four
treenails driven through the frame from the inside. 58
The completed frame halves were hoisted into position against their assigned floors. The
heels of the first futtocks butted against the sides of the keel, and the heels of the second futtocks
butted against the heads of the floor. Chocks were then placed across the timber butts and
secured with treenails. A larger chock crossed the keel, connecting the heels of the lower
futtocks, and was bolted through the keel. Finally, the lower futtocks were bolted through fore
and aft to their associated floor. 59 Once this was accomplished the frames were shored in place
and ribbands were placed to ensure the fairness of the remaining frames as they were assembled
in place. The breadth ribband was placed so that the main wale could be placed before the
ribband was removed. 60 All of the remaining floors were then placed. They were not lofted as
those before but were ‘spiled’ or shaped once in place to conform to the ribbands. The remaining
deadwood was built up on top of the keel assembly towards the stem and sternpost to
accommodate the rising and narrowing of the frames as they neared the posts. 61
The sided dimensions of all frames and futtock timbers diminished afore and abaft of
midship but usually not more than one inch (2.5 cm.) over the entire length of the ship. For
33
simplicity only midship dimensions are given here. All available sources agree that the midship
floors for a 36-gun frigate of the period were molded 18 in. (45.7 cm.) at the keel, 10 to 12 in.
(25.4-30.5 cm.) at the rung heads, and were sided 12½ to 14 in. (31.7-35.6 cm.). The first
futtocks were molded 10½ in. (26.7 cm.) at the rung heads and sided 12½ in. (31.7 cm.). The
second futtocks were molded 10½ in. (26.7 cm.) at the rung heads and sided 11¾ in. (29.8 cm.).
The third futtock was molded 9 in. (22.9 cm.) at the gun deck and sided 11 in. (27.9 cm.). The
top-timbers were molded 4 to 4½ in. (10.2-11.4 m.) and sided 10½ to 11 in. (26.7-27.9 cm.) at
the heads. The lengths of the chock scarfs are not as conclusive; the 1719 Establishment list calls
for scarfs 6 ft. 4½ in. (1.94 m.) long. However, these figures represent a period when timber was
more abundant and larger pieces were employed. Diana and Pandora, while considerably later,
are much closer in date to Pallas. The frame scarfs on Diana were about 48 in. (1.22 m.) long
and those on Pandora were about 28 in. (71 cm.) long. 62 It is therefore reasonable to assume that
those on Pallas would have been an average between Diana and Pandora, or about 38 in. (96.5
cm.) long.
Once all of the full frames were erected the gun ports were installed. The upper and
lower sills of the ports were notched into the neighboring full frames. The port sills had the same
molded dimensions as the frames. 63 Since Pallas had only a single gun deck, only one row of
ports was needed. Ollivier observed that no space was left between the floors and frames up to
the heads of the first futtocks and that the space between was caulked. He surmised that this
served both as ballast and prevented water from gathering between the floors. 64 However it is
clear that warships of Pallas’ time had considerable space between the frame timbers. Goodwin
states that the room and space (the width of the frame plus the space in between) for one full
frame on a 36-gun ship in 1780 was about 30 in. (76.2 cm.). 65 The room and space recorded
from the remains of HMS Charon was 28 in. (71.1 cm.) and the floors were sided 12 in. (30.5
34
cm.). 66 Both sources suggest a room and space close to twice the 12½ to 14 in. (31.7-35.6 cm.)
sided dimension of the midship frame at the keel. They had enough room in fact that the
elements of the filling frames could be separated, leaving ventilation space between them and
reducing the amount of timber required to frame the ship. The timbers of the filling frames were
cut in exactly the same manner as those for the full frames. However, the two courses that were
bolted together on full frames were assembled and raised as independent elements leaving space
between the two courses (Fig. 12). On one half, the head of the floor was chocked to the heel of
the second futtock, and the head of the second futtock was chocked to the heel of the top-timber,
on the other, the head of the first futtock was chocked to the heel of the upper futtock. Oak
filling pieces were placed between the two halves of the filling frames and were bolted through
fore and aft. 67
As the frames neared the bow the floors became half floors. They ceased to cross the
deadwood and instead component parts were notched into the top and sides of the deadwood.
The notches found on the remains of Charon were cut 2 to 3 in. (5.1-7.6 cm.) deep into the top of
the deadwood and 12 to 13 in. (30.5-33 cm.) long down the sides. 68 Further forward, as the bow
continued to rise and narrow, the cant frames were only notched and bolted to the sides of the
deadwood.
Cant frames were frames situated at the ends of the ship that gradually transitioned the
lines of the sides towards their respective posts (Fig. 8). 69 They were introduced sometime in the
eighteenth century. Sutherland’s Shipbuilding Unvail’d of 1711 makes no mention of cant
frames. They start to appear in ship models around 1719, becoming more common until almost
universal by 1750. 70 They were to be equally spaced at the breadth ribband, and shaped using the
ribbands, to fair with hawse pieces at the bow, and the transoms and fashion pieces at the stern
(Figs. 8 and 9). Cant frames never progressed past 45 degrees from the line of the keel. 71
35
Hawse pieces filled the remaining space between the cant timbers and the stem
assembly. They were broad timbers standing nearly parallel to the keel through which holes were
cut to allow the passage of anchor cables. (Fig. 8 and 13) 72 Their heels butted against the forward
face of the foremost cant timber and then curved forward and upward forming the cheeks of the
bow. The cants were bolted to the stem assembly and to each other abaft the hawse holes. They
were fashioned so that the area around the hawse holes stood proud of (and therefore interrupted)
the planking and ceiling strakes—thus preventing excessive damage to the butt ends of those
strakes. 73 Pallas had four hawse pieces, of the same molded dimensions as the forwardmost cant
frame timber and sided 14 in. (35.6 cm.). 74 The timbers directly adjacent to the stem were called
bollard timbers or knights heads. They extended above the top timbers and provided lateral
support to the bowsprit (Fig. 8). The hawse holes were 13 in. (33 cm.) in diameter and 19 in.
(48.3 cm.) above the lower deck. They were lined with lead 1 in. (2.5 cm.) thick. 75
All ships above 6th-rate had a manger or partially walled compartment, not more than 3
ft. 6 in. (106.7 cm.) high, inside the hawse holes to collect water entering through them and to
prevent it from running into the ship. The manger boards were 8 to 10 in. (20.3-25.4 cm.) wide, 3
in. (7.6 cm.) thick, rabbetted and secured directly to the cant frames, or to stanchions fixed to
them, and extending to stanchions 6 to 9 in. (15.2-22.8 cm.) square placed on either side of the
bowsprit step. At the after edges of the manger were two 4¾ in. (12.1 cm.) diameter lead
scuppers. The manger, as the name suggests, was also typically used for live animal storage. 76
F. Keelson
The keelson was a heavy longitudinal timber fixed directly over the keel, binding the
frame timbers in between, and strengthening the lower part of the ship (Fig.4). 77 It also formed a
foundation to support the masts, stanchions and other structural elements. The keelson on Pallas
36
was composed of five pieces, 14 in. (35.6 cm.) square, assembled with hook scarfs 4 ft. 10 in.
(1.47 m.) long, and fastened with two ¾ in. (1.9 cm.) iron bolts at each scarf (Fig. 6). The
keelson scarfs, like those on the false keel were shifted clear of the keel scarfs. The keelson was
notched down over the floor timbers ¾ in. (1.9 cm), before being bolted through every other
floor to the keel (those floors not already bolted to the keel) with 1¼ in. (3.2 cm.) iron bolts. 78
After 1750 the keelson no longer terminated at the deadwood but instead carried up to or over
the transoms (as the ‘sternson’) and up to the lower deck hook (as the ‘stemson’). 79 The sternson
was simply an extension of the keelson over the deadwood, retaining the dimension of the
keelson and ending in a sternson knee against the inner post. The stemson extended from the
forward end of the keelson up to the underside of the upper deck breast hook and diminishing to
10 in. (25.4 cm.) square at its peak (Fig. 7). 80
G. Internal Planking
Ships like Pallas were planked both inside and out. The first and most important part of
the planking to be fitted was the main wale, a belt of heavy strakes placed between the waterline
and the gun ports. Its primary function was to add longitudinal strength. The main wales ran
parallel to the line of the sheer rather than the decks. The lower edge tapered towards the ends of
the ship. 81 Wales were made of the very best quality oak cut 25 ft. (7.62 m.) long and 7 in. (17.8
cm.) thick. The main wales on both Diana and Pandora were at or near the dead flat of the sides
(Fig. 14). All sources agree that the main wales on 36- to 38-gun frigates were composed of four
strakes, 38 to 43 in. (96.5-109.2 cm.) wide, and 5½ to 7 in. thick. 82
During construction, once the main wale was fitted, all attention shifted to the internal
planking. Work began at the bottom and progressed upwards. As the planking reached the height
of each deck, the beams and supporting knees for that deck were installed.
37
The limber strakes, ceiling or footwaling, stringers, deck clamps, waterways, spirketting,
and quickwork were all varieties of longitudinal internal planking. They were all fitted over the
frames in parallel courses, tapering towards the posts, and butting up against the apron at the
bow and the fashion pieces at the stern. The transoms were usually left exposed. 83
The limber strakes were a double row of strakes placed 9 to 10 in. (22.9-25.4 cm.) from
the keelson amidships (Fig. 14). Each strake was constructed of plank sections about 25 ft. (63.5
cm.) long, joined together with flat scarfs, and fixed to the frames with treenails. The first strake,
that closest to the keelson, was 12 to 13 in. (30.5-33 cm.) wide and 5 to 5½ in. (12.7-14 cm.)
thick. The second strake was 11¼ to 12 in. (28.6-30.5 cm) wide and 4 to 4¼ in. (10.2-10.8 cm.)
thick. The strakes tapered towards the ends of the ship to about one-third their width at the
midship frame. The outboard edge of the second limber strake was chamfered to meet the
neighboring footwaling.
A groove about 2 in. (5 cm.) deep was cut into the inboard edge of the inner limber
strake into which the limber boards were seated. 84 Limber boards were short panels left loose
between the keelson and the limber strakes that could be removed to allow access to the bilge. 85
The limber boards on Charon were found to be 3 inches (7.6 cm.) thick. 86
Also known as thick stuff, stringers were a series of heavy ceiling strakes laid at the rung
heads of the floors to help strengthen the joint (Fig.14). For a 36-gun ship the stringer assembly
consisted of five strakes. The one directly over the joint was 15 in. (38.1 cm.) wide and 6 in.
(15.2 cm.) thick, the next two above and below were 12 in. (30.5 cm.) wide and 5½ in. (14 cm.)
thick, and the outer two were 11 in. (27.9 cm.) wide and 4½ in. (11.4 cm.) thick. The strakes
were fastened together with plain flat scarfs (Fig. 6). All were secured to the frames with
treenails. As with all planking and ceiling strakes, stringer strakes diminished in width towards
the bow and stern to accommodate the rising and narrowing of the hull. 87
38
Clamps were thick strakes worked fore and aft inside the ship that supported the ends of
the deck beams (Fig 14). They were assembled from oak planks 25 to 30 ft. (7.62-9.14 m.) long
scarfed together hook and butt fashion (Fig. 6). The scarfs were 34 to 45 in. (86.4-114.3 cm.)
long and were bolted together with two ¾ in. (1.9 cm.) diameter iron bolts through the butt ends
of each scarf. The upper edge was beveled to match the slight arc of the deck beams they
supported and they were notched about 1 in. (2.5 cm.) to receive the ends of the deck beams. The
clamps on 5th-rate warships usually consisted of two strakes with the scarfs shifted half their
length. 88
The orlop clamps were composed of two strakes assembled with hook and butt scarfs
and secured together with two ¾ in. (1.9 cm.) iron bolts through the lip of the scarf. The upper
strakes were 11¾ to 14 in. (29.8-35.6 cm.) wide and 4 to 4¾ in. (10.2-12.1 cm.) thick; the lower
clamp strakes were 9¾ to 11 in. (24.8-27.9 cm.) wide and 3 to 3 ¾ in. (7.6-9.5 cm.) thick. 89
The lower deck clamps were composed of two strakes assembled with hook and butt
scarfs 34 in. (86.4 cm.) long. The upper strakes were 14 to 15 in. (35.6-38.1 cm.) wide and 5¼ to
5½ in. (13.3-14 cm.) thick, and the lower strakes were 13 in. (33 cm.) wide and 4 to 4 ¼ in.
(10.2-10.8 cm.) thick. 90
The upper deck clamps were composed of one or two strakes assembled with hook and
butt scarfs 45 in. (114.3 cm.) long. For a frigate carrying a main battery of 12-pound guns on the
upper deck it is reasonable to assume that two strakes would have been used. 91 Both strakes of
the gundeck clamps were 9¾ in. (25.8 cm.) wide and 4 to 4 ¾ in. (10.2-12.1 cm.) thick, with the
lower strakes being chamfered about 1 inch (2.5 cm.) at the bottom edge. 92
The deck clamps for the quarterdeck and forecastle consisted of only a single strake on
frigates, with the planks being scarfed together with two iron bolts driven vertically through a
flat scarf. The deck clamps for both the forecastle and the quarterdeck generally filled the entire
39
space between the tops of the gun port sills on the gun deck, and the beams on the underside of
the forecastle and the quarterdeck respectively. For a frigate this was about 11½ in. (29.2 cm.)
wide and 3¾ to 4 in. (9.5-10.2 cm.) thick with the lower edge being chamfered about 1 in. (2.5
cm.). 93
All deck clamps were fastened to the frames with both treenails and iron ‘dumps’ (round
tapered spikes) and tapered towards the ends of the ship in a similar fashion to the planking and
ceiling. They were usually chamfered about 1 in. (2.5 cm.) on their lower edge to meet the
ceiling planking. 94
As previously stated, the beams and supporting knees for each deck were installed as the
planking reached the height of that deck. However, for the sake of continuity discussion of deck
beams and associated timbers will follow completion of the internal planking.
The next internal planks installed were the waterways, which were specially shaped
ceiling strakes, wider than the rest, placed onto the ends of the deck beams. They were designed
to prevent water from passing between the ceiling planking and decking and reaching the beamends and frames (Fig 14). During the 18th century, waterways on British warships were concave
on the exposed surface creating a smooth transition from the horizontal decking to the vertical
spirketting. 95 The lower deck waterways were 4 in. (10.2 cm.) thick. 96 The upper deck
waterways were 4½ in. (11.4 cm.) thick and had six 2¾ in. diameter scuppers along each side. 97
The waterways for both the quarterdeck and forecastle were 4 in. (10.2 cm.) thick. 98
Spirketting was a thick band of ceiling strakes that filled the space between the tops of
the waterways and the bottoms of the gun ports (Fig. 14 and 15). 99 As with wales and stringers, it
served to increase the longitudinal strength of the hull. It was constructed with hook and butt or
anchor stock scarfs that were shifted away from the gun ports (Fig. 6). The seam between the
lower spirketting strake and the waterway was caulked with oakum and tar. The width of the
40
individual strakes would have depended entirely upon the space to be filled between the
waterway and the gun port sills. The lower deck spirketting was 4 to 4 3/8 in. (10.2-11.1 cm.)
thick. 100 The upper deck, spirketting was composed of two strakes, each 4 in. (10.2 cm.) thick. 101
The spirketting for both the quarterdeck and forecastle was 3 to 4 in. (7.6-10.2 cm.) thick. 102
Foot waling consisted of all of the remaining inboard planking from the keelson to the
orlop clamps (Fig. 14). 103 It filled the space between the limber strakes and the stringers over the
frame heads, and from the stringers up to the berth deck clamps. Unlike the rest of the ceiling, it
was often made from pine instead of oak. Each strake was about 9 in. wide, 3½ to 4 in. (8.9-10.2
cm.) thick, and was fixed to the frames with treenails. Spaces were typically left between strakes
to allow for ventilation of the internal structure. 104
Quickwork was the planking that formed the internal lining of the hull throughout the
working decks (gun deck, lower deck, and orlops) (Fig.15). Like the footwaling, the quickwork
was usually made from pine. On the orlop deck the planks were 10 to 15 in. (25.4-38.1 cm.)
wide and 6 to 8 in. (15.2-20.3 cm.) thick. They were secured to the frames with iron bolts at the
ends and treenails in between. Usually 1½-3 in. (3.8-7.6 cm.) spaces were left between the
quickwork strakes for ventilation. On the lower deck the quickwork consisted of a single strake
2½-2¾ in. (6.3-7 cm.) thick. The upper deck quickwork consisted of two strakes 1¾-2 in. (4.45.1 cm.) thick. 105 The width varied depending on the number of strakes and the space to be filled.
The quickwork strakes between the gun ports had openings cut into them (and were therefore
known as air strakes) to provide ventilation to the frames (Fig. 15). 106
Finally the strings of the waist were worked in just below the gunwale, between the
forecastle and quarterdeck, to provide longitudinal integrity to the sheer. The strings were
composed of one or two strakes 3½ in. (8.9 cm) thick, scarfed hook and butt into the forecastle
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and quarterdeck clamps. They were notched over each frame timber for added rigidity and
fastened with ¾ in. (1.9 cm.) iron bolts. 107
H. Deck Beams, Knees, Carlings, Ledges and Hooks
Once the clamps were in place at each deck level, the deck beams and supporting knees
were installed. The numbers and approximate placement of the deck beams were provided by
Slade’s construction draft (Fig. 5). However, some adjustments and corrections had to be made
to reconcile the various plan views and placement of additional internal fittings. 108
Beams were assembled or ‘made’ from multiple pieces of timber, usually oak but
sometimes pine, fastened together with an elongated form of hooked or tabled scarf in the
vertical plane. The scarfs were one-third the overall length of the beam and were secured with 1
in. (2.5 cm) diameter iron bolts. With the exception of orlop beams, all beams were rounded up
or ‘cambered’ towards the centerline of the ship to ensure that water drained outboard to the
scuppers. 109 The beams were seated into 1 in. (2.5 cm.) notches cut into the clamps and, because
the exposed beam-ends were prone to rot, these joints were packed with tarred flannel or brown
paper. The space between the beam-ends was filled either with a lodging knee or with a specially
fitted spacer or ‘packing piece.’ Beams were spaced so that associated hanging knees did not
interfere with gun ports and they were located over one another and supported through pillars
directly down to the keelson. Every effort was made to place beams under gun ports to support
the weight of the guns. By necessity beams had to be placed clear of masts and hatchways. 110
This was accomplished by using beam arms; specially formed deck beams that curve to meet the
fore or aft face of the neighboring beams thereby partially compensating for the loss of an
athwartship beam. Pallas had a single ‘fork beam’ or two beam arms curving from each side to
meet the fore and aft faces of the same beam (Figs. 5, 16 and 17). 111
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Knees were angled timbers that reinforced the joints between the deck beams and the
sides of the ship. 112 They were carved from carefully selected curved oak compass timber
possessing a grain following the desired curvature of the knee. The deck structure of 18th-century
frigates employed several varieties of knees. Hanging knees were oriented in the vertical plain,
with the vertical arm reaching down, and supporting the deck structure from the underside.
Standing knees or ‘standards’ were also oriented in the vertical plane but had the vertical arm
reaching up above the deck supporting it from above. Finally, lodging knees were placed in the
horizontal plain between the deck beams and prevented movement fore and aft.
All sources agree that the orlop deck beams were composed of single timbers sided 9 in.
(22.9 cm.) and molded 8 to 9 in. (20.3-22.9 cm.). 113 The orlop beams were secured to the side of
the ship with standing and lodging knees. The standing knees were sided 6¼ to 6½ in. (15.9-16.5
cm.) and the athwartship arms were 42 to 45 in. (106.7-114.3 cm.) long. The vertical arms
reached to the upper edge of the lower deck clamp. The lodging knees were sided 6½ to 6 ¾ in.
(16.5-17.1 cm.), the athwartship arms were 42 in. (10 cm.) long, and the fore and aft arms were
not less than 38 in. (96.5 cm.) long. All were bolted through with six 1 in. (2.5 cm.) diameter
iron bolts (Fig. 18) 114
The lower deck beams were sided 9 to 10 ½ in. (22.9-26.7 cm.) and molded 8 to 9½ in.
(20.3-24.1 cm.). 115 They were composed of two pieces and were cambered 4½ in. (11.4 cm.) at
the centerline of the ship. 116 The lower deck beams were secured to the side of the ship with both
hanging and lodging knees. The hanging knees were sided 7½ in. (19 cm.), the athwartship arms
were 40 to 44 in. (101.6-111.8 cm.) long, and the vertical arms were 54 in. (137.2 cm) long. The
lodging knees were sided 7 to 7½ in. (17.8-19 cm.), and the athwartship arms were 40 to 44 in.
(111.8 cm.) long. The length of the fore and aft arms was dictated by the space between the deck
beams. All were bolted through with eight 1 in. (2.5 cm.) diameter iron bolts (Fig 17). 117
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The upper deck beams were sided 11 to 12 in. (27.9 cm.) and molded 8½ to 11 in. (21.6
cm.). 118 They were composed of two pieces and were cambered 8 in. (20.3 cm.) at the centerline
of the ship. 119 The upper deck beams were secured to the side of the ship with both hanging and
lodging knees. The hanging knees were sided 7½ to 8 in. (19-20.3 cm.) and the athwartship arms
were 40 in. (101.6 cm.) long. The vertical arm reached down to the spirketting of the lower deck.
The lodging knees were sided 7 to 7½ in. (17.8-19 cm.) and the athwartship arms were 42 in.
(106.7 cm.) long. The length of the fore and aft arms was dictated by the space between the deck
beams (Fig.16). There were also five pairs of upper deck standing knees or standards. Their
exact placement is unknown but they were probably distributed as evenly as possible along the
ship’s side without interfering with the operation of the guns. They were sided 8 in. (20.3 cm.),
the athwartship arms were 36 in. (91.4 cm.) long, and the vertical arm reached to the upper edge
of the forecastle and quarterdeck clamps or the string of the waist. All were bolted through with
seven 1 in. (2.5 cm.) diameter iron bolts. 120
The quarterdeck and forecastle beams were sided 6 ½ to 8 in (16.5-20.3 cm.) and
molded 5 ¾ to 6 in. (14.6-15.2 cm.). 121 They were composed of two pieces and were cambered 7
in. (17.8 cm.) at the centerline of the ship. 122 The forecastle and quarterdeck beams were secured
to the side of the ship with hanging and lodging knees. The hanging knees were sided 4¾ in.
(12.1 cm.) and the athwartship arms were 31 to 33 in. (78.7-83.8 cm.) long on the forecastle and
33 in. (83.8 cm.) long on the quarterdeck. The vertical arms reached to the spirketting on the gun
deck. All were bolted through with seven ¾ in. (1.9 cm.) diameter iron bolts. The lodging knees
were sided 4½ to 5¼ in. (11.4-13.3 cm.) and the athwartship arms were 31 in. (78.7 cm.) on the
forecastle and 35 in. (88.9 cm.) on the quarterdeck. The length of the fore and aft arms was
dictated by the space between the deck beams. All were bolted through with five ¾ in. (1.9 cm.)
diameter iron bolts (Fig 19). 123
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The catbeam was the foremost beam on the forecastle and the largest beam on the ship.
It supported the inboard ends of the catheads and therefore had to be able to support the weight
of the anchors. It also supported the upper ends of the vertical stanchions of the beakhead
bulkhead (Figs. 5 and 19). It was 18 in. (45.7 cm.) wider and 2 in. (5.1 cm.) deeper than the other
forecastle beams. The knees supporting the catbeam were sided about 4½ in. (11.4 cm.) larger
than the other forecastle knees. 124
Once the deck beams and their corresponding knees were installed the carlings and
ledges were fitted. Carlings were nearly square pieces of oak or fir fitted fore and aft in tiers
between the deck beams. They were scored 1½ in. (3.8 cm.) into the beams down to the same
level as the tops of the deck beams. Ledges were scored 1 in. (2.5 cm.) into the carlings
athwartship in the same manner that the carlings were notched into the deck beams. Carlings and
ledges were considered a means of adequately strengthening the deck structure while saving both
timber and weight (Figs. 16 and 17). 125
The carlings under the orlop deck were 6¼ to 6½ in. (15.9-16.5 cm.) wide and 4¼ to 4 ¾
in. (10.8-12.1 cm.) deep and the ledges were 3½ to 3 ¾ in. (8.9-9.5 cm.) wide and 3 in. (7.6 cm.)
deep. 126 The carlings under the lower deck were 6¼ to 6½ in. (15.9-16.5 cm.) wide and 5¼ to
5½ in. (13.3-14 cm.) deep and the ledges were 3¾ in. (9.5 cm.) wide and 3¼ to 3½ in. (8.2-8.9
cm.) deep (Fig. 17). 127 The carlings under the upper deck were 6¾ to 7 in. (17.1-17.8 cm.) wide
and 4¾ to 5 in. (12.1-12.7 cm.) deep and the ledges were 3½ in. (8.9 cm.) wide and 3 in. (7.6
cm.) deep (Fig. 16). 128 All carlings and ledges were secured in place by nails driven from below.
The quarterdeck and forecastle did not have carlings and ledges built into them. 129
As each level of deck beams was installed, the corresponding transoms, breast hooks,
and deck hooks were also installed. Breast hooks were large knees made of compass oak fixed
transversely to the inner face of the stemson and over the cant frames and internal planking on
45
either side of the bow. Their function was to tie together the bow assembly and to buttress the
bow against the impact of heavy seas. 130 Deck hooks were similar to breast hooks except that
they also supported the ends of the lower and gun decks. They rose 3 in. (7.6 cm.) above the
deck planking and had a rabbet cut into them to receive the hood ends of the deck planking. 131
There was one breast hook between the upper and lower deck and three below the lower deck.
The positioning and approximate dimensions of each breast hook, deck hook, and crutch can be
seen on Slade’s construction drafts (Fig. 5). 132 The gun deck hook was sided 11 in. (27.9 cm.),
molded 30 in. (76.2 cm.), about 16 ft. (4.88 m.) long, and was secured to the stem and frames
with eleven 1¼ in. (3.2 cm.) diameter iron bolts. 133 The lower deck hook was sided 11 in. (27.9
cm.), molded 30 in. (76.2 cm.), about 16 ft. (4.88 m.) long, and was secured to the stem and
frames with eleven 1¾ in. (4.4 cm.) diameter iron bolts. 134 The three breast hooks below the
lower deck were all sided 10½ in. (26.7 cm.); the upper was molded 30 in. (76.2 cm.) and was 14
ft. (4.27 m.) long, the lower was molded 27 in. (68.6 cm.) and was 12 ft. (3.66 m.) long, and the
middle one was somewhere in between. They were secured to the stemson and the sides of the
ship with ten 1¾ in. (4.4 cm.) diameter iron bolts. 135 No dimensions were found for the between
decks breast hook but, given the similarity of all of the other breast and deck hooks, it is
reasonable to assume that it was also sided 11 in. (4.88 m.) and about 16 ft. long.
Crutches were similar to the breast hooks except that they were placed on top of the
keelson from the mizzen step aft where they provided internal support between the after frames.
They were composed of compass oak to accommodate the sharp rise towards the stern. Slade’s
construction draft shows only one crutch half way between the mizzen step and the sternson
knee. It was sided 9½ to 10½ in. (24.1-26.7 cm.), molded about 29 in. (73.7 cm.), and the arm
lengths were 5 ft. 6 in. (167.6 cm.) on each side of the ship. 136
46
As previously discussed, transoms were beams or timbers extending across the stern
providing strength and giving shape to the stern. However, those transoms above the head of the
sternpost were notched over the forward face of the counter timbers instead of to the sternpost
assembly and fashion pieces. The lowest of these was the helm port transom, which on frigates
was simply the upper gun deck transom. 137 It was seated against the inboard faces of the counter
timbers at the height where the head of the rudder penetrated the stern. 138 It was 7½ to 12 in.
(19-30.5 cm.) deep, 13½ to 18 in. (34.3-45.7 cm.) broad, and its length was equal to the distance
between the side counter timbers. The underside of its after edge was bearded to conform to the
shape of the counter. It was bolted to the counter timbers with 7/8 in. (2.2 cm.) diameter iron
clench bolts. 139 The seat transom was at the height of the lower port sills and was so named
because there was usually a bench built under the stern ports and windows. It was 4½ in. (11.4
cm.) thick, about 12 in. (30.5 cm.) broad, and was scored and bolted to the stern timbers. It was
secured to the sides by two knees fastened with 7/8 in. (2.2 cm.) diameter iron bolts. 140 The
quarterdeck transom was 7 in. (17.8 cm.) deep, and was scored and bolted to the stern timbers
and kneed at each end. The fore and aft arms of the knees were long enough to receive iron bolts
forward of the gallery doors. 141
Riders were interior ribs or frames that reached from the keelson to the lower deck
beams. 142 However, the Shipbuilder’s Repository does not give dimensions for floor riders or
futtock riders for ships below 64 guns. 143 Furthermore, no riders are represented on the drafts of
Diana or Pandora. Therefore it is reasonable to conclude that Pallas did not have riders. 144
I.
External Planking
The overall integrity of the hull construction was dependent upon the quality of the
planking. As with the ceiling, the planking process began at the bottom of the hull and worked
47
upwards (with the exception of the previously-fitted main wales). For ease of planking the
garboard and second strake were usually left out until the end. This also facilitated clearing the
hull of construction debris. Planks of uniform length were carefully fashioned to bring as many
strakes as possible to the stern; however, the shape of the stern rarely permitted this, requiring
some strakes to be ‘dropped’ or terminated short of the post. Furthermore, the curvature at the
bow often required the placement of ‘stealers’ or short filling planks worked in between the
existing strakes. 145 However, neither Diana nor Pandora is depicted as having drop strakes or
stealers. 146 The planking was usually English oak (sometimes elm was used near the garboard)
laid in parallel strakes. The strakes were composed of 25 ft. (7.62 m.) long planks with squared
butt ends that were butted over frames to facilitate fastening. They maintained the same
thickness as the upper edge of the garboard strake all of the way up to the diminishing strake. 147
Charon had 3 in. (7.6 cm.) planking near the garboard and both Diana and Pandora are depicted
as having planking about 3 in. (7.6 m.) thick. 148 The strakes were fastened to the hull with iron
clench bolts at the butts and 1½ in. (3.8 cm.) diameter treenails through every frame. 149 Ollivier
observed that the hull planking was fastened entirely with treenails and that no iron nails or iron
bolts were used. 150 It is possible that this was the case in 1737 when Ollivier visited England, but
it is more likely that he simply observed a much greater number of treenails being used than
were employed in French shipyards and overlooked the relatively few iron clench bolts
employed at the butts.
Directly below the main wale were three rows of diminishing strakes that transitioned
from the thickness of the wale to the thickness of the planking. They were assembled from
parallel strakes 25 ft. (7.62 m.) long and 10 to 12 in. (25.4-30.5 cm.) wide. 151 Directly above the
wales was a strake, known as the black strake. Like the diminishing strakes, it transitioned the
thickness from that of the wales to that of the planking. It was 11 to 16 in. (27.9-40.6 cm.) wide
48
and about 1 in. (2.5 cm.) thinner than the wale. It was assembled with butts shifted away from
the scarfs of the wale, and from the gun ports.
The strakes between the main wale and the waist rail were about 3 in. (7.6 cm.) thick and
cut to fill the distance to the waist rail. 152 The waist rail was about 6 in. (15.2 cm.) wide, was set
about 21 in. (53.3 cm.) below the top-timber line, and ran parallel to the sheer. It extended the
full length of the side but was interrupted by gun ports except at the very stern. 153 The strakes
between the waist rail and the sheer rail were referred to as sheer strakes. Along with the string
of the waist, they provided most of the topside longitudinal strength and therefore were thicker
than the normal external planking. 154 The sheer strakes on Pallas were 4 in. (10.2 cm.) thick. 155
The sheer rail ran the full length of the side along the top-timber line and was approximately the
same width as the waist rail. Goodwin states that the channels interrupted the sheer rail.
However, the drafts of Brilliant show the channels seated into notches cut into the underside of
the sheer rail. The drift rails ran parallel to the sheer rail and stood slightly proud of the
quarterdeck and forecastle decks respectively. Because the quarterdeck rises away from the sheer
line, it was necessary for the aft drift rail to step up about 12 in. (30.5 cm.) a short distance aft
from the fore edge of the quarterdeck. The fife rail ran parallel to, and about 9 in. (22.9 cm.)
above, the drift rail. It was 2 to 3 in. (5.1-7.6 cm.) thick and had tenons cut to allow the
timberheads to pass through. 156 The planking of the stern and counters was 8 in. (26 cm.) wide
and 2½ in. (6.3 cm.) thick. It extended across the stern and was only interrupted by the stern
ports and the helm port. The beakhead bulkhead was planked in the same fashion. 157
The garboard strakes were made of English oak cut in 25 ft. (7.62 m.) lengths, 9¼ in.
(23.5 cm.) wide, and fastened together in the same fashion as the other external planking.
According to Peter Goodwin they were 7 in. (17.8 cm) thick at the lower edge and tapered to 3½
in. (8.9 cm.) thick at the upper edge. 158 They were bearded to fit the rabbet of the keel and the
49
joint was caulked and payed. The Admiralty drafts of Brilliant do not agree with Goodwin’s
calculations and neither do the drafts of Diana and Pandora. All three examples suggest a much
more uniform garboard, tapering only slightly from lower to upper edge. 159
J.
Bitts, Partners, Capstans, and Mast Steps
Before the decks were laid the bitts, capstans and mast steps were installed. 160 The riding
bitts were a heavy framework of timber, stoutly fixed to the structure of the ship, used to secure
cables and ropes. They straddled the centerline of the ship just aft of the foremast, and were
composed of a double set of bitt pins passing down through the lower deck and orlop deck, and
were bolted through the deck beams. The bitt pins were further buttressed by standards about
two-thirds the width of the pins, bolted through the forward face and down through the lower
deck beams. The after faces of the bitt pins were scored 2 ½ in. (6.3 cm.) deep about 18 in. (45.7
cm.) above the gun deck and heavy transverse cross beams were bolted to them. 161 The riding
bitts on Pallas are prominently portrayed on Slade’s construction drawings providing both
placement and dimensions (Figs. 5 and 11). 162
The aft bitt-pins were 13 in. (33 cm.) square from the heads to about 6 in. (15.2 cm.)
below the lower deck. From there, they tapered to about 10 in. (25.4 cm.) square where they
were stepped into the footwaling. The fore bitts were more lightly constructed, being about 11 in.
(27.9 cm.) square and terminating at the orlop deck. They were scored 2 in. (5.1 cm.) into the aft
face of the deck beams and secured with two 1 in. (2.5 cm.) iron bolts. The heads of both sets of
bitts stood 52 in. (132.1 cm.) above the deck. The distance between the heads of the bitts
athwartship was 38 in. (96.5 cm.). The cross beams of the bitts were 14 in. (35.6 cm.) fore and
aft and 12 in. (30.5 cm.) deep. The aft face of each cross beam had an additional elm cladding 5
in. (12.7 cm.) thick. The standards of the bitts were sided 10 in. (25.4 cm) and notched into the
50
decking 1 in. (2.5 cm.). The vertical arms reached the height of the upper edge of the
crossbeams. The fore and aft arms of the forward bitt standards reached the beam immediately
before the foremast and, with the carlings below, formed the foremast partners. The fore and aft
arms of the aft bitt standards butted against the aft face of the forward bitt pins. All of the
standards were fastened to the beams and carlings with 1 in. (2.5 cm.) diameter iron bolts. 163
Topsail and jeer bitts were the primary belaying points for securing running rigging.
They typically consisted of heavy bitt pins, although much lighter than the riding bitts, secured
to the deck beams, and had cross beams or pin rails for tying off ropes. The main topsail and jeer
bitts were mounted on the upper deck fore and aft of the mainmast respectively. The bitt pins
passed through the upper deck and were stepped into the lower deck; the pins for the jeer bitts
also supported the foremost quarterdeck beam. The bitt pins were 11 in. (27.9 cm.) square. The
cross pieces to the bitts were 5½ in. (14 cm.) deep, 7½ in. (19 cm.) wide, and were scored 1½ in.
(3.8 cm.) onto the bitt pins. The cross pieces to the gallows were 8 in. (20.3 cm.) wide, 14 in.
(35.6 cm.) deep, and 10 ft. (3.05 m.) long. The upper side was 6 ft. 5 in. (1.96 m.) above the
deck. 164 The fore topsail and jeer bitts were mounted on the forecastle fore and aft of the
foremast respectively. The bitt pins passed through the forecastle deck and were stepped into the
upper deck. The bitt pins were 9 in. (22.9 cm.) square. The cross pieces were 5 in. (12.7 cm.)
deep, 7 in. (17.8 cm) wide, and scored 1 in. (2.5 cm.) onto the bitt pins. Their heads were 39 in.
(99.1 cm.) above the deck. 165 No information was available regarding the dimensions of the
brace bitts. It seems that they could be positioned either forward or aft of the mizzenmast on the
quarterdeck and, because they were not tied to the deck beams, usually had standards supporting
each bitt pin. The standards were always placed on the side of the bitts away from the mast. 166
Mast steps were usually cut from a single large piece of oak. They were notched on the
underside to sit over the keelson and had a mortise cut in the upper surface to receive the tenon
51
on the mast’s heel. The placement, fore and aft siding, and depth dimensions of the mast steps
are represented on Slade’s construction drafts (Fig. 5). The main mast step was sided 27 in. (68.6
cm.) and was 24 in. (61 cm.) high. 167 The athwartship dimension is unknown but Goodwin states
that it must slide clear of the stanchions of the pump well. The foremast and mizzenmast steps
both took the form of additional crutches. The fore mast step was sided 23 in. (58.4 cm.), molded
24 in. (61 cm.) amidships, and was 8 to 10½ ft. (2.44-3.2 m.) long athwartship. The mizzenmast
step was sided 15 in. (38.1 cm.), molded 24 in. (61 cm.) amidships, and the athwartship arms
were each 5 ft. 6 in. (167.6 cm) long. 168 The step of the bowsprit was composed of two pieces of
oak 10 in. (25.4 cm.) thick, rabbetted into each other and bolted through with two 1 in. (2.5 cm.)
diameter iron bolts. Exact information could not be found regarding the athwartship breadth of
the bowsprit step, but it was probably about 3½ ft. (1.07 m.). The step reached from the lower
deck beam directly before the foremast to the upper deck beam above, was notched into both,
and secured to the beams with 1 in. (2.5 cm.) diameter iron bolts. 169
The longitudinal mast partners were essentially oversized carlings on either side of the
mast. The foremast partners on the lower deck were 13 in. (33 cm.) wide and 8 in. (20.3 cm.)
deep. The standards for the foremost riding bitts composed the upper portion of the partners, and
rabbets were cut into the upper surface deep enough to receive cross chocks 5 in. (12.7 cm.)
thick. The main mast partners on the lower deck were 14 in. (35.6 cm.) wide and 13 in. (33 cm.)
deep. Their upper sides stood 6 in. (15.2 cm.) proud of the deck beams and were bolted through
with 1 in. (2.5 cm.) diameter iron bolts. Rabbets were cut into the upper surface deep enough to
receive cross chocks 6 in. (15.2 cm.) thick. The mizzen partners on the lower deck were 5 in.
(12.7 cm) thick and 38 in. (96.5 cm.) wide. 170 The foremast partners on the upper deck were 12
in (30.5 cm.) wide and 7 in. (17.8 cm.) deep. 171 The mainmast partners on the upper deck were
15 in. (38.1 cm.) wide, 14 in. (35.6 cm.) deep, and their upper sides were 6½ in. (16.5 cm.)
52
above the deck beams. The mizzen partners on the upper deck were 4½ in. (11.4 cm.) thick and 4
ft. 6 in. (1.37 m.) wide. 172 The partners to the capstans were 5 in. (12.7 cm.) wide and 5¼ in.
(13.3 cm.) deep. 173
The capstans were heavy mechanical winches whose primary function were to haul in or
veer out the anchor cables, but they would have also been employed for other heavy lifting such
as raising masts and yards, moving heavy loads into the holds, and winding or kedging the ship
(Fig. 20). The two double capstans on Pallas are prominently portrayed on Slade’s original
construction plans providing both absolute placement and dimensions (Fig. 5 and 11). 174 Double
capstans consisted of two central barrels mounted on a spindle that passed between the upper and
lower decks and were firmly secured to the deck beams of both. A ‘drumhead’ was mortised to
the top of the barrel, at about chest height on the upper deck, and a ‘trundle head’ was fixed to
the barrel at the same height on the lower deck. Mortises 3½ to 4½ in. (8.9-11.4 cm.) square
were cut into the edges of each, typically twelve in the drumhead and ten in the trundle head,
into which capstan bars could be inserted to turn the capstan. Flat timbers called whelps radiated
from the barrel (six on the upper and five on the lower) and served to increase the diameter of
the barrels and hold cables more securely. They were shaped to prevent the cables riding up too
far and interfering with the men pushing the bars. At the base of the capstan there was a simple
ratchet device called a ‘pawl ring’ that prevented the capstan from ‘walking back’ or loosing
ground. The barrels of Pallas’ capstans were 20 in. (50.8 cm.) in diameter; the heads were 45 in.
(114.3 cm.) in diameter and 9 in. (22.9 cm.) thick, and the whelps were 10 in. (25.4 cm.) thick.
The capstan bars were made of English ash. They were 11 ft. 11¾ in. (3.65 m.) long, 3½ to 4½
in. (8.9-11.4 cm.) square, and had a slot cut into the outer end, about 1/3 the width of the bar, to
receive the ‘swifter.’ The swifter was a rope rigged around the periphery of the capstan bars that
secured all of the bars in place and permitted additional men to work the capstan when needed.
53
For more specific detail both Lavery and Goodwin offer comprehensive studies of the historical
evolution and mechanics of capstans and their related accessories. 175
Pallas carried 10 cables: seven 100 (189.9 m.) fathoms long and 16½ in. (41.9 cm.) in
circumference, one 100 fathoms (189.9 m.) long and 9½ in (24.1 cm.) in circumference, one viol
44 fathoms (80.5 m.) long and 10 in. (25.4 cm.) in circumference, and one messenger 44 fathoms
(80.5 m.) long and 10 in. (25.4 cm.) in circumference. 176
K. Decking
The decking was typically laid in parallel strakes from the centerline of the ship
outwards. The strakes were about 25 ft. (7.62 m.) long and 9 to 12 in. (22.9-30.5 cm.) wide
depending on their location and the curvature of the sides. Deck planking was made from oak,
elm, or Prussian or ‘Danzig’ deal (high quality Baltic pine). Oak was used near the ship’s sides,
and around capstans and hatchways where strength was required, elm or deal was used for the
remainder. 177
The upper deck was the first to be planked so that work could continue uninterrupted by
weather. The decking was worked around the various openings, and oak coamings and head
ledges were installed around the hatches, gratings, ladder ways, and scuttles to keep water from
reaching the decks below. The head ledges were 5 in. (12.7 cm.) wide, the coamings were 6 in.
(15.2 cm.) wide, and both were 9 in. (22.9 cm.) high (Fig. 5 and 17). Outboard of the hatch
coamings, on either side of the ship, three courses of binding strakes were laid. Unlike the other
decking they were notched down over the deck beams binding them together and contributing to
the longitudinal strength of the hull. They were probably oak, cut 10 to 14 in. (25.4-35.6 cm.)
wide at midship and narrowing towards the bow and stern. They were 4 to 4 ½ (10.2-11.4 cm.)
thick and were notched 1 to 1 ½ in. (2.5-3.8 cm.) onto the beams. The next fourteen courses of
54
planking were fir or deal, cut 3 in. (7.6 cm.) thick and 6¾ to 7 in. (17.1-17.8 cm.) wide at
midship, and narrowing towards the bow and stern. The binding strakes were composed of 25 ft.
(7.62 m.) long planks joined with butts located over deck beams. They were laid in courses of
four strakes in a specific pattern so that each butt was shifted one beam away from the previous
butt (Figs. 16, 17 and 19). 178 The outermost plank, parallel to the ship’s side and waterways, was
called the margin plank. Notched to receive the butt ends of diminishing decking strakes, its
purpose was to prevent the need for these strakes to be tapered to a point where they met the side
of the ship (Fig. 16). On White’s reconstruction of Diana, he has combined the margin strakes
and waterways into single strakes 15 in. (38.1cm.) wide. This may not have been the case on
Pallas but the Diana reconstruction was the only reasonable parallel found that provided decking
detail. 179 Once the upper deck planking was completed, a large timber called the collar beam was
placed on top of the decking athwartship between the two foremost frame timbers. It was
probably the same dimensions as the other upper deck beams. The collar beam’s primary
function was to serve as a footing for the beakhead bulkhead, but it also provided additional
support to the underside of the catbeam. It had eight 4½ in. (11.4 cm.) square mortises cut into
its upper face to step the stanchions of the beakhead bulkhead. 180
The decking on the lower deck was carried out in a similar manner. The head ledges
were 5 in. (12.7 cm.) wide and the coamings were 7½ in. (19 cm.) wide. Because they were
below deck, the head ledges and coamings were only 3 in. (7.6 cm.) high, except for those
around the bread room scuttle, which were 7½ in. (19 cm.) high. The three binding strakes were
12 in. (30.5cm.) wide at midship, 3½ to 4 in. (8.9-10.2 cm.) thick, and were notched down onto
the deck beams 1 to 1½ in. (2.5-3.8 cm.). The next eight strakes were 8 to 8½ in. (20.3-21.6 cm.)
wide at midship and 2½ in. (6.3 cm.) thick. The outer two courses of planking on the lower deck
were composed of double strakes of oak 12 in. (30.5 cm.) wide and assembled top and butt
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fashion. Like the upper deck, the margin plank and waterways were combined into a single
strake 21 in. (53.3 cm.) wide. 181
The planking on the forecastle and quarterdeck was much more basic. The head ledges
were 4½ in. (11.4cm.) wide and the coamings were 5-6 in. (12.7-15.2 cm.) wide. They were only
3 in. (7.6 cm.), high except for those around the captain’s cabin skylight, which were 4½ in.
(11.4 cm.) high. The decking was composed of forty uniform strakes about 8 in. (20.3 cm) wide
at the midship end and tapering towards the bow and stern. The forecastle strakes were 2½ in.
(6.3 cm.) thick and the quarterdeck strakes were 3 in. (7.6 cm.) thick. Like the upper and lower
deck, the margin plank and waterways were combined into a single strake 9 in. (22.9 cm.) wide.
All deck planks were fastened to the deck beams and carlings with iron spikes, dumps or
treenails. 182
Once the forecastle was decked, the catheads were installed. Catheads were strong
timbers projecting out over both sides of the bow from the forecastle, providing clearance for the
anchor flukes when raising and lowering the anchor. They had three sets of sheaves at the end of
each arm to which the cat block was rigged. The catheads were 14 in. (35.6 cm.) fore and aft and
12 in. (30.5 cm.) deep. The steeve of the catheads can be determined from Slade’s drafts. The
inner arms of the cathead rested on the forecastle and were bolted to the foremost forecastle deck
beam or catbeam. The outer arms were supported from underneath by a hanging knee that
transitioned into the rail of the beak head. 183
The planking on the orlop decks differed from the other decks. Rather than being laid in
25 ft. (9.45 m.) lengths over several deck beams, the orlop planks were cut into short, easily
removable planks that filled the spaces between beams. They were seated onto ledges cut into
the forward and after edges of the beams, but were not secured into place. This allowed
convenient access to stores in the hold beneath. The planks were 9 in. (22.9 cm.) wide and 1 in.
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(2.5 cm.) thick, and battened together into pallets that could be easily shifted or removed.
Removable gratings were also frequently used in the orlop decking to provide ventilation and
light to the hold. 184
In the open space between the fore and aft orlop decks, there were five additional
transverse beams that supported the cable tier where the ship’s large cables were stored (Fig. 5).
The cable tier was an open platform, centrally located low in the ship, where the cables could
drain into the bilges while remaining easily accessible. It extended from the deck beam
immediately abaft the pump well to just under the forward capstan. It was decked in a similar
fashion to the other orlop platforms. Additional beams 4 to 6 in. (10.2-15.2 cm.) square were
placed over the deck to lift the cables and allow for ventilation and drainage. A row of
stanchions supporting heavy wooden gratings divided each side of the cable tier to prevent the
cables from shifting while still permitting ventilation. 185
Access to the forecastle and quarterdeck was provided by stairs located on each side of
the ship, near the bulwarks. It is unclear weather Pallas was ever fitted with gangways
connecting the forecastle to the quarterdeck. However, it was common practice at the time to fit
narrow gang boards about 18 in. (45.7 cm.) wide, supported by small wooden or iron knees,
along the planksheer. 186
L. Hatches, Gratings, Ladder Ways and Scuttles
The placement and dimensions of the various hatches, gratings, ladder ways, and scuttles
are prominently portrayed on Slade’s various deck plans for Pallas (Figs. 16, 17 and 19). 187 Most
hatches had gratings that seated onto sills cut into the inner edge of the coamings. Gratings
provided footing over the hatchways and allowed air and light to reach the lower decks. In poor
weather they could be covered with canvas to keep out water. Some gratings were permanent like
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the steam grating over the stove; others like those over the main hatches were only removed during
loading or unloading. The gratings for the ladder ways were removed during the day but were
usually replaced at night. They consisted of a lattice of ledges crossed by battens. The ledges were
usually about 3 in. (7.62 cm.) square and were oriented athwartship. The battens were the same
width but only about ¾ in. (19 cm.) deep except for those at the edges that formed the frame of the
grating. They were notched into the top of the ledges to their full depth leaving 3 to 4 in. (7.6210.2 cm.) square holes in the lattice. Like the decks, the gratings were cambered towards the
centerline of the ship, as were the head ledges. 188
M. Pillars or Stanchions
Pillars or stanchions were placed under the deck beams to support the decks above. The
exact number and placement on each deck is unclear. However, Ollivier states that pillars
supported nearly all of the gun deck beams. 189 On the other decks they were probably placed
under every second deck beam. They were placed as close as possible to the centerline of the
ship to focus the load above the keel and to leave as much room as possible free for the working
of the guns, capstans, and messenger cable. They were not permanently fixed in place, but
instead were stepped into mortises cut into the decking or the top of the keelson. The tenons
were 1½ in. (3.8 cm.) square and were chamfered at the forward edge to facilitate removal and
replacement. 190 The pillars in the hold under the orlop and gun deck beams were 7½ in. (19 cm.)
square at the lower end and 6¼ in. (15.9 cm.) square at the upper end. 191 The pillars on the upper
deck were 6¾ in. (17.1 cm.) square at the lower end and 6½ in. (16.5 cm.) square at the upper
end. 192
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N. Quarter Galleries
The quarter galleries were mounted on either side of the extreme stern. They provided
light to the great cabin, allowed the captain to observe the sails without going on deck, and the
portside gallery served as the captain’s private head. 193 They were not structurally fixed to the
hull, but instead were supported by stout ornately carved oak brackets, called the lower
finishings, bolted to the ship’s sides. The floor platforms or ‘stools’ were constructed of 3 to 4 in.
(7.6-10.2 cm.) thick planks bolted together and cut to the floor plan of the gallery. The stools
continued the camber of the main deck, and the inner edges were chamfered to meet the angle of
the ship’s sides. The stools were secured to the tops of the lower finishings with iron dumps
driven through from above. This formed the foundation for the gallery structure. Next, vertical
timbers called quarter posts were erected at the aft outboard corners of the stools and bolted into
position. The quarter posts were assembled in the same fashion as the counter timbers. They
continued the shape of the counters to the extremities of the galleries and were supported by a
series of molded rails worked across the aft faces of the stern counter timbers. The upper stools
or ‘deck heads’ were constructed in the same manner as the lower stools and were bolted to the
quarter posts and the sides of the ship. The upper finishings were shaped to conform to the ship’s
sides and bolted to the stools and the sides. A single quarter rail was installed between the
quarter posts and the forward edge of the galleries on each side, about 18 in. (45.7 cm.) above
deck level. They were about 12 in. (30.5 cm.) wide and 8 in. (20.3 cm.) deep, and the inboard
edges were rabbetted to form the lower windowsills. Another lighter quarter rail was mounted
beneath the deck heads on each side and rabbetted to form the upper windowsills. The area
between the lower stools and the quarter rails was planked horizontally with planks 4 to 6 in.
(10.2-15.2 cm.) wide and 1½ to 2 in. (3.8-5.1 cm.) thick. The windows and mullions between
them were installed and fixed in place with iron spikes. Typically only the middle window was
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real; the fore and aft ones were false lights painted to look like windows. The same was true of
the windows across the stern; the two outer windows and two chase port lids on either side of the
center window were false lights. 194
Once the galleries were finished the taffrail and quarter pieces could be mounted across
the stern. These defined the shape of the upper part of the stern and were decorated with intricate
molding and carvings. They probably also contributed structurally to the stern and quarter
gallery assembly. Two additional quarterdeck chase ports were cut into the taffrail directly above
the upper deck chase ports. These are clearly visible on Slade’s construction draft of Brilliant. 195
Finally, the taffrail fife rail was installed across the peak of the stern.
A single stern lantern was mounted on an angled bracket projecting from the after face
of the taffrail amidships. Decorative style may have varied according to the tastes of the builder
but lanterns were usually made from iron or brass, gilt or painted, with glass panes. They were
hexagonal in shape, tapering slightly towards the base. The lantern typically housed an oil lamp
the burned whale oil or colza (rape seed oil). A single lantern of this type can be seen on a model
of the 32-gun frigate Lowestoft, (1761) and there is no reason to expect Pallas to have been very
much different. 196
O. Rudder and Tiller Assembly
The overall shape and dimensions for the rudder can be seen on Slade’s draft of Pallas’
sister ship, Brilliant (Fig. 3). 197 Specific details for the rudder fittings proved more difficult to
locate; however, all of the most reliable sources, extant period models, and period iconography
agree that rudders and rudder fittings on British ships of the line changed very little between
1650 and 1800. 198 White’s reconstruction was chosen as an acceptable parallel for Pallas. 199
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Although Diana is considerably later than Pallas, her rudder details differ very little from those
seen on a 1732 model of the 44-gun Centurion. 200
The rudder on Pallas was made from four parts. The ‘main piece’ was the primary
structural element. It was of oak, had the same siding as the sternpost and extended the full
length of the rudder. The fore piece or ‘bearding’ was made of elm and extended from the base
to about half the height of the rudder. It was beveled 45 degrees on both its fore edge to allow for
the movement of the rudder. The two after pieces were made of fir and gave fore and aft breadth
to the foot of the rudder. At the foot and the after face, narrow fir strips were fixed to protect the
assembly from damage. The rudder head was square with rounded corners and was bound with
four iron straps 3 to 4 in. (7.6-10.2 cm.) wide and ½ to ¾ in. (1.3-1.9 cm.) thick. The rudder was
mounted to the sternpost with six hinges or gudgeons. Notches were cut into the rudder’s
bearding at the height of each gudgeon and the pintles were set flush with the fore edge. The
pintles were 2¾ in. (7 cm.) in diameter and 11 in. (27.9 cm.) long, and the sockets in the
gudgeons were the same diameter. The pintle straps were 3¾ in. (9.5 cm.) wide, were only
slightly shorter than the full breadth of the rudder assembly at their respective stations, and
served to bind the whole structure together. The gudgeons were mounted over the sternpost and
stern planking, the arms splayed to conform to the shape of the stern. The gudgeon arms were
3¾ in. (9.5 cm.) wide and the arm length depended on the height at which they were set. The
lowest had arms 5 ft. 10 in. (1.78 m.) long; the length diminished towards the rudder head to 3 ft.
8 in. (1.12 m.) long at the second uppermost gudgeon. The head of the ‘main piece’ had two
tiller holes. The tiller was normally mounted in the lower hole and passed through the helm port
just below the gun deck transom. The upper tiller hole could be accessed through the rudder head
cover in the great cabin if an auxiliary tiller needed to be rigged (Fig. 5). 201
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The tiller was made of oak, ash, or pine; ash was preferred due to its flexibility. It was
19 ft. (5.79 m.) long, 9½ in. (24.1 cm.) square at the widest point, and 7½ in. (19 cm.) square at
the foremost end. 202 It swung just below the upper deck beams and was suspended from the
quadrant or sweep by a gooseneck bracket at its forward end. The sweep was a curved track or
race fixed under the deck beams beneath which the fore end of the tiller traveled. In the forward
face of the sweep a groove was cut and set with lignum vitae or iron rollers to allow for the travel
of the tiller ropes. A shelf was cut along the after face of the sweep along which the gooseneck
of the tiller traveled. Two iron bands, with two eyebolts each, were fitted around the forward end
of the tiller and two more were fixed to the sides of the tiller about two-thirds the distance to the
rudder head. 203 All sources agree that the rigging of the tiller ropes and tensioning tackle on large
warships was consistent throughout the 18th century.(Fig. 21). 204
P. Head
The knee of the head was a large flat bracket extending forward from the stem of the
ship that supported the head and provided a rigid foundation for the bowsprit, gammoning and
the bobstays (Fig.6). The shape and sided dimensions of the knee of the head can be clearly seen
on Slade’s drafts of Brilliant (Fig. 3). The molding was 12½ in. (31.7 cm.) at the stem just above
the cheek. It was assembled from six pieces of oak coaked or tabled and bolted together: the
lacing, the choke piece, the gammon piece, the gammoning knee, the bobstay piece, and the
gripe. At the base of the knee of the head, the gripe was notched into the leading edge of the keel
and keelson and secured to both the stem and keel with horseshoe plates placed on either side
and bolted together through all three. 205
Next, the cheeks were attached. The cheeks were two large double sets of oak knees that
gave lateral support to the knee of the head and formed the foundation of the head. They also
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contributed to the ornamentation, forming a graceful transition from the knee of the head to the
sides of the ship just below the hawseholes. The area between the cheeks was closed with filling
pieces, and timbers called wash cants further contoured the flat faces on the underside of the
cheeks. Finally a contoured bolster was placed around each of the hawseholes.
Once the knee of the head and the cheeks were attached, the head was assembled. The
head was the open working area forward of the beakhead bulkhead and above the bowsprit and
cheeks of the bow. It was composed of a complex assembly of relatively lightweight timbers
whose purpose was as much aesthetic as functional. The lower rail and head rail formed a
gracefully rising triangular basket, crossed by transverse head timbers, and floored with a mesh
of carlings and ledges. The shape and dimensions of the head from the sheer perspective are
clearly visible on Slade’s draft of Brilliant (Fig. 3). A similar example can be seen in White’s
reconstruction of Diana. Within the head on either side of the bow were two circular toilet
facilities that projected over the edge of the bow. Further forward, out over the water and on
either side of the bowsprit, were two more open-air seats of ease. 206
Finally, the figurehead was installed. The figurehead was the primary focus of the ship’s
ornamental motif and was usually symbolic of the ship’s name. The name Pallas most likely
refers to the Greek goddess Athena, but it could also be a reference a mythological titan of the
same name. Figureheads were gilded until 1760 after which they were painted with bright colors.
Presumably, Pallas would have had a gilded figurehead when launched in 1757, however it is
possible that is was refinished with paint at a later date. 207 The figurehead was mounted against
the fore edge of the main piece, atop the bobstay piece and bolted to both.
As work progressed, caulkers went to work on the areas already completed. All of the
ship’s external planking and decking was caulked inside and out. This was done by forcing
oakum—strands of old rope covered with pitch or resin—into every seam. Once this was done
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the ship’s bottom was graved with ‘black stuff,’ ‘white stuff,’ or ‘brown stuff’—various
mixtures of tar, pitch and brimstone—and the hull was ready to launch. Pallas was launched
before the advent of copper sheathing, but was coppered later in her career. The coppering will
be discussed below. Finishing work was usually carried out after launch enabling shipyards to
free up the slipways for new hulls to be started.
Finishing and Fittings
A. Bulkheads
Bulkheads were the various partitions that separated one part of the ship from another.
Slade’s construction drafts provide his recommended locations and dimensions for the various
bulkheads and compartments on Pallas. Furthermore, the functions of the individual
compartments are clearly labeled on the deck plans. 208 Above the waterline the bulkheads were
little more than lightweight screens made of canvas stretched over batten frames. This facilitated
their swift removal and stowage in the hold when clearing for action. 209
The berthing deck contained the various officers’ cabins and the pantry, all placed on
either side of the ship in the stern. The four cabins on the starboard side housed the carpenter, 1st
lieutenant, master, and gunner. The four on the port side housed the boatswain, 2nd lieutenant,
surgeon, and purser. In the center of the stern, built around the mizzenmast, was the pantry
where special food items were kept secure from the crew. There was no enclosed wardroom on
Pallas, but the space between and aft of the cabins would have served as the officers’ mess and
social area. In the extreme stern, aft of the pantry, was the scuttle to the bread room (Fig. 17). 210
On the upper deck the only substantial bulkheads defined the captain’s cabins in the
stern. These included the captain’s coach (administrative office) just aft of the mizzenmast on
the port side, his bedroom on the starboard side, and the great cabin extending the breadth of the
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ship in the stern. Slade’s drafts also show a small partition with double doors just aft of the stove
under the forecastle. This was almost certainly a windbreak to shelter the stove, cook, and food
from the elements. 211
The bulkheads below the waterline were permanent and more substantial. The principle
compartments in the hold were the magazine, shot locker, fish room, bread room, and spirit
room. The aftermost bulkhead was placed at the aftermost beam of the orlop deck creating the
bread room in the extreme stern. It was constructed of pine planking 6 in. (15.2 cm.) wide, and 3
in. (7.6 cm.) thick, worked horizontally over a series of pine or oak stanchions, 4 to 6 in. (10.215.2 cm.) square and tenoned into the orlop beam above and the ceiling planking below. The
planks were rabbetted along their edges and battens were worked over the seams to keep water
out. Raised palleting, assembled from ledges and battens in the same fashion as the hatch
gratings, was laid on the floor to help keep the bread dry. Access to the bread room was from
above through the scuttle in the berthing deck. The remaining bulkheads were constructed in the
same manner. The fore bulkhead of the fish room formed the aft bulkhead of the spirit room and
the fore bulkhead of the spirit room formed the aft bulkhead of the main hold. 212 The forward
part of the hold was devoted to the magazine, which will be addressed in a separate section
below.
On the orlop deck were individual storerooms for the various ships’ fittings. The
bulkheads were built in much the same manner but were of lighter construction than those in the
hold. The stanchions were 4 in. (10.2 cm.) square, and were constructed of fir or pine. The
planking was 8 in. (29.3 cm.) wide and 1½ in. (3.8 cm.) thick. It was rabbetted like the bulkhead
planking in the hold, and was also quite often rabbetted into the outer edges of the stanchions as
well. On the starboard side of the fore orlop deck, working forward, were the block room and the
carpenter’s storeroom. On the port side were the boatswain’s storeroom and a sail room.
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Between these storerooms and above the magazine was another sail room. An enclosed
passageway led around the starboard side of the central sail room to a stairwell that provided
access to the magazine below. Another passageway on the port side led beyond the central sail
room, past the light room for the magazine, to the gunner’s storeroom in the extreme bow. On
the starboard side of the after orlop deck were the slop room and, further aft the steward’s room.
On the port side were the marine’s clothing room and the captain’s storeroom. Situated in the
floor between the aft storerooms were hatchways to the fish room and spirit room. 213
B. Magazine
Magazines were closed storerooms in which the ship’s powder was kept. They were
strongly secured against both fire and moisture. The bulk of the powder was stored in barrels or
casks in the magazine. At the forward end of the magazine, elevated a little above the palleting
was the filling room where cartridges were filled and stored. Both rooms were lighted through
glass windows or light scuttles from an adjacent and securely isolated light-room. The magazine
on Pallas was located just aft of the foremast. The exact placement, layout and dimensions of the
magazine are clearly depicted in Slade’s construction drafts (Figs. 5 and 18). 214
The floor of the magazine was elevated above the bottom of the hold and supported by a
series of transverse beams. Pine planking 12 in. (30.5 cm.) wide and 3 in. (7.6 cm.) thick was
laid across the beams and fastened with copper dumps. On top of this the palleting flat was
assembled. A lattice of beams and carlings, each 4½ to 4¾ in. (11.4-12.1 cm.) square, were
notched together dividing the floor into 3 ft. (91.4 cm.) square compartments or scuttles 4½ to
4¾ in. (11.4-12.1 cm.) deep. A 1 to 1 ½ in. (2.5-3.8 cm.) deep rabbet was cut into the upper
edges of each scuttle. Covers were assembled from four 3 ft. (91.4 cm.) long, 9 in. (22.9 cm.)
wide and 1 to 1 ½ in. (2.5-3.8 cm.) thick pine planks battened together. The covers were not
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fastened down, allowing access for the removal of accumulated loose powder. Goodwin states
that the scuttles were left empty to enable airflow to cool the magazine. Lavery states that the
scuttles were filled with charcoal to absorb moisture. 215
The athwartship bulkheads of the magazine were constructed in the same fashion as the
other bulkheads in the hold. Rabbetted planks 2 in. (5.1 cm.) thick were laid over stanchions 4¾
in. (12.1 cm.) square, tenoned into the deck beams and ceiling, and the seams were covered with
thin battens to keep out moisture. The side bulkheads were constructed differently. Stanchions
12 in. (30.5 cm.) fore and aft and 6 in. (15.2 cm.) wide were placed approximately 27 in. (68.6
cm.) apart. Paneling 3 in. (7.6 cm.) wide was then worked into rabbets cut in the fore and aft
faces of each stanchion. 216 The whole structure was plastered and single lined with slit deal on
the outside and plastered and double lined with slit deal on the inside. All exposed metal capable
of causing a spark was puttied over. 217 Access to the magazine was through a door on the orlop
deck leading to a ladder down to the filling room. Just above the door was a small scuttle
through the lower deck between the aft most riding bit pins (Figs. 17 and 18).
C. Shot Lockers
The shot lockers were placed directly before and abaft of the pump well and the main
mast. The reason for this was to keep the weight of the shot as low and as close to the midship
centerline as possible. The pump well on Pallas was 6 ft. 8 in. (2.03 m.) square. The four
bulkhead stanchions that formed the corners of the pump well were 6 to 8 in. (15.2-20.3 cm.)
square and were tenoned to the ceiling of the hold and the orlop deck beams above. The shot
lockers shared the athwartship bulkheads of the pump well, were 22 to 24 in. (55.9-61 cm.) fore
and aft, and about 6 ft. (1.83 m.) high. Stanchions 6 to 8 in. (15.2-20.3 cm.) square supported the
outer corners but did not reach the deck beams above. Transverse stiffening timbers 3 to 4½ in.
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(7.6-10.2 cm.) square were worked across the heads of the corner timbers and across the
transverse bulkheads of the well. The well and shot lockers shared common sidewalls, and all
three compartments were planked as a single unit. The planking on the well bulkhead and the
shot lockers was 9 in. (22.9 cm.) wide and 2½ in. (6.3 cm.) thick. The nails on the outer
bulkheads of the shot lockers were canted to prevent the weight of the shot from forcing out the
sides of the locker. The area between the top of the pump well and the underside of the lower
deck was enclosed on all sides with horizontal louvers. Hinged panels gave access through the
top of the lockers, and the planking on the fore and aft bulkheads was probably removable to
provide ready access as the level of shot went down during battle. Each locker was divided
vertically to store different types of shot. 218 Some round shot was stored in shot garlands placed
between the guns; garlands were racks with round holes cut into the top to prevent the shot from
rolling in heavy seas.
Pallas carried twenty-six hundred 12-pound round shot (1820 in home waters), one
hundred and eighty-two 12-pound grape shot, seventy-eight 12-pound double shot, one thousand
6-pound round shot (700 in home waters), seventy 6-pound grape shot, seven hundred and
twenty ½-pound round shot, and one hundred and forty-four ½-pound grape shot. 219
D. Ordnance
Pallas was originally armed with a main battery of twenty-six 12-pound guns, 8½ ft.
(2.59 m.) long, mounted on the gun deck, eight 6-pound guns, 6 ft. (1.83 m.) long, on the
quarterdeck, two 7½ ft. (1.9 m.) long 6-pound, bow chase guns on the forecastle, and eight to
twelve ½-pound swivel guns mounted along the forecastle and quarterdeck rails (Fig. 22). The
12-pound guns available when Pallas was commissioned were intended for the relatively
spacious upper decks of much larger warships. They proved to be too long for the close, narrow
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decks of the new frigates and within a year the Ordnance Board had introduced a specially
designed, 7½ ft. (2.29 m.) version. All frigates were gradually rearmed with the new 12-pound
‘shorts’. 220 Gunlocks were not introduced for general use by Royal Navy warships until the late
1770’s and it is unlikely that Pallas was fitted with them given her age and declining
condition. 221 Instead, Pallas’ gunners likely used the centuries-old linstock and slow-match to
manually ignite the guns’ priming. The 12-pound guns was considered a man killer but not a
ship killer, whereas the 18-pound guns that followed could inflict severe damage to any vessel.
Nevertheless, the 12-pound guns remained a significant threat to small warships, shore
installations, and especially merchant shipping and privateers. 222 By the middle of the 18th
century 6-pound guns were obsolete. They were still mounted on the forecastle and quarterdecks
of most warships but lacked the power to inflict significant damage. 223 The ½-pound swivel guns
were strictly anti-personnel weapons, intended for use in close combat.
The primary purpose of the gun carriage was to support the gun. The secondary purpose
was to facilitate elevation and traversing of the gun. And thirdly they absorbed the recoil and
facilitated the loading process. They were constructed of elm and were always painted, usually
ochre red. 224 Gun carriages were inefficient by design to retard the recoil as much as possible. 225
The design and the proportions for the carriages of each weight of gun had been firmly defined
by 1725 and would remain little changed for the remainder of the century. The best nearcontemporary source available to us is John Muller’s A Treatise of Artillery, 1780, in which
there is an excellent engraved schematic of a generic naval gun carriage and its component parts
(Fig. 23). 226 The 6-pound and 12-pound guns were both mounted on this type of carriage, the
only difference being in their relative size. The ½-pound swivel guns were mounted on iron
crutches inserted into fixed wooden stocks along the rails; two on each side of the forecastle and
four on each side of the quarterdeck. 227
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Two eye bolts and two ring bolts were mounted at each gun port for the gun
tackle and another single ring bolt was secured through the deck and deck beam near the
centerline of the ship, behind each gun, for the train tackle. The bolts on the gun deck
were 1 in. (2.5 cm.) in diameter and the rings were 4½ in. (11.4 cm.) inside diameter and
those on the quarterdeck and forecastle were ¾ in. (1.9 cm.) diameter and the openings
in the rings were 3¼ in. (8.9 cm.). 228
Like the gun carriages, the function and arrangement of the gun tackle had been
formalized early in the century and was consistent throughout all Royal Navy warships of the
period. Falconer provides an excellent, nearly contemporary depiction of the guns and gun tackle
in their action and storage configurations (Fig. 24). 229 This is supplemented by Adrian Caruana
who defines in detail the various elements of the gun tackle and their role in the operation of the
guns. 230
It was difficult to determine the exact details of the gun port lids. However, the most
common type for the period was the standard single lid, hinged to open up and out. Two hinges
extended the length of the lid and served to reinforce it structurally. 231 Two good period
examples of this type of lid can clearly be seen on a 1730s Admiralty model of a 70-gun ship and
on the detail model of Diana. 232 With the exception of slight artistic differences, both examples
are virtually the same in both form and function.
E. Pumps
Whether from leaks, rain, water washing over the deck, or simple accumulation of sea
spray, all ships continuously took on water. The camber of the upper deck directed most shipped
water to scuppers in the ship’s sides and back to the sea. Nevertheless, some water always found
its way below decks and accumulated in the bilge. Furthermore, heavy seas, or battle damage
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could breach the hull below the waterline. Whatever the cause for water accumulation, all ships
required an effective means of removing water from within their hulls.
Suction pumps were rarely used on larger warships where chain pumps were more
efficient and manpower plentiful. However, due to the complexity of early chain pumps they
were more prone to breakdown, were more difficult to repair, only capable of drawing water
from the bilges, and were incapable of producing pressure. Suction pumps could be rigged to
draw clean water from other sources or directly from the sea. Therefore, suction pumps were
retained as auxiliaries and for secondary functions such as washing the decks and firefighting. 233
The pumps and pump wells from HMS Charon were both found to be partially intact. The wells
for the suction pumps were located on either side of the keelson, just aft of the mainmast. They
were constructed from a log bored out to a diameter of 2¾ in. (7 cm.). The outside was octagonal
in shape and 7½ to 8 in. (19 cm.) in diameter. Four vertical channels were cut in the base to
allow bilge water access to the pump bore. 234 No suction pumps are portrayed on Slade’s
construction drafts. However, like Charon, it is probable that Pallas would have had a pair of
suction pumps on either side of the mainmast. 235
The chain pumps are prominently featured on Slade’s construction draft just aft of the
mainmast (Figs. 5 and 11). 236 Pallas would have been launched with the old style chain pump
but retrofited with the improved Cole-Bentinck type introduced in 1768 (Figs. 25 and 26). 237 The
Cole-Bentinck chain pump offered greater ease of maintenance and repair, improved reliability,
and vastly superior performance. With the old type chain pump, four men could raise 1 ton of
water in 81 seconds, with the new type the amount of time required to raise the same amount of
water was dramatically reduced to 43½ seconds. 238 This is particularly pertinent given that
during her final days the pumps on Pallas were in constant use and were largely responsible for
the ultimate survival of her crew.
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F. Ground Tackle
The navy did not manufacture its anchors, but instead purchased them from contractors
(Fig. 27). Every ship had three principle anchors; the best bower, second bower, and sheet
anchor. 239 These anchors did not vary substantially in weight, the main difference being in
location and function. The bower anchors were historically the two largest anchors; the only real
difference being that the best bower was on the port and the second bower on the starboard. The
sheet anchor was carried for added security should the bowers fail. Very little information was
found regarding the size of anchors carried by Royal Navy warships. Lavery suggests a 30 cwt.
(1362 kg.) bower for a ship of 625 tons and a 45 cwt. (2043 kg.) bower for a ship of 969 tons. 240
The 513-ton Pandora carried bowers weighing 29 cwt. (1317 kg.) and the 1000-ton Diana
carried bowers weighing 40 cwt. (1816 kg.). 241 Therefore, it is reasonable to assume that the
724-ton Pallas carried bowers weighing between 35 and 40 cwt. (1589-1816 kg.). Additional
smaller anchors included the stream anchor for short-term use in light weather, and the kedge
anchor used to assist in complex maneuvers across or against the prevailing currents. 242
The anchor lining was a layer of sacrificial planking built up on the ship’s sides to
protect the hull below the catheads from the anchors. Its placement was determined by the length
of the anchor shank and the arc described by the anchor while being catted. The thickness of the
lining typically made up the difference between the hull planking and the wales. 243
G. Navigation and Communication
The helm on Pallas was located just forward of the mizzenmast on the quarterdeck. It
consisted of the wheel and the binnacle. The design, dimensions and placement of the double
wheel can be determined from Slade’s construction drafts. 244 The wheel assembly consisted of
two ten-spoke wheels fixed to each end of a cylindrical wooden barrel mounted longitudinally on
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the ship’s centerline. An outer wooden rim reinforced each wheel about two-thirds the distance
between the barrel and the ends of the spokes. The wheel assembly turned on an iron spindle
suspended between two wooden brackets. The rope from the tiller passed through holes cut in
the deck below the wheel and wrapped around the barrel five to seven times before returning to
the tiller. 245
The precise location of the binnacle is not known but it would have been midship, just
forward of the wheel. The binnacle was a small wooden cabinet divided into three compartments
that protected the ship’s compasses against the elements. The central compartment contained a
lantern and the two outer compartments each contained a compass. Glass partitions between the
compartments let light from the lantern reach the compasses. The outer compartments had glass
fronts but the lantern compartment did not. This permitted the helmsman to view the compasses
without the light from the lantern affecting his night vision. Above the compass compartments
was a drawer that contained the log lines, lead lines, and hourglasses. 246
Almost all activities on an 18th-century Royal Navy warship revolved around the ship’s
bell; consequently it occupied a suitably prominent position on the ship. The belfry on Pallas
was located amidships at the after end of the forecastle. It consisted of four stanchions covered
by a cross-arched roof. The bell swung on an athwartship beam called the headstock that was
suspended between two cross pieces fixed fore and aft between the stanchions. 247
Communication between ships at sea was typically carried out with various
combinations of signal flags. This consequently required that ships carried a large number and
variety of flags that needed to be stored in an easily accessible location. The flag locker on
Pallas was probably located just below the taffrail at the extreme after end of the quarterdeck.
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H. Galley
The galley on smaller warships was usually located under the forecastle. Iron stoves of
standardized dimensions were first proposed in 1728, and by 1757 had supplanted the old style
brick hearth. A flat-bottomed copper kettle, rectangular in shape and divided into two unequal
sections, was mounted above two separate fireplaces. The fireplaces were stoked through doors in
the side and the fore fireplace contained a rack for grilling with brackets on which to mount a spit.
A small oven was located between the two fireplaces. Each kettle section had a tap fitted near its
bottom to drain the water and a removable lid about half the diameter of the overall kettle. The
stove from HMS Dorsetshire, launched in 1757, conformed to new Admiralty standards issued in
May of that year (Fig. 28). The stove on Pallas would have been identical and only a little
smaller. 248
I.
Other Permanent Fixtures
Hammock cranes were U-shaped wrought iron stanchions bolted along the top of the
planksheer or the inner face of the bulwarks—usually fitted on the forecastle and quarterdecks of
frigates and smaller warships. They were connected together with ropes or rails to form stowage
racks for hammocks. The hammock crane and hammock combiantion acted as a windbreak and
afforded some protection to the crew while in action.249
Fenders were fixed, typically in pairs, down the outside of the hull. Their primary
function was to prevent boats and cargo being hoisted aboard from damaging the wales and
various rails on the side of the ship. Pallas had one set of double fenders on each side of the ship
outboard of the main hatch. 250
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Frigates did not have decorative entry ports like larger warships. Access to the ship was
provided by one set of steps on each side of the ship between the fenders and the break of the
quarterdeck. 251
J.
Ballast
The purpose of ballast is two-fold; its primary function is to lower the center of gravity
providing both stability and seaworthiness, and its secondary function is to trim the ship,
compensating for the uneven distribution of guns, cargo and provisions. The amount of ballast
carried by mid 18th-century Royal Navy warships varied considerably based on the ship’s design
and on the preferences of the captain. However, by the end of the century these amounts had
been standardized based on the number of guns carried. Ballast came in two forms, iron ingots
and stone shingle. The ingots were placed into ‘rooms’ formed by the floor riders or simply
across the floor of the hold near midship. Ballast did not reach very far fore or aft of midship.
Frigates carried their ballast closer to the centerline with little placed aft of the pump well. The
amount of shingle carried was usually about four times the iron. The main advantages of shingle
ballast were that it was far cheaper and more readily available than iron. It also provided a good
stable surface on which to stow casks. Shingle was placed on top of the iron and reached both
farther outboard and fore and aft. 252 The iron ingots, also known as ‘kentledge’, typically took
the form of strips or ‘pigs’ and varied in size between 12 in. (30.5 cm.) long by 4 in. (10.2 cm.)
square and 36 in. (91.4 cm.) long by 6 in. (15.2 cm.) square, with diagonal holes through the
upper corners to facilitate lifting. 253 The ingots found on Charon were 36 in. (91.4 cm.) by 6 in.
(15.2 cm.) square conforming perfectly to this standard. 254 These are identical to those observed
by Ollivier over 40 years earlier. 255 However, the seven iron ingots found at the Pallas site did
not conform to this standard for they measured 25½ in. (65 cm.) long, 17¾ in. (45 cm.) wide and
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5¾ in. (15 cm.) thick. 256 Why Pallas would have been carrying non-standard ballast or where
she got it is unclear however it was not unusual for the Royal Navy to recycle iron ballast from
captured ships or other sources. 257
K. Ships’ Boats
Ships’ boats designed to fulfill a vast array of functions and a variety of tasks. Men-ofwar rarely tied up to a pier or dock; therefore they relied on their smaller boats for
communication with land and other ships. Small boats also transported a ship’s provisions and
stores from shore and from other ships. They carried out military duties such as cutting-out
expeditions and landing troops, guns and supplies. They also played an essential role in
anchoring, mooring and maneuvering the ship by kedging, warping or towing. 258
The best available source concerning ships’ boats is W. E. May’s The Boats of Men-ofWar. He states that from 1761 onwards 32- and 36-gun frigates carried a 23 ft. (7 m.) longboat, a
30 ft. (9.1 m.) pinnace, and a 24 ft. (7.3 m.) yawl. 259 In July of 1780, yawls were removed and
replaced by two 24 ft. (7.3 m.) cutters. In October of 1780, the longboats on all single deck ships
were replaced with 23 to 24 ft. (7-7.3 m.) launches. In June 1781, one of the 24 ft. (7.3 m.)
cutters was replaced with a four-oared 18 ft. (5.5 m.) cutter. 260
The longboat was the largest, heaviest, and strongest boat belonging to any ship, and
was capable of carrying great weights in all weather. 261 Its primary function was to carry out
anchors and carry large numbers of water casks while still being small enough to be hoisted
aboard the ship. It had a single mast and bowsprit, was cutter-rigged, and had a davit and winch.
The launch was generally preferred to the longboat and eventually replaced it. It had less
sheer and a wider stern than the longboat with a square midship section making it good for
carrying large loads. Like the longboat it was cutter-rigged and carried similar fittings. 262
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Frigates did not carry barges. Pinnaces resembled barges but were smaller, never having
more than eight oars. May suggests that the terms pinnace and barge were used indiscriminately
and that the usage depended upon the size of the parent vessel. 263 The pinnace was narrower than
the other boats and had a small transom. Typically used to carry officers, the interior was lined
and paneled to afford some level of comfort. It had fittings for two masts and was probably
lateen or spritsail rigged. 264
Yawls were smaller than cutters but had nearly the same form and similar uses. They
were originally clinker built, had a narrow transom and a rounded sternpost. They were a good
sea boat and were often requested instead of longboats. In 1769, frigates on foreign service had
their clinker yawls replaced with carvel-constructed versions, as they were more durable and
easier to repair. By the end of the century, all yawls seem to have been carvel built. They were
propelled by four, six, or eight oars, had two masts, and were lateen or spritsail rigged. 265
Cutters were clinker built and similar in shape to yawls. They were broader, deeper, and
shorter than barges and pinnaces and were good sailors. They were meant primarily to carry
stores, provisions, and passengers to and from the ship. Like yawls, those built for foreign
service were of carvel construction. They were rowed by six oars, had two masts, and were
spritsail rigged. 266
Because of the chronic shortage of space on large sailing vessels of all types, boat
stowage was always a problem. Davits were not introduced until 1790. Until then boats were
hoisted aboard using capstan and tackle and usually stacked in the waist on top of the spare spars
or on top of skid beams. 267 Skid beams were removable beams placed across the waist of the ship
on which the boats and spare spars were stored. There were usually three or four beams
supported by iron crutches set at regular intervals into the planksheer. 268
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L. Hull Protection
Throughout maritime history, various coatings and claddings have been applied to the
outer hulls of wooden ships to combat marine growth and damaging infestations. During the late
17th and early 18th centuries the Royal Navy experimented with many methods, including
sacrificial wooden sheathing or lead sheathing used conjunction with a variety of chemical
treatments. In 1761, experimentation began with copper sheathing, which was found to inhibit
teredo navalis or ship worm. It was relatively lightweight and had the added benefit of resisting
the buildup of marine growth – thereby increasing performance while reducing hull
maintenance. In July 1779, the Admiralty ordered the coppering of all ships of less than 44guns. 269 The sheathing was composed of uniform copper sheets 48 in. (121.9 cm.) long and 15
in. (38.1 cm.) wide, fastened to the hull with copper tacks 1 in. (2.5 cm.) long and ¼ in. (0.6 cm.)
in diameter. The sheets were overlapped 1½ in. (3.8 cm.) along the aft and upper edges to
minimize water resistance (Fig. 29). The inside of each sheet was painted with white lead and
thick paper and tar was placed between the sheathing and hull. 270 Evidence from the remains of
Charon suggests that the sheets were up to 60 in. (152.4 cm.) long and 18 in. (45.7 cm.) wide.
Curiously, the false keel on Charon was not coppered and neither was the underside of the
keel. 271
Spar Plan and Rigging Plan
Details regarding the rigging and fitting of warships from this period were far more
difficult to obtain than the details of the hull construction. A handful of contemporary treatises,
supplemented by period artwork, do provide a great deal of valuable, if general, information but
rarely provide information pertaining to the rigging details of a specific vessel. Period paintings
and drawings can be quite useful, but without full knowledge of the artist’s background and
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intent, they should be treated with some suspicion when analyzing them for specific detail.
Admiralty models can also prove very useful in determining navy standards and practices for a
given period, but it must be remembered that these models were presented for consideration by
the Admiralty board prior to construction; final approvals were almost always accompanied by
long lists of changes to be made to the finished vessel. Several scholarly modern works on 18thcentury rigging also exist. They are, for the most part, based upon analysis of the previously
mentioned treatises, artwork and Admiralty models but also provide detailed drawings and
descriptions for specific elements during specific timeframes.
The focus of this section is to establish, as accurately as possible, the spar plan and the
standing rigging and running rigging arrangement of the frigate Pallas. Pallas-class frigates
were transitional vessels in several ways. According to navy records, they were originally rigged
with a lateen mizzen yard but were subsequently refitted with mizzen gaffs; Venus was originally
constructed with a sprit topsail and a mizzen topgallant mast, and was also given a flying
jibboom in 1794. 272 The rigging plan described here is intended to represent Pallas as she was
first fitted out following her launch at Deptford shipyard in 1757.
A. Masts and Spars
The positioning of the masts on Pallas was determined from Slade’s drafts. The same
drafts also roughly show the rake of the masts and steeve of the bowsprit (Fig. 30). 273 The best
information available from modern sources for determining the steeve of the masts comes from a
set of standardized formulas described in Goodwin. He states that for 24- to 38-gun ships, the
incline (in inches) per yard length of mast was 1/16 in. (1.6 mm.) for the foremast, 5/8 in. (1.6
cm.) for the main mast and 1 in. (2.5 cm.) for the mizzenmast. 274 From Slade’s drafts of Pallas
and Brilliant it is possible to determine an approximate mainmast rake of about 1½ degrees, a
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mizzenmast rake of about 1¾ degrees, and a foremast rake of less the ½ degree. 275 Goodwin
does not provide an exact formula for the steeve of the bowsprit for warships contemporary with
Pallas. But he does state that the 22-gun Tartar of 1734 had a bowsprit rake of 36 degrees and
that 100-gun Victory had a bowsprit rake of 36 degrees in 1737, subsequently reduced to 30
degrees when it was rebuilt in 1765. 276 From Slade’s drafts of Pallas and Brilliant it is possible
to determine an approximate bowsprit steeve of about 30 degrees. 277
The mast and spar dimensions and proportions, specifically for Pallas class frigates,
exist to the present. 278 The exact taper of the masts and spars for Pallas do not survive.
However, by the middle of the 18th century, these details were in the process of being
standardized throughout the Royal Navy and by the end of the century, a number of
mathematical formulas and tables of such information had emerged. 279 One primary source,
David Steel’s Elements of Mastmaking, Sailmaking, and Rigging, provides a series of tables
defining the standardized taper of masts and spars for Royal Navy warships. 280 Some
information, both modern and contemporary, exists regarding the fittings of the masts, bowsprits
and spars of 18th-century Royal Navy warships. 281 Steel’s treatise provides exact detailed
drawings for a late 18th-century, 36-gun frigate. 282 It has been applied because it is a nearly
contemporary source but it must be remembered that the 36-gun frigate represented in Steel’s
treatise is considerably larger than Pallas. In some cases this study follows Lees or Harland
when they offered slightly different examples claiming to be chronologically closer to Pallas.
All three of the lower masts were made from several pieces coaked together and reinforced with
between six and nine rope wooldings. They had no front fish and had iron hoops only around the
head of the mast. There is some question as to whether Pallas had wooldings on the mizzenmast.
However, Marquardt specifically states that after 1730, frigates with less than 36 guns had no
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wooldings on their mizzenmast. 283 Since Pallas was a 36-gun vessel, it is reasonable to conclude
that her mizzen mast did have wooldings.
One of the more difficult reconstruction tasks was determining the doubling of the masts
and bowsprit. The drafts in Steel’s treatise, and analysis of Admiralty models of Diana, provided
approximations for frigates from the end of the 18th century but examples from frigates dating to
the middle of the century proved difficult to locate. 284 The most reliable and near-contemporary
examples available are a 1745 draft of the 44-gun Centurion (1732) (Fig. 32), a 1719
Establishment draft of a 50-gun ship, and a contemporary watercolor of the 60-gun Lion built in
1709 and rebuilt in 1738 (Fig. 33). The same sources also proved to be indispensable in
determining the exact placement of the spars on the masts. 285 A variety of extant sources
describe the mast tops, hounds, bibs, and caps for 18th-century warships, and all are, for the most
part, in agreement. 286 As with the mast and spar details, Steel’s treatise was followed except
where Lees or Harland offered different examples claiming to be closer to Pallas in date. The
footropes or horses on the spars were spliced to the ends of the yardarms and, after 1760, crossed
each other at the slings before being seized to the yard. There were usually two or three stirrups
supporting the horses on each side depending on the length of the yard. 287 The details of the
studdingsail booms and boom irons followed Steel’s drawings for a 36-gun frigate,
supplemented with information gathered from several modern sources. The dimensions of the
booms were derived by comparing the relative dimensions of the booms to corresponding yards
in Steel’s drafts and then applying those ratios to the known dimensions of Pallas’ yards. The
irons were angled forward at an angle of approximately 45 degrees. Rollers to facilitate moving
the studdingsail booms were not introduced in the Royal Navy until after 1773 so it is doubtful
whether Pallas was ever fitted with them. 288
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Pallas was not rigged with a sprit topsail yard (as was her sister ship Venus) and
predates the introduction of the martingale or dolphin striker. 289 Exact details of the bowsprit
layout for Pallas were unavailable so it was necessary to extrapolate the arrangement from the
1745 draft of Centurion, the 1719 Establishment draft of a 50-gun ship, the watercolor of the 60gun Lion, and the few general examples provided by modern sources. 290 Information for the
bowsprit and jibboom horses was found in several sources. 291
By 1730, lateen yards had become so large that it was no longer feasible to shift around
the mast while tacking. Consequently, the yard was permanently fixed on the starboard side of
the mast. The portion of the sail forward of the mast was discarded and the new leech edge was
laced to the mast. 292 The mizzen parrel was seized to the jeer blocks with a parrel rope running
through a long tackle block, down through a small hook block fastened to an eyebolt in the deck,
and tied off to a cleat on the mast about four feet above the deck. 293
B. Standing Rigging
A great deal of information is available for determining the standing rigging
arrangement of Royal Navy frigates from the middle of the 18th century. The location and
arrangement of the chain plates and channels was included in Slade’s original drafts of Pallas
and Brilliant. 294
For details of the arrangement of the shrouds and futtock shrouds at the tops there are
numerous sources, both modern and contemporary, and all are in general agreement (Fig. 31). 295
The ratlines were typically spaced 13 to 15 in. (33-38.1 cm.) apart and on the fore and mainmast
shrouds ran from the foremost shroud to the second shroud from aft. About every sixth ratline
extended to the aft shroud. All of the ratlines on the mizzen extend across all of the shrouds.
Topgallant shrouds did not carry ratlines after about 1745. 296
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For the stays, there are several good sources. Here the detail drawings in the modern
sources are indispensable for exact location and method of fixing the various stays. While
secondary sources, they are based for the most part on studies of admiralty models and should be
reliable. 297 Slade’s drafts lack a location for securing the backstays of the mizzenmast. The best
sources for determining where to secure the mizzen backstays are the 1761 Admiralty model of
the 32-gun Lowestoffe, the watercolor of Lion, and the 1719 Establishment draft of a 50-gun
warship where the backstays all appear to be fastened to eye bolts located somewhere between
the bulwarks and the channels. The model of Lowestoffe also proved extremely useful. 298 In the
absence of exact information, two eyebolts were added to the after end of the mizzen channel in
a manner similar to those seen on White’s rigging reconstruction of Diana. 299
Exact information for the standing rigging of the bowsprit proved difficult to come by.
For the most part, it was necessary to rely on White’s reconstruction of the rigging for Diana and
detail drawings from Lees. It is reasonable to conclude that there are only two sets of bobstays
and only one set of bowsprit shrouds. They were seized to two collars, the forward collar
securing the outer bobstays and the fore preventer stay and the after collar securing the inner
bobstays, the bowsprit shrouds and the fore stay. 300
C. Running Rigging
Several good contemporary and detailed modern sources exist for the running rigging of
the bowsprit and sprit topsail yard. 301 However it was difficult to find information for the
arrangement of sprit topsail yard lifts. The only detailed example found was a modern schematic
drawing of an English vessel from about 1800. 302
The lower yards were suspended from the tops by jeers. The double upper jeer blocks
were hung from separate strops wrapped around the head of the mast and fed through the lubber
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holes on each side. The lower jeer blocks were single and were seized to the slings of the yard.
The halliards were seized to the yard near the lower jeer blocks, rove through the upper and
lower blocks on each side and down to bits on the deck. 303 An excellent example of a similar,
though not identical, arrangement can be seen on the Admiralty model of Medway, 1742. 304
Slings were not introduced in the Royal Navy until after 1770. 305 The topsail yards were
suspended by their tyes. Each tye ran up from its halliard, rove through a block stropped to the
head of the mast, down through a tye block stropped to the yard, passed back up through the top
block on the other side of the mast and down to the other halliard. The tye was usually fixed to
the backstay by means of a traveler. 306 The topgallant yards simply hung from their tyes. The tye
was seized to the yard and ran up through a sheave in the hounds and down to the halliard, which
was fixed to the lower mast tops. White’s detail of Diana shows the halliard continuing down to
the deck. 307 Details of the lifts and lift blocks were derived mainly from Lees and from White’s
reconstruction of the rigging for Diana. 308 For the braces there was considerably more
information available albeit confusing and not necessarily in agreement. The best nearcontemporary portrayal of braces on a Royal Navy warship was a plate from Sutherland’s 1711
treatise The Ship Builder’s Assistant. 309 While this work is a little early, when combined with the
several modern examples found, I am confident that a reasonably accurate portrayal of the brace
arrangement for Pallas has been achieved. 310
The details of running rigging for the lateen yard are fairly straightforward. The peak
halliard was seized to the peak of the yard, rove through a block at the mast cap, back through a
sister block supporting a span on the upper portion of the yard, back through another block lower
on the mast head and down to the deck. The bowlines were seized to the aftermost main shroud,
rove through a pair of blocks that were stropped to an eyebolt at lower end of the yard, rove back
through another block seized to the aftermost main shroud and were tied off to the rail. The vang
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pendants are typical of nearly all large ships of the period. The middle of a single piece of rope
was clove-hitched to the peak of the yard, rove through a long tackle vang purchase hooked to an
eyebolt on each side of the deck and tied off to a cleat in the side. 311
As previously described a substantial portion of the running rigging lines in Pallas’ rig
extended down to specific belaying points on the forecastle, quarterdeck and the upper deck in
the waist, but the exact location of the various belaying points on Pallas is unknown, however,
they were generally divided into pairs of pin-rails fixed to the inner bulwarks on either side of
each mast and an assortment of kevels, kevel blocks and cleats placed around the forecastle,
quarterdeck and open area of the waist. White’s reconstruction of Diana is the closest parallel
both chronologically and in ship size and type. It provides the location and function of each
individual belaying point. Another relatively close parallel found useful was Lees’ schematic of
a frigate from 1810. Timberheads were also used as non-specific belaying points. They were
shaped with an inverted taper bearded back at the lower end. The crown was also bearded. The
shape and placement of the timberheads can be seen on Slade’s drafts of Brilliant. 312
Notes
1
Admiralty drafts are a standardized set of 1/48-scale drawings approved by the Navy Board and the
Admiralty Board for each proposed Royal Navy warship. Copies were submitted to the shipwrights to
serve as working parameters during construction. Engineering was left almost entirely to the individual
shipwrights and varied considerably from yard to yard throughout the empire.
2
NMM ADM 2042, ADM 2194, ADM 2196, ADM 2198, ADM 2199, and ADM 2200. Admiralty drafts
for construction of HMS Pallas and HMS Brilliant.
3
NMM ADM 170/429 and NMM: ADM 170/430 also reproduced in Goodwin, Construction and Fitting,
242-265.
4
Gardiner, Line of Battle, 36 and Gardiner, First Frigates, 10-12.
5
Murray, Treatise on Ship-Building, 208 For the purposes of this work, the procurement, transport,
processing and seasoning of timber and other materials used in the construction of Pallas in compliance
with Admiralty specifications, will be assumed. Discussion of this process would in itself comprise a
lengthy thesis topic.
6
Sutherland, Ship-Builder’s Assistant, 78 and Steel, Shipwright’s Vade Mecum, 232-33.
7
Goodwin, Construction and Fitting, 5, Ollivier, Remarks, 46 and Sutherland, Ship-Builder’s Assistant,
78. The method used to secure the keel assembly atop the blocks is unclear. Sutherland proposes notches
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in the tops of the splitting blocks and Ollivier states that they used wooden nogs driven down vertically
into the keel block. This may be a case of differing shipyard practices.
8
Gardiner, First Frigates, 28.
9
Anonymous, Shipbuilder’s Repository, 256-57, and Murray, Treatise on Ship-Building, 204.
10
Ollivier, Remarks, 63.
11
Goodwin, Construction and Fitting, 6.
12
It is evident that Admiralty drafts were viewed more as working guidelines and not precise engineering
plans. The contracted shipwrights were left to address the various structural details with considerable
autonomy.
13
Anonymous, Shipbuilder’s Repository, 256-57, Goodwin, Construction and Fitting, 5-7 and Stevens,
Construction and Embellishment, 12. Elm was preferred for the keel due to its durability when immersed
in salt water for long periods. The use of copper bolts below the waterline was not generally practiced
until after 1783. However, Goodwin suggests the possibility that limited application may have occurred
much earlier.
14
Anonymous, Shipbuilder’s Repository, 256-7, Goodwin, Construction and Fitting, 6-7, Steel,
Shipwright’s Vade Mecum, 233 and Murray, Treatise on Ship-Building, 204.
15
Ollivier, Remarks, 45-6.
16
White, Frigate Diana, 3.
17
Goodwin, Construction and Fitting, 7.
18
Steel, Shipwright’s Vade Mecum, 233 and Goodwin, Construction and Fitting, 7.
19
Ollivier, Remarks, 46.
20
Stevens, Construction and Embellishment, 12.
21
Goodwin, Construction and Fitting, 7.
22
Steffy, “The Charon Report,” 226.
23
Goodwin, Construction and Fitting, 8 and Anonymous, Shipbuilder’s Repository, 256-57.
24
Steffy, Wooden Shipbuilding, 177, Steffy, “The Charon Report,” 226.
25
Goodwin, Construction and Fitting, 7-8.
26
Sutherland, Ship-Builder’s Assistant, 78-9.
27
NMM: ADM 2196.
28
Anonymous, Shipbuilder’s Repository, 254-55 and Steel, Shipwright’s Vade Mecum, 234.
29
Ollivier, Remarks, 46.
30
Anonymous, Shipbuilder’s Repository, 256-57 and Ollivier, Remarks, 47.
31
Dodds and Moore, Building the Wooden Fighting Ship, 62-5. This source provides excellent visual
depictions of the process of raising large timber assemblies into place.
32
Ollivier, Remarks, 46 and Goodwin, Construction and Fitting, 9-10.
33
Goodwin, Construction and Fitting, 8 and Steel, Shipwright’s Vade Mecum, 234-35.
34
Anonymous, Shipbuilder’s Repository, 246-49.
35
NMM: ADM 2196.
36
Goodwin, Construction and Fitting , 9.
37
Stevens, Construction and Embellishment, 22.
38
Anonymous, Shipbuilder’s Repository, 248-49.
39
Sutherland, Ship-Builder’s Assistant, 81.
40
Goodwin, Construction and Fitting, 26. The dimensions of the bolts is unknown but they were probably
1-1¼ in. (2.2-3.8 cm.) diameter.
41
Anonymous, Shipbuilder’s Repository, 310-11.
42
Falconer, Universal Dictionary, 123 and Steel, Shipwright’s Vade Mecum, 103.
43
Goodwin, Construction and Fitting, 24.
44
Anonymous, Shipbuilder’s Repository, 248-49, Goodwin, Construction and Fitting, 26 and Ollivier,
Remarks, 47.
45
Dodds and Moore, Building the Wooden Fitting Ship, 62-5. This source provides excellent visual
depictions of the process of raising large timber assemblies into place.
86
46
Anonymous, Shipbuilder’s Repository, 332-33, Goodwin, Construction and Fitting, 31 and NMM:
ADM 2196.
47
Murray, Treatise on Ship-Building, 207.
48
Goodwin, Construction and Fitting, 12-13.
49
Ollivier, Remarks, 47.
50
Steffy, “The Charon Report,” 132.
51
McKay and Coleman, Frigate Pandora, 26-8 and White, Frigate Diana, 30-1.
52
Lavery, Ship of the Line Vol. 2, 43.
53
NMM: ADM 2196 and NMM: ADM 170/429.
54
Several early Unicorn class frigates were built entirely of fir.
55
Sutherland, Ship-Builder’s Assistant, 79.
56
Anonymous, Shipbuilder’s Repository, 262-63 and NMM: ADM 170/429.
57
Steel, Shipwright’s Vade Mecum, 237.
58
Ollivier, Remarks, 65-6, Dodds and Moore, Building the Wooden Fighting Ship, 72-3 and Steel,
Shipwright’s Vade Mecum, 238-39. Ollivier claimed that the doubled frames were fastened together with
treenails rather than iron bolts.
59
Dodds and Moore, Building the Wooden Fighting Ship, 72-3 and Steel, Shipwright’s Vade Mecum, 23839. Steel gives an excellent description of raising the frames into place.
60
Sutherland, Ship-Builder’s Assistant, 79.
61
Steel, Shipwright’s Vade Mecum, 237, Dodds and Moore, Building the Wooden Fighting Ship, 68 and
Sutherland, Ship-Builder’s Assistant, 79.
62
ADM 2196, Anonymous, Shipbuilder’s Repository, 262-69, NMM: ADM 170/430, Steffy, Wooden
Shipbuilding, 177, McKay and Coleman, Frigate Pandora, 64, White, Frigate Diana, 61.
63
Ollivier, Remarks, 52.
64
Ollivier, Remarks, 48.
65
Goodwin, Construction and Fitting, 13.
66
Steffy, Wooden Shipbuilding, 177.
67
Goodwin, Construction and Fitting, 17.
68
Steffy, “The Charon Report,” 130 and Stevens, Construction and Embellishment, 13-14.
69
Falconer, Universal Dictionary, 74.
70
Stevens, Construction and Embellishment, 15-17.
71
Sutherland, Ship-Builder’s Assistant, 80 and Goodwin, Construction and Fitting, 23.
72
Murray, Treatise on Ship-Building, 207, Steel, Shipwright’s Vade Mecum, 109.
73
Ollivier, Remarks, 50.
74
Anonymous, Shipbuilder’s Repository, 254-55.
75
Anonymous, Shipbuilder’s Repository, 254-55.
76
Anonymous, Shipbuilder’s Repository, 308-9, Goodwin, Construction and Fitting, 178, Sutherland,
Ship-Builder’s Assistant, 83 and Steel, Shipwright’s Vade Mecum, 116-17.
77
Steel, Shipwright’s Vade Mecum, 112.
78
Anonymous, Shipbuilder’s Repository, 258-59, Murray, Treatise on Ship-Building, 204 and Sutherland,
Ship-Builder’s Assistant, 79.
79
Stevens, Construction and Embellishment, 19, White, Frigate Diana, 30-1.
80
Anonymous, Shipbuilder’s Repository, 258-59.
81
Falconer, Universal Dictionary, 331, Fincham, Outline of Ship Building, 29, Goodwin, Construction
and Fitting, 53, Steel, Shipwright’s Vade Mecum, 140-141 and Murray, Treatise on Ship-Building, 209.
82
Anonymous, Shipbuilder’s Repository, 268-69, Murray, Treatise on Ship-Building, 205, Goodwin,
Construction and Fitting, 53, McKay and Coleman, Frigate Pandora, 69 and White, Frigate Diana, 61.
83
Steffy, Wooden Shipbuilding, 271. States clearly that some eighteenth century English documents
called all of the ceiling, footwaling in which case the thick strakes near the turn of the bilge were known as
thick stuff. Falconer, Universal Dictionary, 79 and 132, Falconer makes no differentiation between ceiling
and footwaling. Stevens, Construction and Embellishment, 20.
84
Anonymous, Shipbuilder’s Repository, 278-79 and Goodwin, Construction and Fitting, 39-40.
87
85
Murray, Treatise on Ship-Building, 208.
Steffy, Wooden Shipbuilding, 177.
87
Goodwin, Construction and Fitting, 40-1.
88
Anonymous, Shipbuilder’s Repository, 296-97,320-21, Blanckley, Naval Expositor, 35, Murray,
Treatise on Ship-Building, 207, Goodwin, Construction and Fitting, 41-2 and Falconer, Universal
Dictionary, 81.
89
Anonymous, Shipbuilder’s Repository, 280-81, 320-2, Goodwin, Construction and Fitting, 41-2 and
Ollivier, Remarks, 50. Ollivier states that no orlop deck clamps were used. The orlop beams were butted
against the frames, notched into the ceiling strakes and secured at both ends with hanging knees.
90
Anonymous, Shipbuilder’s Repository, 296-97, 320-21 and Goodwin, Construction and Fitting, 41-2.
91
McKay and Coleman, Frigate Pandora, 69 and White, Frigate Diana, 61. The section plan for Pandora
shows a large single-strake clamp. However, Pandora carried only 9-pound guns and therefore did not
require a heavily reinforced gun deck. The section plan for Diana, armed with much heavier 18-pound
guns, shows a two-strake clamp supporting the gun deck.
92
Anonymous, Shipbuilder’s Repository, 320-21 and Goodwin, Construction and Fitting, 42.
93
Anonymous, Shipbuilder’s Repository, 326-29 and Goodwin, Construction and Fitting, 42.
94
Goodwin, Construction and Fitting, 42.
95
Goodwin, Construction and Fitting, 43-4.
96
Anonymous, Shipbuilder’s Repository, 304-5.
97
Anonymous, Shipbuilder’s Repository, 322-5.
98
Anonymous, Shipbuilder’s Repository, 328-29.
99
Blanckley, Naval Expositor, 156 and Steel, Shipwright’s Vade Mecum, 133.
100
Anonymous, Shipbuilder’s Repository, 308-9 and Goodwin, Construction and Fitting, 44.
101
Anonymous, Shipbuilder’s Repository, 324-25 and Goodwin, Construction and Fitting, 44.
102
Anonymous, Shipbuilder’s Repository, 328-31 and Goodwin, Construction and Fitting, 44.
103
Blanckley, Naval Expositor, 57, Steffy, Wooden Shipbuilding, 271. Steffy states clearly that some
eighteenth century English documents called all of the ceiling, footwaling in which case the thick strakes
near the turn of the bilge were known as thick stuff. Falconer, Universal Dictionary, 79 and 132. Falconer
makes no differentiation between ceiling and footwaling.
104
Anonymous, Shipbuilder’s Repository, 280-1 and Goodwin, Construction and Fitting, 46.
105
Anonymous, Shipbuilder’s Repository, 324-25, White, Frigate Diana, 61 and Goodwin, Construction
and Fitting, 46. Goodwin suggests 4 or 5 strakes of quickwork but there is only room between the
spiketting and deck clamps for a single strake on the lower deck and two strakes on the gundeck as can be
seen on White’s reconstruction of Diana.
106
Ollivier, Remarks, 50.
107
Anonymous, Shipbuilder’s Repository, 326-27, Steel, Shipwright’s Vade Mecum, 136.
108
NMM: ADM 2194, NMM: ADM 2196, NMM: ADM 2198, ADM 2199, and ADM 2200, Admiralty
drafts for construction of HMS Pallas and HMS Brilliant.
109
Anonymous, Shipbuilder’s Repository, 298-99, Ollivier, Remarks, 51 and Goodwin, Construction and
Fitting, 65-6.
110
Sutherland, Ship-Builder’s Assistant, 84-5.
111
NMM: ADM 2196, NMM: ADM 2198 and NMM: ADM 2199. Admiralty drafts for construction of
HMS Pallas and HMS Brilliant.
112
Steel, Shipwright’s Vade Mecum, 112-13 and Falconer, Universal Dictionary, 166.
113
NMM: ADM 2196, Anonymous, Shipbuilder’s Repository, 282-83 and Goodwin, Construction and
Fitting, 69-70.
114
Anonymous, Shipbuilder’s Repository, 282-3, NMM: ADM 170/429 and Goodwin, Construction and
Fitting, 78.
115
Anonymous, Shipbuilder’s Repository, 298-99, NMM: ADM 2196 and Goodwin, Construction and
Fitting, 66.
116
Goodwin, Construction and Fitting, 65-6.
117
Anonymous, Shipbuilder’s Repository, 298-301 and Goodwin, Construction and Fitting, 76-7, 88.
86
88
118
Anonymous, Shipbuilder’s Repository, 320-21, NMM: ADM 2196, Murray, Treatise on Ship-Building,
204 and Goodwin, Construction and Fitting, 67-8.
119
Goodwin, Construction and Fitting, 65-6.
120
Anonymous, Shipbuilder’s Repository, 320-25 and Goodwin, Construction and Fitting, 77, 88.
121
Anonymous, Shipbuilder’s Repository, 326-31, NMM: ADM 2196, Murray, Treatise on Ship-Building,
204 and Goodwin, Construction and Fitting, 68-9.
122
Goodwin, Construction and Fitting, 65-6.
123
Anonymous, Shipbuilder’s Repository, 326-31.
124
Goodwin, Construction and Fitting, 72.
125
Anonymous, Shipbuilder’s Repository, 300-1, Blanckley, Naval Expositor, 29, Steel, Shipwright’s
Vade Mecum, 92, 114, Sutherland, Ship-Builder’s Assistant, 85 and Murray, Treatise on Ship-Building,
206.
126
Anonymous, Shipbuilder’s Repository, 284-85 and Goodwin, Construction and Fitting, 74-5.
127
Anonymous, Shipbuilder’s Repository, 300-01 and Goodwin, Construction and Fitting, 74-5.
128
Anonymous, Shipbuilder’s Repository, 322-23 and Goodwin, Construction and Fitting, 74-5.
129
Anonymous, Shipbuilder’s Repository, 300-01 and Goodwin, Construction and Fitting, 74-5.
130
Blanckley, Naval Expositor, 22, Goodwin, Construction and Fitting, 91, Murray, Treatise on ShipBuilding, 206 and Steel, Shipwright’s Vade Mecum, 89.
131
Ollivier, Remarks, 52.
132
NMM: ADM, 2196.
133
Anonymous, Shipbuilder’s Repository, 320-23.
134
Anonymous, Shipbuilder’s Repository, 296-99.
135
Anonymous, Shipbuilder’s Repository, 290-91 and NMM: ADM 2196.
136
Anonymous, Shipbuilder’s Repository, 288-89, Goodwin, Construction and Fitting, 105-6 and NMM:
ADM 2196.
137
White, Frigate Diana, 36 and McKay and Coleman, Frigate Pandora, 42-3.
138
Steel, Shipwright’s Vade Mecum, 109 and Goodwin, Construction and Fitting, 33.
139
Anonymous, Shipbuilder’s Repository, 320-21 and Goodwin, Construction and Fitting, 33.
140
Anonymous, Shipbuilder’s Repository, 324-25, McKay and Coleman, Frigate Pandora, 42 and White,
Frigate Diana, 36.
141
Anonymous, Shipbuilder’s Repository, 328-29, McKay and Coleman, Frigate Pandora, 42 and White,
Frigate Diana, 36.
142
Falconer, Universal Dictionary, 243.
143
Anonymous, Shipbuilder’s Repository, 286-87.
144
Anonymous, Shipbuilder’s Repository, 286-87, McKay and Coleman, Frigate Pandora, 69 and White,
Frigate Diana, 61.
145
Sutherland, Ship-Builder’s Assistant, 87-8 and Goodwin, Construction and Fitting, 50.
146
McKay and Coleman, Frigate Pandora, 40 and White, Frigate Diana, 67.
147
Goodwin, Construction and Fitting, 50.
148
Steffy, “The Charon Report,” 130, McKay and Coleman, Frigate Pandora, 69 and White, Frigate
Diana, 61.
149
Goodwin, Construction and Fitting, 50 and Steffy, “The Charon Report,” 130.
150
Ollivier, Remarks, 52.
151
Goodwin, Construction and Fitting, 51.
152
Goodwin, Construction and Fitting, 54.
153
NMM: ADM 2042 and Goodwin, Construction and Fitting, 57-8.
154
Steel, Shipwright’s Vade Mecum, 130 and White, Frigate Diana, 61, 67.
155
Anonymous, Shipbuilder’s Repository, 270-71.
156
NMM: ADM 2042 and Goodwin, Construction and Fitting, 57-8.
157
Anonymous, Shipbuilder’s Repository, 246-47 and Goodwin, Construction and Fitting, 54.
158
Goodwin, Construction and Fitting, 50.
159
ADM 2042, White, Frigate Diana, 61 and McKay and Coleman, Frigate Pandora, 64.
89
160
Dodds and Moore, Building the Wooden Fighting Ship, 93.
Anonymous, Shipbuilder’s Repository, 302-3, Blanckley, Naval Expositor, 10, Falconer, Universal
Dictionary, 36, Goodwin, Construction and Fitting, 175.
162
NMM: ADM 2196.
163
NMM: ADM 2196 and Anonymous, Shipbuilder’s Repository, 302-04.
164
Anonymous, Shipbuilder’s Repository, 326-27.
165
NMM: ADM, 2196 and Anonymous, Shipbuilder’s Repository, 333-34.
166
Goodwin, Construction and Fitting, 220.
167
NMM: ADM 2196.
168
Anonymous, Shipbuilder’s Repository, 288-89, Goodwin, Construction and Fitting, 172 and NMM:
ADM 2196.
169
Anonymous, Shipbuilder’s Repository, 306-7 and NMM: ADM 2196. The breadth of the bowsprit step
is based on the thickness to breadth ratio given for larger ships in The Shipbuilder’s Repository.
170
Anonymous, Shipbuilder’s Repository, 304-7.
171
Anonymous, Shipbuilder’s Repository, 322-23.
172
Steel, Shipwright’s Vade Mecum, 303. The Shipbuilder’s Repository does not provide these dimensions
173
Anonymous, Shipbuilder’s Repository, 306-7.
174
NMM: ADM 2196.
175
Goodwin, Construction and Fitting, 145-50, Steel, Shipwright’s Vade Mecum, 92, 102 and Lavery,
Construction and Fitting, 36-49.
176
Gardiner, First Frigates, 67.
177
Goodwin, Construction and Fitting, 58-9 and Dodds and Moore, Building the Wooden Fighting Ship,
96.
178
Anonymous, Shipbuilder’s Repository, 240-41, Goodwin, Construction and Fitting, 59-60 and White,
Frigate Diana, 48-9.
179
Goodwin, Construction and Fitting, 59-60 and White, Frigate Diana, 48-9.
180
NMM: ADM 2200 and Goodwin, Construction and Fitting, 72.
181
Anonymous, Shipbuilder’s Repository, 238-39 and White, Frigate Diana, 52-3.
182
Anonymous, Shipbuilder’s Repository, 242-43, Goodwin, Construction and Fitting, 58-60 and White,
Frigate Diana, 46-7.
183
Blanckley, Naval Expositor, 30, Falconer, Universal Dictionary, 79, Anonymous, Shipbuilder’s
Repository, 252-53, Murray, Treatise on Ship-Building, 206 and Lavery, Construction and Fitting, 51.
184
Goodwin, Construction and Fitting, 58-9 and Anonymous, Shipbuilder’s Repository, 238-39.
185
Lavery, Construction and Fitting, 45-6 and Goodwin, Construction and Fitting, 115.
186
Goodwin, Construction and Fitting, 193 and Lavery, Construction and Fitting, 249.
187
NMM: ADM 2198, NMM: ADM 2199, NMM: ADM 2200.
188
Blanckley, Naval Expositor, 66 and Lavery, Construction and Fitting, 239-40.
189
Ollivier, Remarks, 50.
190
Steffy, “The Charon Report,” 128.
191
Anonymous, Shipbuilder’s Repository, 290-91.
192
Anonymous, Shipbuilder’s Repository, 310-11.
193
Lavery, Construction and Fitting, 202-3.
194
Goodwin, Construction and Fitting, 199-201 and White, Frigate Diana, 34-5. Up until the early 18th
century glazing was made from ground mica commonly known as Muscovy glass.
195
Steel, Shipwright’s Vade Mecum, 137, Gardiner, First Frigates, 30 and White, Frigate Diana, 34.
196
Lavery, Construction and Fitting, 255, Gardiner, First Frigates, 84 and Goodwin, Construction and
Fitting, 206. Up until the early 18th century glazing was made from ground mica commonly known as
Muscovy glass.
197
NMM: ADM 2042.
198
Harland , Seamanship in the Age of Sail, 71, and Lavery Construction and Fitting, 10-12.
199
White Frigate Diana, Plate 6, 19, 115.
200
Lees Masting and Rigging, Plate 58, 155.
161
90
201
Lavery, Construction and Fitting, 11, Goodwin, Construction and Fitting, 129-131 and White, Frigate
Diana, 114-15.
202
Anonymous, Shipbuilder’s Repository, 312-13.
203
Steel, Shipwright’s Vade Mecum, 137, Goodwin, Construction and Fitting, 131-36, Lavery,
Construction and Fitting, 17-21 and White, Frigate Diana, 112-14.
204
Lavery, Construction and Fitting, 20-1 and White, Frigate Diana, 112-14.
205
Steel, Shipwright’s Vade Mecum, 113, NMM: ADM 2042, Anonymous, Shipbuilder’s Repository, 3345 and Goodwin, Construction and Fitting, 36-7.
206
NMM: ADM 2042 and White, Frigate Diana, 70-1.
207
Goodwin, Construction and Fitting, 205.
208
NMM: ADM 2194, NMM: ADM 2196, NMM: ADM 2198, NMM: ADM 2199 and NMM: ADM
2200. These could be subject to modification by the builder and/or Captain.
209
Goodwin, Construction and Fitting, 111.
210
NMM: ADM 2196, NMM: ADM 2198 and Blomfield, “Internal Economy,” 161-4.
211
NMM: ADM 2196 and NMM: ADM 2199.
212
Steel, Shipwright’s Vade Mecum, 90, Goodwin, Construction and Fitting, 111-2, White, Frigate Diana,
55, Lavery, Construction and Fitting, 146 and Dodds and Moore, Building the Wooden Fighting Ship, 99.
213
NMM: ADM 2194 and NMM: ADM 2196.
214
Falconer, Universal Dictionary, 186, NMM: ADM 2194 and NMM: ADM 2196.
215
Goodwin, Construction and Fitting, 121 and Lavery, Construction and Fitting, 144-46, 150.
216
Goodwin, Construction and Fitting, 121-22 and Anonymous, Shipbuilder’s Repository, 292-93.
217
Lavery, Construction and Fitting, 150.
218
Anonymous, Shipbuilder’s Repository, 290-93, Goodwin, Construction and Fitting, 126-27, Lavery,
Construction and Fitting, 150 and Steffy, “The Charon Report,” 139-40.
219
TNA: PRO ADM 95/66 and Gardiner, First Frigates, 80.
220
Caruana, History of English Sea Ordnance Vol. 2, 152, Gardiner, First Frigates, 81, and Lavery,
Construction and Fitting, 101.
221
Caruana, History of English Sea Ordnance Vol. 2, 391-2 and Lavery, Construction and Fitting, 143.
222
Caruana, History of English Sea Ordnance Vol. 2, 242.
223
Lavery, Construction and Fitting, 102.
224
Caruana, History of English Sea Ordnance Vol. 2, 358.
225
Caruana, History of English Sea Ordnance Vol. 1, 229.
226
Muller, Treatise of Artillery, 149, also published in Dodds and Moore, Building the Wooden Fighting
Ship, 123.
227
Gardiner, First Frigates, 81.
228
Anonymous, Shipbuilder’s Repository, 324-5, 328-29 and Goodwin, Construction and Fitting, 77, 88.
229
Falconer, Universal Dictionary, 203.
230
Caruana, History of English Sea Ordnance Vol. 2, 381-88.
231
Goodwin, Construction and Fitting, 188.
232
White, Frigate Diana, 19 and Lavery, Construction and Fitting, 55.
233
Falconer, Universal Dictionary, 221-23 and Oertling, Ships’ Bilge Pumps, 53.
234
Steffy, “The Charon Report,” 134 and Steffy, Wooden Shipbuilding, 174.
235
NMM: ADM 2196.
236
Ibid.
237
Lavery, Construction and Fitting, 72, Oertling, Ships’ Bilge Pumps, 59-61 and Steffy, “The Charon
Report, 134-5. The Admiralty did not order its use on all Royal Navy warships until 1774.
238
Falconer, Universal Dictionary, 221-23.
239
Falconer, Universal Dictionary, 9.
240
Lavery, Construction and Fitting, 33.
241
McKay and Coleman, Frigate Pandora, 76 and White, Frigate Diana, 76.
242
Lavery, Construction and Fitting, 35.
243
Goodwin, Construction and Fitting, 183-84.
91
244
NMM: ADM 219.
Lavery, Construction and Fitting, 22-3.
246
Falconer, Universal Dictionary, 35-6 and Lavery, Construction and Fitting, 26.
247
Goodwin, Construction and Fitting, 206-7.
248
Lavery, Construction and Fitting, 197 and NMM: ADM 2196. In fact the stove depicted on Slade’s
construction draft of Pallas appears to be nearly identical to the one on Dorsetshire.
249
Goodwin, Construction and Fitting, 211.
250
NMM: ADM 2042 and Goodwin, Construction and Fitting, 184.
251
NMM: ADM 2042.
252
Lavery, Construction and Fitting, 186-7.
253
Lavery, Construction and Fitting, 186.
254
Steffy, “The Charon Report,”, 118.
255
Ollivier, Remarks, 55.
256
Garcia and Monteiro, Intervenção Arquelógica Subaquática, 20.
257
King, “Iron Ballast for the Georgian Navy,” 15-16.
258
Lavery, Construction and Fitting, 207-12.
259
May, Boats of Men-of-War, 36.
260
Gardiner, First Frigates, 67.
261
Falconer, Universal Dictionary, 39.
262
Lavery, Construction and Fitting, 218-19.
263
Falconer, Universal Dictionary, 39, May, 1999. 25-6.
264
Lavery, Construction and Fitting, 219-20.
265
Falconer, Universal Dictionary, 39, Lavery, Construction and Fitting 222.
266
Falconer, Universal Dictionary, 39 and Lavery, Construction and Fitting, 222-3.
267
May, Boats of Men-of-War, 47-9.
268
Goodwin, Construction and Fitting, 210 and Lavery, Construction and Fitting, 235.
269
Knight, Copper Sheathing, 299-301, Steffy, “The Charon Report,” 131, and Lavery, Construction and
Fitting, 62-3. Analysis of the logbooks for Pallas (specifically time spent in home ports) suggests that she
was coppered as early as January 1778. (see service history chapter and Appendix C)
270
Knight, Copper Sheathing, 301-2, Goodwin, Construction and Fitting, 225-27 and Lavery,
Construction and Fitting, 6.
271
Steffy, “The Charon Report”, 131.
272
Gardiner, First Frigates, 88.
273
NMM: ADM 2196 and NMM: ADM 2042.
274
Goodwin, Construction and Fitting, 166-9.
275
NMM: ADM 2196 and NMM: ADM 2042.
276
Goodwin, Construction and Fitting, 169
277
NMM: ADM 2196 and NMM: ADM 2042.
278
Gardiner, First Frigates, 88.
279
Marquardt, Eighteenth-century Rigs and Rigging, 17, Lees, Masting and Rigging, 2 and Goodwin,
Construction and Fitting, 170.
280
Steel, Elements of Mastmaking, 50-1.
281
Lees, Masting and Rigging, 3-15, Marquardt Eighteenth-century Rigs and Rigging, 14, 22-33 and
Harland, Seamanship in the Age of Sail, 19-21,34.
282
Steel, Elements of Mastmaking, Plate IV and V.
283
Marquardt, Eighteenth-century Rigs and Rigging, 14-16.
284
Steel, Elements of Mastmaking, Plate V and White Frigate Diana, 78.
285
Lees, Masting and Rigging, Plate 21-Admiralty Draft (#6039) Centurion and Ollivier, Remarks, 44,
166–an anonymous watercolor of Lion, and a draft of a 1719 Establishment 50-gun ship.
286
Steel, Elements of Mastmaking, Plate IV, Lees, Masting and Rigging, 3, 23-31 and Harland,
Seamanship in the Age of Sail, 19-20.
287
Lees, Masting and Rigging, 69 and Marquardt, Eighteenth-century Rigs and Rigging, 72-3.
245
92
288
Steel, Elements of Mastmaking, Plate IV, Lees, Masting and Rigging, 14-16, Marquardt, Eighteenthcentury Rigs and Rigging, 104 and Harland, Seamanship in the Age of Sail, 21.
289
Gardiner, First Frigates, 88, Marquardt, Eighteenth-century Rigs and Rigging, 29, and Harland,
Seamanship in the Age of Sail, 20-1.
290
Marquardt, Eighteenth-century Rigs and Rigging, 29, and Harland, Seamanship in the Age of Sail, 20,
Lees, Masting and Rigging, 11, Plate 21-Admiralty Draft (#6039) Centurion, Ollivier, Remarks, 44, 166
An anonymous watercolor of Lion, and a draft of a 1719 Establishment 50-gun ship.
291
Lees, Masting and Rigging, 51, Harland, Seamanship in the Age of Sail, 24 and Marquardt, Eighteenthcentury Rigs and Rigging, 52.
292
Harland, Seamanship in the Age of Sail, 75.
293
Lees, Masting and Rigging, 105.
294
NMM: ADM 2196 and NMM: ADM 2042.
295
Gardiner, First Frigates, 84-Admiralty model of Lowestoffe, Harland, Seamanship in the Age of Sail,
22-3, Lees, Masting and Rigging, 54.
296
Marquardt, Eighteenth-century Rigs and Rigging, 63 and Lees, Masting and Rigging, 44, 61.
297
Lees, Masting and Rigging, 48, 50, 56-7, Biddlecombe, Art of Rigging, Plate IX, 62-3, Harland,
Seamanship in the Age of Sail, 22.
298
Gardiner, First Frigates, 84-Admiralty model of Lowestoffe, and Ollivier, Remarks, 44, 166 – An
anonymous watercolor of Lion, and a draft of a 1719 Establishment 50-gun ship.
299
White Frigate Diana, 84.
300
White Frigate Diana, 84-6 and Lees, Masting and Rigging, 50.
301
Lees, Masting and Rigging, 100-1.
302
Marquardt, Eighteenth-century Rigs and Rigging, 57.
303
Lees, Masting and Rigging, 64-5.
304
Lees, Masting and Rigging, Plate 3.
305
Marquardt, Eighteenth-century Rigs and Rigging, 77.
306
Marquardt, Eighteenth-century Rigs and Rigging, 89, 92, White Frigate Diana, 93 and Lees, Masting
and Rigging, 83.
307
Harland, Seamanship in the Age of Sail, 26 and White, Frigate Diana, 93.
308
Lees, Masting and Rigging, 68-9, 85, and White Frigate Diana, 95.
309
Sutherland Ship-Builder’s Assistant, 114.
310
Marquardt, Eighteenth-century Rigs and Rigging, 101, White Frigate Diana, 94 and Biddlecombe, Art
of Rigging, Plate X, 64-5.
311
Harland, Seamanship in the Age of Sail, 75-6 and Lees, Masting and Rigging, 106-8.
312
NMM: ADM 2042.
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CHAPTER V
LIFE ABOARD AN 18TH-CENTURY ROYAL NAVY FRIGATE
The field of nautical archaeology has focused, for the most part, on the ships themselves
and to a lesser degree on recovered artifacts. Consideration has been given primarily to the
methods and circumstances of construction, to aspects of the political, environmental and
economic conditions that may have influenced design, and to the circumstances surrounding
their ultimate demise. Very little emphasis has been placed on the study of physical,
environmental, and social conditions of the men that lived, sailed and, in many cases, died on
these ships. There has been a collective tendency to sterilize, when what is needed is a move to
humanize a ship and its collection of artifacts. Nautical archaeologists are, after all, cultural
anthropologists whose ultimate goal should be the study of mankind based upon analysis of
material culture. Historians, on the other hand, perhaps because many view themselves more as
humanists than scientists, have devoted more consideration to shipboard life. What follows is an
examination of the living conditions common throughout the British fleet during the 18th century
focusing specifically on HMS Pallas wherever possible. Topics addressed include shipboard
hierarchy, duties and discipline, pay and benefits, accommodations, food, clothing, health and
hygiene, and leisure activities
Entering the Service
There were three ways for the common seaman to enter the service of the Royal Navy.
He could enter as a young apprentice bound to an officer patron, volunteer of his own free will
or, during wartime, be pressed onto service.
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Contrary to popular perceptions, 18th-century press gangs did not wander the streets
clubbing able-bodied men over the head and depriving them of their liberty. In practice, press
gangs were generally very selective and took only seafaring men or those possessing experience
in maritime related industries. 1 Men illegally impressed had legal recourse to regain their
freedom. However there were many cases in which such individuals, upon receiving their legal
release, chose instead to remain and serve. 2
There is a great deal of information regarding the methods employed by the navy to
address the manpower shortfall during this period. However, navy records of recruitment
activities make it impossible to establish any meaningful numbers or ratios for each type of
recruitment. This is primarily because these records speak simply of ‘recruits’ (defined as
volunteers and pressed men) and ‘losses’ (defined as discharges, desertions and deaths). A
number of record-keeping errors resulted from this. Men who deserted from one vessel quite
often found themselves pressed into the service of another by the end of the same week. Ships
returning home often had large portions of their crews pressed onto other outbound ships before
they reached port, as pressing at sea was a common practice; it is clear that the navy’s records
included only those men recruited on land. 3
The navy reckoned that a year at sea made an ‘ordinary’ seaman and two years made an
‘able’ seaman. 4 Captains typically considered a crew composition of one-third able seamen,
one-third ordinary, and one-third landsmen as the absolute minimum acceptable ratio required to
safely operate a ship. 5
Shipboard Hierarchy, Duties and Responsibilities
Every man that joined a ship’s company was assigned a rating by the captain or first
lieutenant. The rating was recorded in the muster book and determined pay scale and duties.
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Boys and new volunteers were usually the lowest rates followed by landsmen, ordinary seamen
and able seamen, petty officers, warrant officers, and commissioned officers. 6
The ideal compliment for a 36-gun 5th-rate warship of the 1750’s consisted of 240 men:
four commissioned officers, 14 warrant officers, 36 petty officers, six idlers, 104-132 seamen
and 45 marines with the remainder being servants and widow’s men. Widow’s men, fictitious
seamen whose wages were contributed to the pension fund, were borne on the ship’s books at a
rate of two for every hundred crew. 7
The Pallas’ commissioned officers consisted of a captain and three lieutenants. The
captain was in overall command of his vessel and its crew and was responsible for its sailing,
manning, and upkeep. Before sailing, he was expected to oversee the assignment of ratings to
the members of the crew and to draw up and post ‘watch,’ ‘division,’ ‘station,’ and ‘quarter’
lists. He was expected to obtain from the Clerk of the Survey a book listing the inventory of
stores allotted to the boatswain, carpenter, gunner and purser of his ship and to confirm that it
was in agreement with the individual inventories of those men. He was not permitted to make
alterations to the spars, sails, or hull of his ship. Finally, he was expected to keep a complete
journal recording the activities of the ship and its crew and to sign and submit a copy to the
Admiralty and Navy Office after each voyage. 8
Each lieutenant was expected to keep a list of the men in his watch and to frequently
muster them, reporting any deficiencies to the captain. He was expected to visit below decks at
night to see that there was no disorder, to ensure against unauthorized fire, candles or smoking,
and to report any infractions to the captain. He was not permitted to change the course of the
ship without orders except to avoid immediate danger. No boats were permitted to arrive or
depart without the permission of the lieutenant on duty. In action, he was expected to ensure that
the men were at their proper action stations performing their duties. The senior lieutenant
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assumed command of the ship in the event of the captain’s absence, illness or death. Lieutenants
were required to supply themselves with the necessary instruments, maps, and books of
navigation and, like the Captain, to keep a journal to be turned over to the Admiralty at the end
of each voyage. 9
The function of the master was to assist the captain in overseeing the fitting out of the
ship. He was expected to oversee the loading of all stores, and to report any damaged goods to
the captain. He was in charge of the receiving, loading, and distribution of ballast; he supervised
the loading of the hold, and continually oversaw the redistribution of stores over the course of
the voyage to ensure the ship’s trim. He was charged with ensuring that compasses, glasses, log,
and lead lines were kept in good order, and was responsible for navigating the ship in accordance
with the orders of his captain or other superiors. He was further charged with observing all
coasts and waterways and recording any new navigational details observed. When at anchor, he
was responsible for keeping the hawse clear of fouls and obstructions. Finally, the master was
expected to monitor and sign the accounts and logs of those below him and to ensure that he was
thoroughly acquainted with their contents. Like the other officers, the master was required to
supply himself with the necessary maps, instruments, and books of navigation and to keep a
journal to be turned over to the Admiralty at the end of each voyage. 10
The boatswain was in overall charge of the rigging, cable, anchors, cordage, and
canvas—stores that he was expected to jealously guard against excessive waste. He was to
inspect the rigging every morning and report his findings to the captain, to assist in changing the
watches, and to ensure that the men carried out their duties. He was responsible for his own
accounts, which had to be audited and vouched for by both the captain and master before being
turned over to the Surveyor of the Navy. 11
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The sailmaker was required to inspect all of the sails taken onboard ship and to attend all
surveys and conversions of the sails and rigging. He was expected to keep all of the sails in good
repair and fit for service and was responsible for the drying and storage of all sails not in use. He
was also expected to assist with hammocks and was instructed by the boatswain to cut up useless
scraps of canvas to patch hammocks. 12 Gabriel Bray’s sketch “The sailmaker ticketing
hammocks on board the Pallas, November 1774” (Fig. 37) suggests that the sailmaker may also
have been, in part, responsible for overseeing the stowage of hammocks. 13
The gunner was in charge of the guns, gunnery tools, and stores of powder, ammunition
and small arms. He was expected to oversee the maintenance and securing of the guns and their
mountings. Before every voyage, he was required to apply to the storekeeper of His Majesty’s
ordnance for the ship’s allotment of gunnery stores. He was expected to notify the captain when
powder was brought aboard and to ensure the security and safety of the powder rooms. 14
The carpenter oversaw the upkeep of the ship and ensured that the hull was sound and
free of leaks. He was responsible for the maintenance of masts, yards, bulkheads, and cabins and
for ensuring that the pumps were in good working order. He was to examine the masts several
times a day and to report his findings to the officer of the watch. He was to keep a sufficient
quantity of shot plugs made at all times, and during engagements, he and his crew were expected
to continually inspect the hold for leaks. Upon reaching port, the carpenter was required to draw
up a report of the condition of the ship’s hull, masts and yards, and any repairs that were
required. 15
The surgeon took charge of the sick and injured. He was responsible for the sick berth,
for organizing additional space when necessary, and was able to draw on the crew for additional
help. The surgeon was required to pay particular attention to the cleanliness of the sick berth and
to the overall cleanliness of the ship. He was to visit between decks every morning and make a
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report to the captain. In foreign ports, the surgeon was expected to visit the local hospital and
sick houses every second day (Tuesday and Thursday mornings in English ports) and submit a
written report to the captain. Finally, the surgeon was expected to be present when punishments
were administered. 16
The purser had the key to the steward’s store and was responsible for the inspection,
maintenance, and distribution of its contents. It was his responsibility to procure funds from the
navy and deliver them to the victualler, to ensure the honesty of the cook with regard to
purchasing and dressing victuals, and to ensure the cleanliness of the steward’s room. Like most
jobs, responsibilities varied depending upon the captain; according to one captain, the purser was
responsible for the candles in the lanterns taken on deck at night. The purser kept the ship’s crew
lists and the pay books, and was expected to provide the captain with a weekly report on the
expenditure and inventory of all types of goods. 17
The cook was responsible for the steep tub and answerable for the meat put therein. He
soaked the meat to remove the salt and then boiled it. He oversaw the preparation, division, and
distribution of the ship’s food, and was expected to cut the meat ration fairly with regard to both
quantity and quality. He ensured fair distribution of all foodstuff, being always on the lookout
for messes trying to sneak a double ratio—a not infrequent occurrence. 18
Few frigates had a chaplain, if one was present, he served much the same purpose as his
shore bound counterparts and in many cases also served as the shipboard schoolmaster. The
schoolmaster was certified by the navy and was expected to instruct volunteers in writing,
mathematics, and the theory and practice of navigation. He was expected to oversee the
education of the boys according to a curriculum set out by his captain and to be diligent in his
duty. He did not receive his pay without confirmation from his captain. 19
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The armorer and gunsmith assisted the gunner in the survey and receipt of small arms.
They were expected to be conscientious in cleaning and maintaining the small arms and to
undertake their repairs when possible. 20
The master at arms drilled the petty officers and ship’s company daily in the use of small
arms. He placed and relieved the sentinels and inspected their weapons to ensure their
cleanliness and maintenance. He attended the arrival and departure of all boats to prevent
seamen from leaving the ship without permission, and he was expected to work with the officer
of the watch to maintain order aboard ship. 21
The thirty-six petty officers were composed of: two master’s mates, six midshipmen, a
captain’s clerk, three quartermasters and three quartermaster’s mates, a boatswain’s mate, two
yeoman of the sheets, a coxswain, a sailmaker’s mate, a gunner’s mate, a yeoman of the powder
room, nine quarter gunners, a carpenter’s mate, a steward, two corporals, and a trumpeter. The
idlers were composed of sailmaker’s crew and carpenter’s crew. 22
The ship’s company was divided into each of several groupings with each man assigned
to specific stations and duties within each grouping. At sea, all men-of-war maintained at least
two watches. The body of the crew up to the rank of petty officer was divided into starboard and
larboard watches with one watch being on deck at all times. Only the non-seaman officers (the
purser, carpenter, surgeon and chaplain), were exempt from standing watch and not expected to
answer ‘all hands.’ Each watch was four hours long except for the two two-hour dogwatches
between four and eight in the evening (Table 2). A petty officer kept a half-hour sandglass and
rang the ship’s bell every time he turned the glass. No one on a watch got more than four hours
of sleep at a time and often had to wake and turn out for ‘all hands’; this happened more
frequently on smaller vessels like frigates and sloops. The master and the lieutenants took turns
as watch officer. 23 Pallas had four watch officers so each had 12 hours between watches.
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The typical day at sea began when the navigation sightings were taken at noon. During
the afternoon watch, the main meal of the day was eaten, the crew drilled and carried out routine
maintenance, and the first grog ration of the day was issued. Supper was eaten during the
dogwatches. During the first and middle watches the order was “hammocks down.” The morning
began with the order ‘hammocks up” at 4 a.m. The men arose, bundled their hammocks and
stowed them in their assigned location in the hammock cranes along the rail. The ship was
thoroughly cleaned and breakfast was eaten. The forenoon watch consisted mainly of drilling
and maintenance.
Table 2: Depicting the standard watch schedule aboard Royal Navy Warships.
1st watch
8 p.m. – midnight
Middle watch
Midnight – 4 a.m.
Morning watch
4 a.m. – 8 a.m.
Forenoon watch
8 a.m. – noon
Afternoon watch
Noon – 4 p.m.
1st dog watch
4 p.m. – 6 p.m.
2nd dog watch
6 p.m. – 8 p.m.
The crew was further divided into a number of divisions equal to the number of
lieutenants with each lieutenant being responsible for the health and welfare of the sailors in his
division. Each sailor had a particular ‘station’ for each of the ship’s specific maneuvers. He was
required to know where to be and what his job was for each maneuver. Each sailor was
‘quartered’ to a specific part of the ship while in action; most were quartered as gun crew but
some were quartered as top men, magazine help, or powder monkeys. Some were quartered to
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assist the carpenter with damage control and others to the cockpit to assist the surgeon with
casualties. Most men also had secondary duties while in action including trimming sails, fire
fighting, working the pumps, repelling boarders, or serving in boarding parties. Finally the crew
was divided into messes—usually about eight to twelve men who received and ate their food
together. 24
Pay and Benefits
It has been proposed that the low rate of pay was one of the main reasons the Royal
Navy had difficulty manning the fleet. An able seaman in the navy received twenty-four
shillings, an ordinary seaman nineteen shillings, and a landsman eighteen shillings per month.
From this was deducted sixpence a month for the Greenwich Hospital and one shilling to be
divided between the surgeon, the chaplain, and the Chatham Chest—a pension established for
wounded sailors and the widows of those killed in action. It was true that sailors could
potentially earn much more serving aboard merchant ships or privateers, but like most
government jobs, the lower pay scale came with certain benefits. A sailor in the navy was
guaranteed his pay. A merchant sailor could spend months at sea and if the voyage was
unprofitable he was liable to receive little or no pay; privateers received no pay, only a share in
prizes taken at sea. Navy sailors could also expect to receive a share, albeit usually smaller, of
prizes taken by their ship. Furthermore, the navy sailor had all of his overhead expenses taken
care of; the navy provided food, a generous ration of alcohol and a place to sleep. Volunteers
usually received an award or ‘bounty’ upon enlistment but the bulk of his pay was withheld until
the end of his ship’s commission. Sailors discharged before then received a ticket redeemable on
the date that that ship was paid off. When a navy sailor got paid, usually just before sailing on
the next commission, he had few, if any, financial obligations. A navy sailor injured in the line
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of duty would be provided for by the Greenwich Hospital. If permanently disabled he could
expect to receive a modest pension from the Chatham Chest for the remainder of his life. 25
Discipline and Punishment
Discipline in the modern sense of the word—as a code of behavior imposed by the naval
authority—did not exist per se in the 18th-century Royal Navy. Instead, what existed, amounted
to a collective agreement amongst the seamen and officers to undertake the necessary steps to
ensure the safety of the ship and the survival of its crew. The modern perception of perpetual
animosity between the officers and crew has been greatly exaggerated. Seamen understood and
respected the need for a structured chain of command and likewise most officers understood that
extreme or unnecessary punishments only served to alienate the crew and adversely effected the
smooth operation of the ship. 26 According to the Royal Navy’s Articles of War-1757, officers
aboard His Majesty’s ships of war had the right to maintain a solemn, orderly and reverent
atmosphere free from profanity and drunkenness. The use of personal violence by officers and
mates to encourage performance of duty, was accepted by the crew as a necessary means of
maintaining discipline. However, even in this there was established structure and set boundaries
to be observed. Officers and petty officers could reasonably coax a malingering sailor with a
well-placed blow of a knotted rope or rattan stave (referred to as ‘starting’) but beating a man
was not permitted. Striking a man’s face was considered unacceptable. 27
Punishment for crimes committed aboard 18th-century Royal Navy warships is difficult
to quantify. The most common punishment was flogging and the most common offence was, by
far, drunkenness. For misdemeanors, suspension of grog ration or menial labor was a typical
punishment. Various punishments were designed both to confine and to humiliate the offender; a
man could be seized into the rigging for a period of time or placed in leg irons on the deck—
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usually in a location where the entire ship’s company could see him. A man who had committed
a crime against the ship’s crew, such as theft, could be sentenced to running the gauntlet—a
punishment whereby all of the crew was given the opportunity to flog the offender as he passed
among the the assembled ship’s company. Officers and petty officers could be disrated but there
was virtually nowhere to disrate an ordinary or able seaman.
According to the Admiralty’s Regulations and Instructions Relating to His Majesty’s
Service at Sea, no captain had the authority to administer more than twelve lashes. However,
twelve lashes generally were seen by captains as the minimum punishment that justified
assembling the ship’s company. Any crime deemed worthy of a more severe punishment had to
be tried by court martial, but a court martial typically returned sentences too severe to suit
intermediate crimes. Furthermore, the squadron or port second-in-command and a panel of at
least five officers had to preside over a court martial. A ship at sea could go months without
assembling a quorum and, in practice, captains carried out the punishments themselves,
administering more than twelve lashes or other punishments based on the severity of the crime. 28
For more serious crimes a man could be keel hauled, or if in port, whipped through the
fleet—taken from ship to ship and flogged in front of the assembled company of each. The only
crimes dire enough to warrant capital punishment were espionage, cowardice or desertion in the
face of the enemy, murder, and sodomy. Seamen were hung; officers were shot. 29
Accommodations
Hammocks first began to appear on Royal Navy warships in the early 17th century but it
was not until the 18th century that they were officially adopted. In 1746, the Navy Board ordered
that all ships be fitted with hammock cranes—a framework of U-shaped, wrought iron brackets
mounted along the top of the rail. Hammocks were slung parallel to the keel of the ship on the
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gun deck so that all swung in unison as the ship rolled. On larger warships men were allotted as
little as 18 inches in which to hang their hammock, but on frigates the ratio of crew to space
available was greater leaving considerably more space to spread out. When hammocks were not
in use, they were stowed in the hammock cranes and covered with canvas to form a sort of
parapet. This served several purposes; it provided organized storage away from the gun deck, it
acted as a windbreak and, in combat, it provided some protection from musket fire and flying
splinters. Frigates and sloops, having proportionately smaller crews and consequently fewer
hammocks, usually arranged those that they did have on the quarterdeck and forecastle rails. 30
There were typically two hammocks issued per man but the boatswain ensured that the spares
were conserved and protected against unnecessary or unauthorized use. 31
The sailors’ possessions were kept in large wooden sea chests that served both for storage
and often as seating during mealtime and leisure. Like hammocks, each man’s sea chest was
assigned a specific storage location.
The officers and some of the warrant officers had the comfort of semi-private quarters. A
frigate captain had the entire after section of the main deck, below the quarterdeck, as his personal
cabin. He did not have the day cabin or dining room that captains of larger ships enjoyed but they
were still relatively spacious and private quarters. The lieutenants, master, gunner, and marine
officer each had a small berth in the aft area of the lower deck around the pantry area—frigates
did not have a wardroom per se. The boatswain and the carpenter each had small berths on either
side of the main mast on the lower deck, and the purser, surgeon, and steward all had small berths
in the aft section of the orlop deck. 32
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Food
The Navy Victualling Board issued each man standard weekly rations as follows: Sunday
one pound of biscuit, one gallon of beer, one pound of pork, and a half pint of peas; Monday one
pound of biscuit, one gallon of beer, one pint of oatmeal, two ounces of butter, and four ounces of
cheese; Tuesday one pound of biscuit, one gallon of beer and two pounds of beef; Wednesday one
pound of biscuit, one gallon of beer, a half pint of peas, one pint of oatmeal, two ounces of butter
and four ounces of cheese. Thursdays were the same as Sundays, Fridays the same as
Wednesdays and Saturdays the same as Tuesdays. On foreign voyages, the following authorized
substitutions could be made. A half pint of brandy, rum or arrack could take the place of a gallon
of beer. Four pounds of flour or three pounds of flour, a pound of raisins, a half-pound of currents
and a half-pound of beef suet equaled four pounds of beef or a two pound piece of pork with
pease. A half-pound of rice was equal to a pint of oatmeal, and a pint of olive oil was equal to a
pound of butter or two pounds of Suffolk cheese or a pound and a third of Cheshire cheese. 33
Messes on Royal Navy warships were typically composed of eight to twelve men. On
frigates like Pallas this number was probably considerably lower. One source suggests that on a
38-gun frigate of the Diana class, if six feet (1.83 m.) (the length of a hammock) were allowed
for each mess table, there would be room for twelve tiers of tables. With an inner and outer tier
on each side, for a crew of 240 men including officers, each mess would seat four to five men.
Even if only outer tiers were used, each mess would average about nine men. 34 The mess captain
collected the allotment for his entire mess in a wooden tub. Each man had his own spoon and
cup and all messmates ate out of the same tub. Bray’s watercolor of a marine mess on board the
Pallas shows that mealtime was rather informal and suggests that neither mess tables nor sea
chests were necessarily used during mealtimes (Fig. 39). 35
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All provisions were packed in casks and the beef and pork were salted and pickled in
casks. While in port, the biscuit was replaced by bread, and fresh meat was to be provided twice a
week when it was possible and convenient. Victualling vessels with a cargo consigned to one ship
could not be waylaid by another captain and the provisions were to be turned over to their
intended ship without charge to the purser. If the contents of a cask appeared spoiled when it was
opened, a survey was carried out by a panel of officers and if the contents were found unfit for
consumption, the purser was credited with its value. 36
Analysis of Royal Navy records shows that for the period 1750-57 the total proportion of
condemned foodstuffs issued by the victualling board amounted to less than one percent of that
issued. This was accomplished by the scrupulous use of only the best ingredients and continual
experiment and development. Great care was taken to ensure that stock was turned over and two
years was considered to be the maximum time that beef or pork should be stored in a cask even at
the end of long supply lines. The diet was plain and repetitive but provided more than sufficient
calories for the hard physical work of a seaman. When compared with the diet of the population
ashore, that of the seaman was quite extravagant, providing a daily hot meal, a beer ration every
day, and meat four times weekly. 37 This serves as yet another example of why, despite the rigors
and hardships, many men chose a life aboard a Royal Navy warship.
Dress
The common seaman in the 18th century was not required to wear a prescribed uniform.
His choice of clothing was instead dictated by the working conditions aboard ship. That they
dressed differently from landsmen, and in a distinctive fashion, is certain. Seamen were
immediately identifiable on land and were equally able to identify landsmen. Newly inducted
landsmen were the object of considerable derision and mistrust until they got their seaman’s
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clothes. The Marine Society was founded in 1756 in part to ensure that seamen and boys went to
sea properly attired. A 1757 list of the clothing supplied by the Society to men and boys
included: 38
Table 3: Showing the list of clothing provided to Royal Navy seaman and boys by the Marine
Society. After Robinson, “British Seaman’s Dress,” 325-7.
1 leather cap
2 worsted caps
2 pair shoes
3 hand kerchiefs
2 Hessen frocks
3 7/8ths check shirts
1 ticken mattress
1 striped flannel waistcoat
1 pillow
1 pair half-thick browns drawers
1 blanket
1 settee-waistcoat, blue duffil lined lapelled
1 coverlet
1 pair Russia-drab breeches
1 pair buckles
2 pair check drawers
1 pair buttons
2 pair yarn hose
1 sewing kit
2 pair worsted hose
1 knife
2 pair pett-duck trousers
Clothing was often available for sale aboard ship from the ship’s ‘slops,’ a small store of
items maintained by the purser. Most sailors were acquainted with the rudiments of sewing, and
often sewed strips of canvas over the seams of their clothing to extend wear. Shoes were
typically avoided unless the weather was unusually cold. Waistcoats or vests were worn in cold
weather and all seamen had an oilskin or some other form of water-resistant clothing. 39
The Royal Navy first introduced a specified uniform for officers and midshipmen in
1748. Until that time, it was the only maritime power not to have a distinctive uniform for its
officers. The new uniforms varied by rank but generally were similar except for decorative detail.
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The coat was blue with white trim, the waistcoat was white kersymere trimmed with lace. The
cloth was Prussian blue and very thick. The sleeves were cut short to allow the lace of the
waistcoat to show. Breeches were either white or blue kersymere and the three cornered hat was
blue with lace trim. 40 Officers had dress uniforms for formal occasions and undress uniforms for
day-to-day wear at sea—the latter often made them indistinguishable from the common seamen.
Officers were required to pay for their uniforms.
Health and Hygiene
In the Royal Navy during the 18th century, far more sailors died as a result of sickness
than died in battle. Malnutrition, communicable disease, and insect-borne fevers were the most
common ailments encountered by ship surgeons. In addition, a high occurrence of food
poisonings and dysenteries were common ailments capable of decimating whole crews. Scurvy,
typhus, and pulmonary tuberculosis were the most common culprits in tropical latitudes. Fevers
such as malaria, yellow fever, and undulant fever were a chronic problem. Whole ship’s crews
and even whole squadrons could be wiped out by fever in a relatively short period of time. In one
famous incident, a Caribbean squadron under the command of Admiral Hosier lost 4000 to 5000
men to tropical fever (probably yellow fever) during the years 1726-27. 41
By the early 17th century the deficiency of fresh fruits and vegetables was recognized as
the cause of scurvy. However, it was not until navy surgeon James Lind submitted his
comprehensive document, A Treatise of the Scurvey, (1753), that the Royal Navy instituted
permanent preventative measures to counter its occurrence—including citrus fruit or juice as a
part of the regular victuals. 42
During the 18th century, the cause of typhus was thought, as with many diseases, to be
impure air, bad smells and confined spaces. It was not until 1909 that it was understood to be
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transmitted by lice. Having made the association between lack of cleanliness and typhus, great
effort was made to maintain a clean environment aboard Royal Navy warships. One disease that
actually was the result of impure air and poor ventilation was tuberculosis.
The majority of the collectively-termed tropical fevers that plagued sailors during this
period were poorly understood and believed to be contagious. Although associations were made
between swampy environments and tropical fever, it wasn’t until 1847 that the direct connection
between fevers and biting insects was made.
Every effort was made to improve hygiene aboard Royal Navy warships throughout the
18th century and cleaning became a regular part of day-to-day activity. Conditions were further
improved during the 1740s and 1750s when Admirals Boscawen and Hawke campaigned for the
installation of below-decks ventilators.
An additional factor to be considered was the physical environment. Ships, especially
sailing ships, were dangerous places and the risk of physical injury from falls, falling objects,
over straining, and other mishaps was much higher than on land. Finally, moisture and cold
would have then, as it still does today, contributed to a much higher incidence of arthritis amongst
sailors. 43
One of the more interesting topics relating to shipboard health and hygiene was the
sanitary arrangements aboard ship. Privacy was of little consequence and there were a number of
ways a seaman could answer the call of nature. The easiest and most time-honored methods were
to go to the channels on the lee side of the ship and urinate off the side or, grabbing hold of the
shrouds, to hang out over the water and defecate. The wind and heel of the ship would ensure
that the waste was carried well clear of the sides. By the middle of the 17th century, round
enclosures were added to the channels of larger ships. By the 1620s, the beakhead also became
universally accepted as a place for men to relieve themselves and by the 1680s purpose-built
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‘seats of easement’ began to appear on ships. These were simple boxes with a round or keyshaped hole in the top and a conduit to direct the waste clear of the ship. By the late 18th century,
three rows of multiple seats became common on larger ships; however there was usually less than
one seat for every one hundred crewmen on board. Another sanitary arrangement that began to
appear in the late 17th century was the piss-dale—a urinal-like fixture mounted on the bulwarks
near the waist of the ship with the waste being carried out in a manner similar to scuppers. By the
middle of the 17th century, officers were usually afforded the privilege of enclosed private heads
located in the quarter galleries. 44
Leisure
The 18th century Royal Navy seaman relished his infrequent leisure time aboard ship and
put it to good use. Typically, simple pleasures such as fishing, sleeping, reading, writing,
drinking, and smoking were the most common. Games such as draughts (checkers), cards, and
dice were common among the crew with chess being the preferred game of officers (Figs. 36, 38
and 43). Yarning (storytelling) was a highly developed and appreciated talent amongst sailors of
the day. Arts and crafts such as rope work, macramé, embroidery, carving, model-making,
painting, and sketching were also popular leisure pastimes and have provided the world with
some great surviving maritime artifacts from which a great deal of anthropological data can be
drawn.
There is little doubt that common 18th-century Royal Navy seamen lived a rugged,
dangerous, and physically demanding existence. They lived, worked, and slept together in the
absolute minimum of space and could expect to go years without seeing their families and loved
ones. They risked a high mortality rate and received relatively little pay. However, it is equally
true that they enjoyed numerous benefits unavailable to the common landsmen. They were part of
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a proud, close-knit, supportive, and deeply loyal community. They generally ate better than their
land-bound counterparts (if somewhat more monotonously) and had access to top-notch (for the
day) medical attention. They also had access to basic education, and there is considerable
evidence that a great many learned to read and write while serving aboard Royal Navy warships.
They were able to travel and visit exotic ports of call. Finally, if they survived to retirement or
were crippled in the line of duty, they could expect to receive a modest pension from His
Majesty’s government.
Notes
1
Rodger, Wooden World, 150.
Ibid., 177
3
Ibid., 145-52.
4
Ibid., 26.
5
Ibid., 26-7.
6
Blake and Lawrence, Nelson’s Navy, 66.
7
Rodger, Wooden World, 348-51.
8
Lavery (ed.), Shipboard Life and Organization, 9-14.
9
Ibid., 23-5.
10
Ibid., 25-7.
11
Anonymous, Observations and Instructions, “Orders to the Boatswain”, Lavery (ed.), Shipboard Life
and Organization, 27-8, and Mountaine, Seaman’s Vade Mecum, 53-4.
12
Anonymous, Observations and Instructions, “Orders to the Boatswain”, and Mountaine, Seaman’s Vade
Mecum, 53-4.
13
Spavens, Memoirs of a Seafaring Life, 123 and Quarm, “An Album of Drawings by Gabriel Bray,” 39.
14
Lavery (ed.), Shipboard Life and Organization , 29-36.
15
Anonymous, Observations and Instructions, “Orders to the Carpenter” and Lavery (ed.), 1998, 38.
16
Anonymous, Observations and Instructions, “Orders to the Surgeon”.
17
Anonymous, Observations and Instructions, “Orders to the Purser” and J.L., Sea-Man’s Vade Mecum,
142.
18
Perrin, Boeteler’s Dialogues, 14-15, Lavery (ed.), Shipboard Life and Organization, 44, and Montaine,
Seaman’s Vade Mecum, 68.
19
Lavery (ed.), Shipboard Life and Organization, 43 and Rodger Wooden World, 23-4.
20
Lavery (ed.), Shipboard Life and Organization, 36-7.
21
Lavery (ed.), Shipboard Life and Organization, 41-2.
22
Rodger, Wooden World, 348-51.
23
Rodger, Wooden World, 39-40.
24
Lavery (ed.), Shipboard Life and Organization, 242-55.
25
Rodger, Wooden World, 124-29.
26
Rodger, Wooden World, 205-11.
27
Rodger, Wooden World, 211-17.
28
Rodger, Wooden World, 218-22.
29
Royal Navy Articles of War 1757, Articles 1-35.
2
112
30
Goodwin, Construction and Fitting, 210-11.
Anonymous, Observations and Instructions, Orders to the Boatswain, Blomfield, “Hammocks and Their
Accessories,” 146-7 and Mountaine Seaman’s Vade Mecum, 53-4.
32
Lavery Construction and Fitting, 165.
33
Mountaine, Seaman’s Vade Mecum, 72.
34
Lavery (ed.), Shipboard Life and Organization, 244-5.
35
Spavens, Memoirs of a Seafaring Life, 107, and Quarm, “An Album of Drawings by Gabriel Bray,” 39.
36
Montaine, Seaman’s Vade Mecum, 71-4, and Rodger, Wooden World, 82-7.
37
Rodger, Wooden World, 84-5.
38
Robinson, “British Seaman’s Dress,” 325-7.
39
Rodger, Wooden World, 94-95.
40
Manwaring, A Bibliography of British Naval History, 105-13.
41
Marcus, Heart of Oak, 128.
42
This is where the practice of referring to the British as ‘limeys’ originated.
43
BR2193- Handbook for Royal Navy Medical Officers, Articles 0101-0107, Lind, Treatise of the Scurvy,
“Of the Prevention of the Scurvy,” and Marcus, Heart of Oak, 128-42.
44
Lavery Construction and Fitting, 201-3.
31
113
CHAPTER VI
HMS PALLAS: SERVICE HISTORY
An examination of the service history of the frigate Pallas will demonstrate the role
frigates played in British strategic policy, the kinds of duties and responsibilities typically
assigned to them and will clearly illustrate the demanding maintenance requirements of all active
Royal Navy warships of the era.
At the outbreak of war with France in April 1756 the Royal Navy was acutely aware of
the inadequacy of its cruiser fleet. In order to protect British maritime trade and military convoys
from French predations and to carry the guerre de course to the French, more and better cruisers
were desperately needed. In response the Admiralty ordered nine new 32 and 36-gun frigates. It
was believed that these new designs could compete with and hopefully surpass their French
counterparts.
On August 31, 1757, the 128-foot hull of the Royal Navy’s newest warship class slid
down the slipway of the Wells shipbuilding firm at Deptford and into the Thames River. 1 The
ship, commissioned HMS Pallas, was one of the Royal Navy’s new classes of 36-gun, 12-pound
frigates. 2 These frigates, the 32-gun Richmond class designed by William Bately 3, and the 32gun Southampton class, 4 and the 36-gun Pallas class 5 designed by the recently appointed
Surveyor of the Navy, Thomas Slade, were developed in the early 1750’s, in response to a
perceived French superiority both in the sailing qualities and gun power of their cruisers. 6 The
designs for all three classes placed all of the guns on the main deck, quarterdeck and forecastle,
leaving the lower deck free for living space and the extra stores that would allow them to cruise
for months without putting in for provisions. The new frigates possessed the speed and sailing
qualities needed to elude larger warships and the strength to overpower any pirate, smuggler or
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privateer encountered. The completed hull of Pallas, on the day she was launched, lacked any
major fittings other than lower masts and bowsprit. She carried no ballast, raising considerable
concern regarding her stability until she could be floated into position and lashed alongside HMS
Gibraltar (24), for fitting out.
On September 3rd, Captain Archibald Cleveland arrived at Deptford and took possession
of Pallas. For the next month he supervised the final fitting out, crewing and provisioning prior
to her shakedown cruise to Long Reaches, Gravesend and The Nore. 7 The remarkably hasty
fitting –out period for Pallas is testimony to the urgency of the navy to supplement its cruiser
fleet.
On the morning of October 29, 1757 Pallas sailed with HMS Shannon (36), on her first
operational cruise with orders to support Admiral Edward Hawke’s squadron blockading the
French fleet at Brest (Map 2). On the following day, having lost sight of Shannon and sailing
alone, Pallas brought to several Dutch vessels.
Over the next month, Pallas patrolled with the squadron blockading the French fleet in
Brest. During this period she was variously in company with Shannon, HMS Medway (60),
HMS Dolphin (20), HMS Unicorn (28), HMS Ramillies (90), HMS Royal George (100), and
HMS Southampton (36), occasionally breaking away to pursue unidentified sails. On November
3rd, after a long chase, Pallas captured her first prize, a French privateer. Other than generally
poor weather, no other notable events were reported during this period. The deteriorating
weather began to take its toll on the fleet; damaged ships and support vessels began returning to
Spithead and on December 15th Pallas received word that the remainder of the fleet should begin
working to Spithead to ride out the weather.
The weather had obviously taken its toll on Pallas. On December 21, 1757 a pilot came
aboard to bring her into Portsmouth harbor for repairs. Over the following ten days, the guns and
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powder were removed, the main and mizzen shrouds were replaced, the blocks and rigging were
overhauled, new gammoning was installed on the bowsprit, iron ballast was removed to adjust
the trim and the hull was re-caulked. By the end of December, re-provisioning and re-rigging
were completed and the masts had been scraped and payed with pine varnish. On January 12,
1758 she was moved from Portsmouth harbor to Bembridge Point and on the 15th she sailed to
join HMS Eagle (60) and HMS Torbay (74) patrolling the Biscay coast about 200 miles (325
km.) southwest of Brest. Over the next two months she patrolled west and southwest of Brest
enforcing the blockade of French commerce (Map 2).
On February 14th Pallas returned to Plymouth Sound for general maintenance. On
February 20th it was discovered that the foremast was sprung under the upper wedges. The
foremast was removed the following day and on February 23rd Pallas was hauled into dry dock
where caulkers were employed in breaming the ship’s bottom. February 25th and 26th were spent
installing and rigging the new foremast.
By March 1st, Pallas had been re-provisioned and moved out into Plymouth Sound. On
March 3rd she sailed with HMS America (60) to patrol southwest of Plymouth. On the second
day her foremast stay parted. It is interesting to note that she did not immediately return to
Plymouth, but continued to patrol for two weeks encountering mostly British convoys bound for
the Americas. On March 17th Pallas re-entered Plymouth Sound. March 18th was spent fixing the
lower rigging, un-reaving the bad running rigging, and reaving new running rigging. On March
20th, the crew un-rigged the fore and main topmasts and re-rigged them the following day. On
March 22nd, Pallas once again made sail and returned to her patrol.
Between March 23rd and April 28, 1758 while patrolling off the southwest coast of
England, there were two notable encounters. At Land’s End on the 31st, Pallas sighted and
pursued a French frigate—her first encounter with an enemy warship. There was little or no wind
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and the Frenchman used sweeps to evade capture. On April 17th, just to the north of Le Havre,
Pallas liberated a British merchant ship taken by a French privateer (Map 2). 8 During this period
it appears that there was considerable concern on the part of the Admiralty regarding fever
aboard English warships and orders were issued that all ships should be washed with vinegar. 9
On April 18, 1758 Pallas dropped anchor at Spithead, and on April 24th was taken into
Portsmouth (Fig. 2) for general maintenance where the main and mizzen masts were found, like
the foremast before them, to be sprung. Either the ship was being driven hard or the quality of
the mast timber was poor. Since Pallas had been built during the first months of the war and
priority was given to the construction of frigates it is reasonable to assume that stockpiled
seasoned timber was employed in the hull construction—the longevity of Pallas hull supports
this view. However, by the time Pallas was launched, stockpiles of seasoned masts and spars
would have been used up servicing active ships and in fitting-out ships brought out of ordinary.
Therefore Pallas probably received sub-standard masts and spars. The new main and mizzen
masts were stepped and re-rigged by May 10th. Having been re-provisioned Pallas made ready to
sail, but on the following day, the foremast was found to be sprung beneath the wooldings.
Pallas remained in Spithead until June 1st replacing the foremast and carrying out general
maintenance. 10
There is a gap in the logbooks from June to October of 1758. However, it is known that
on June 6th Pallas took part in the destruction of shipping and storehouses at St. Malo and that
from August 6th to the 17th, Pallas participated in Admiral Richard Howe’s raids on Cherbourg.
On August 7th Howe temporarily transferred his flag to Pallas so that he could stand in closer to
shore during the operation. 11 By October 6th, Pallas was back at Portsmouth undergoing a major
overhaul. The lower masts were replaced and re-rigged, a new best bower cable was taken
aboard, and she was hauled into dry dock for breaming, caulking, and blacking. Once again this
117
illustrates the hard service that frigates were subjected to and the shortage of quality timber
available to the Royal Navy as the war progressed. On November 1st, the ship’s company
received its first distribution of prize money. 12 Provisioning was completed by November 6th
and Pallas was moved to Spithead where she remained at anchor until November 11, 1758.
The following day, Pallas set sail from Spithead with orders to escort HMS Saltash (14),
which was carrying silver to pay the garrison at Senegal, and to then join up with Admiral
Augustus Keppel’s fleet off West Africa. 13 On November 17th the fleet was sighted and they
joined company with Torbay and 16 merchant ships (referred to in Pallas’ logbooks as 16 sail).
Pallas parted company with the fleet on November 20th, just off Lisbon, dispatched back to
England. 14 For the remainder of 1758 Pallas patrolled the Bay of Biscay as far north as Le
Havre, at various times in company with HMS Actæon (28), Deptford (50), Essex (64), Windsor
(60), and the Rochester privateer (Map 2).
On January 1, 1759, Pallas returned to Portsmouth for general maintenance. On January
30th after maintenance and provisioning she joined a large fleet anchored at Spithead under the
command of Admiral Charles Holmes. On February 14th, Pallas set sail in company with HMS
Chatham (50), HMS Falkland (50), HMS Chichester (70), and HMS Boreas (28), escorting an
outbound East India convoy. Together they patrolled the southern approaches until February 24th
when Chichester and Chatham parted company leaving Falkland in command of the convoy. On
March 12th, the four ships met up with again. On the same day the main mast of Pallas was
found to be sprung. The following day, the carpenter from Boreas came aboard to assist in
woolding the mast. Pallas parted company with Boreas on March 14th, came safely to anchor at
Spithead two days later, and the following day was moved into Portsmouth Harbor. Over the
next ten days, the main mast was replaced and general maintenance and provisioning were
carried out.
118
On April 4, 1759, Pallas set sail in company with Essex, and the Jamaica sloop and
anchored at Needle Point. They were joined by Chatham on the following day and commenced
their patrol of the French coast. For the next three weeks, the four ships patrolled off Brest
enforcing the commercial blockade, bringing-to numerous vessels, and liberating a Jamaican
prize taken by the French (Map 2). On April 26th, Essex (64), and Chatham, returned to
Plymouth with the prize and Pallas made for Portsmouth. From April 29th to May 21st, Pallas
rode at anchor at Spithead and carried out general maintenance in Portsmouth harbor. There she
joined an assembled fleet that included HMS Nottingham (60), HMS Hercules (74), HMS Venus
(36), and HMS Minerva (32), as well as Chatham and Essex.
At some point during the beginning of June Captain Archibald Cleveland departed and
Captain Michael Clements took command of Pallas. 15 Clements would remain captain until
Pallas was paid off in January 1764. 16 On June 18, 1759 Pallas sailed from Spithead in the
company of HMS Rochester (50) and a cutter with orders to patrol the Channel coast and the
Bay of Biscay near Brest. On July 5th, Pallas stood into Brest harbor firing on French ships there
and at the shore batteries at St. Matthew’s Convent. From July 6th to 16th, Pallas continuously
harried the French at St. Matthew’s Convent and in Brest harbor (Map 2). On the following day
she turned for home and on July 18th entered Plymouth Sound. Over the course of the next week
she was heeled and her bottom cleaned and the crew carried out general maintenance and loaded
provisions aboard.
On July 28th, Pallas sailed from Plymouth in company with HMS Hero (74), HMS
Sapphire (32), Southampton, and Venus to relieve Admiral Hawke’s force blockading the French
ports of Brest and Le Havre. Pallas remained with Hawke’s fleet through the summer without
notable encounter and returned to Plymouth Sound on October 3rd. 17 She spent the next two
119
weeks having a sprung bowsprit replaced, carrying out general maintenance and loading
provisions for three months at sea.
On October 19, 1759 Pallas set sail from Plymouth Sound with orders to patrol the
French coast of the Bay of Biscay around Quiberon Bay, Belle Isle, and the Isle of Groa (Ile de
Groix) (Map 2). Between October 29th and November 14th she was variously in company with
HMS Vengence (28), HMS Firm (50), HMS Maidstone (28), Chatham, Venus, Sapphire,
Southampton, and the Swallow sloop. There is a gap in the logbooks in the crucial period from
November 15th until January 5, 1760, but it is known that Pallas joined Hawke’s fleet on the 15th
and that on the same day the sloop of war Fortune arrived with news that the French Grand Fleet
was making for Quiberon Bay. 18 Firm and Southampton where dispatched to carry the news to
Hawke’s fleet and Pallas was dispatched to carry the news to the commanders of Fame and
Windsor, cruising off of Finisterre, with a request to bring out the remainder of their squadron. 19
On November 19th, Hawke’s combined fleet crippled the French fleet at the Battle of Quiberon
Bay, essentially ending any threat of a French cross-channel invasion of England.
Pallas returned to Plymouth on January 5, 1760 where she remained until January 29th
carrying out general maintenance and provisioning. The following day she sailed with her sister
ship HMS Brilliant (36) with orders to patrol St. George’s Channel between Ireland and Wales
(Map 2). For more than two weeks they patrolled south and southwest of Ireland and on
February 18th came to anchor at Kinsale Harbor in southern Ireland. General maintenance was
carried out until February 25 when Pallas and Brilliant, accompanied by HMS Æolus (32),
resumed their patrol. On February 28th, Pallas, Brilliant, and Æolus encountered three strange
ships and gave chase. They proved to be the French frigates Marechal de Belle Isle (44), La
Blond (36) and Terpsichore (24). 20
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The French frigates had been dispatched from Dunkirk in October with a small
detachment of troops under the command of the renowned privateer Captain François Thurot
with orders to sail north and land a diversionary force in Ireland in preparation for the crosschannel invasion. Thurot’s passage around northern Scotland had been plagued by bad weather
delaying his arrival off the Irish coast for several months. Unaware that the invasion had been
thwarted by Hawke at Quiberon Bay the previous fall, Thurot carried out his assignment
temporarily landing a small force near town of Carrickfergus. 21
The two squadrons engaged off the Isle of Man and after a short, hour and-a-half long
battle, all three French ships were taken (Fig. 34). Pallas suffered sail and rigging damage, a shot
through the mainmast and had her best bower was shot away. The three French prizes were taken
to Ramsey Bay where the prisoners were put ashore and temporary repairs were made. On
March 6th, Pallas, Brilliant, Æolus, Weasel sloop and the three prizes sailed for Plymouth,
stopping at Kinsale Harbor on the way, and arriving at Plymouth Sound on March 26th. 22 For the
next two weeks Pallas underwent repairs.
On April 9th Pallas returned to patrolling the French channel coast near St. Matthew’s
Convent and Brest (Map 2). On April 16th, lookouts sighted a sail and Pallas gave chase. The
ship proved to be French and the two ships exchanged fire. During the engagement the French
ship was ran aground so violently that her masts fell. Pallas wore and raked her to finish the
job. 23 On April 17th Pallas joined company with HMS Shrewsbury (74) and they remained in
contact until Pallas returned to Plymouth sound on May 24th. She remained in Plymouth
between May 25th and June 16, 1760 undergoing a major overhaul, and departed on June 17th
bound for service in the Mediterranean. 24
On June 23rd, about 100 miles (160 km.) southwest of Brest, Pallas again sprung her
foremast. She continued south for two weeks, sighting the rock of Lisbon on July 3rd, passing off
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Cadiz on July 4th,and arriving at Gibraltar on the following day. Pallas spent a week in Gibraltar
having her foremast repaired and taking on provisions. She sailed on July 12th and patrolled off
Europa Point and Gibraltar for the next week. On July 24th, she began to work eastwards and, on
July 29th, came to anchor at Majorca. On August 7th, she departed Majorca bound for Malta,
arriving there four days later (Map 3).
There is a gap in the Pallas’ logbooks from August 11, 1760 until the beginning of
October. However, it is known that Pallas joined up with Admiral Charles Saunders’ fleet
blockading the French Fleet at Toulon. At some point after July 12th Pallas, Shrewsbury, and
HMS Argo (28), engaged in a running battle with the French 74-gun Diadème escorting a
convoy to Martinique. Shrewsbury was a poor sailor and it was left to the frigates to harass and
slow Diadème until Shrewsbury could catch up. Unfortunately, Pallas exposed herself to a
broadside from Diadème, suffered significant damage, and was forced to break off the pursuit.
Diadème later took part in both the Battle of the Capes (that forced the surrender of the
British Army at Yorktown), in October, 1781 and Battle of the Saints, April, 1782. 25 It is
probable that most of the remaining period missing from the logbook was spent at Gibraltar
making repairs to the damage inflicted by Diadème.
In early October, 1760 Pallas returned to patrolling in the western Mediterranean around
Malta and Cape Angelo with HMS Somerset (64), HMS Dunkirk (60), HMS Shannon (36), and
Shrewsbury. 26 For the next five months in late 1760 and early 1761, Pallas patrolled the western
Mediterranean calling variously at Messina in Sicily, Malta, Tunis, Leghorn (Livorno, Italy), and
Cagliari Bay for maintenance and provisions. The only incident of note was the capture of a
French prize off Cape Negro, Morocco (Map 3). 27
There is month-long gap in the logbooks from April 30th to June 5, 1761. From June 6th
to 19th, Pallas was once again moored in Malta where she took on provisions, had her rigging
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overhauled and carried out general maintenance. Another month-long gap occurs from June 19th
to July 23rd. From July 24th to September 1st, Pallas was moored in Leghorn. There she
underwent a complete refit: careening, caulking, and breeming. The decks, masts and sides were
scraped and payed. New masts were stepped and new rigging was installed, and the whole ship
and the gun carriages were painted. Pallas sailed from Leghorn Road in early September 1761
on a five-month patrol of the western Mediterranean, the eastern approaches to Malta and the
‘Strait of Sicily’ (presumably the Straits of Messina), periodically calling at Messina, Tunis and
Malta before returning to Gibraltar on March 16, 1762 (Map 3). While there she was overhauled
and the crew was employed in picking oakum before sheathing the hull. 28
Departing Gibraltar on May 1, 1762 Pallas sailed out to patrol up the east coast of Spain
to Villefranche Bay east of Nice, arriving on May 11th. Pallas remained at Villefranche for
several weeks taking on provisions and carrying out general maintenance before returning to
Gibraltar in late May. 29 For the next eight months she patrolled off Cadiz, Cape Trafalgar, the
Atlantic approaches to Gibraltar, and the Atlantic coast of Morocco, returning periodically to
Gibraltar or Lagos Bay for provisions and general maintenance. The only incident of note took
place on July 23rd in Cadiz harbor when Pallas was attacked by two xebecs—low fast coastal
vessels—which were driven off after suffering heavy casualties. 30
On February 10, 1763 the war with France came to an end with the signing of the Treaty
of Paris. News of the peace had probably not yet reached Gibraltar when, on February 17 1763,
Pallas sailed with Dunkirk, Chichester, and a convoy of merchant vessels bound for England.
On February 26th, Pallas parted company with the convoy and entered Lisbon Harbor where she
remained moored until March 14th when she returned to Gibraltar. Pallas remained moored in
Gibraltar or Cadiz from March 18 until the end of April, sailing in early May to patrol the south
coast of France and western Italy, calling at Cagliari, Genoa, and Leghorn (Map 3). By the first
123
week of July she had returned to Gibraltar for provisions and general maintenance. From July
until late November 1763 she was moored intermittently between Gibraltar and Cadiz. On
November 22nd she sailed for Lisbon en route to Spithead, arriving on December 21st. A pilot
came aboard the following day to bring her into Portsmouth harbor and between December 22nd
and January 13th, Pallas was stripped of her spars and fittings and placed in ordinary. On January
14, 1764, the crew was paid off. 31 This completed a period of over six years of active service in
home waters and in the Mediterranean. The logbooks clearly show that Pallas was worked hard
throughout this period displaying both her utility and durability.
The stripped hulk of Pallas languished in the ordinary yard at Portsmouth for nearly
seven years before she was once again commissioned in early October 1770 and a new
commander, Captain John Laforey, took possession. 32 During the period of her working up, from
October until March of 1771, she was either in Portsmouth harbor or at Spithead. A letter exists
from Captain Laforey to the Admiralty requesting authority to crew her, and several letters from
Laforey to the Admiralty during that period describe both chronic illness and personal problems.
In one letter he simply asked to be replaced, in his next letter he claimed to be so ill that he could
not travel without endangering his health and in his final letter he requested leave citing the poor
order of his family affairs. 33 The tone of the correspondence suggests that Laforey did not want
command of Pallas. At some point at the beginning of 1771 Captain Laforey was relieved and
Captain C. Watson took command of Pallas. 34
Pallas remained at anchor at Spithead until May 5th when she received orders to sail for
the Mediterranean. On May 13, 1771 Pallas joined company with frigates HMS Pearl (40) and
Minerva off Porto, Portugal, and together they made for Gibraltar (Map 2). On May 28th, Pallas
sailed into the Mediterranean with Minerva. Captain Watson was made commodore of the fleet
charged with protecting English trade interests in the Levant and evacuating English subjects
124
should it become necessary. 35 They arrived in the Gulf of Smyrna on July 7th, and remained
moored there until the end of November, carrying out general maintenance and showing the
British flag. A letter from Captain Watson to the Admiralty dated July 6th reports their arrival on
station and advises that a plague was at the time ravaging Smyrna. 36 On November 30th Pallas
sailed from Smyrna and returned to the western Mediterranean, patrolling the north coast of
Africa and the south coast of Spain, arriving off Europa Point, Spain on February 8, 1772. On
February 9th she anchored in a squall and was obliged to cut away her bower before entering
Gibraltar harbor on the following day. 37
Pallas remained moored in Gibraltar harbor before sailing on April 5th. The following
day a shock ran through the ship and it was feared that she had hit an uncharted rock but no
damage was found. It was later determined to have been an earthquake. On April 12th Pallas
arrived at Lisbon where she remained moored in the Tagus River for several weeks before
returning to Gibraltar on May 1st. A week later she sailed for the eastern coast of Spain where
she patrolled for the next four months, calling periodically at Port Mahon for maintenance and
provisions before returning to Gibraltar on September 17th. There is a gap in the record of Pallas
for the period September 18th until December 8th. From December 9th until March 25, 1773, she
remained at Gibraltar. 38 On March 26th, she sailed with orders to patrol the Atlantic approaches
to Gibraltar and then to make her way back to England.
At some time during the following month, it was decided to again place Pallas in
ordinary. Captain Clements was re-assigned and Captain James Alms took command for the
duration of her decommissioning. 39 The crew was paid off and Pallas was placed in ordinary in
June 1773.
It was only slightly more than a year before the need to protect England’s commercial
interests abroad compelled Pallas’ return to service. The frigate was re-commissioned on
125
October 5th 1774 and spent the next five weeks moored in Portsmouth harbor working up, where
a new captain, William Cornwallis, took command. 40 It is also worth noting that Gabriel Bray,
the new senior Lieutenant, joined Pallas’ crew at this time. Over the course of the next several
voyages, Bray would create a series of amazing and useful watercolors of life aboard Pallas
(Figs. 35 to 43)
On December 12, 1774 she sailed in company with Weasel sloop with orders to patrol
down the Atlantic coast of West Africa. Presumably, the British government intended to prevent
American colonial smugglers from doing business with, and acquiring arms from, sympathetic
European nations through West African trading posts. Pallas worked down the coasts of
Portugal and Morocco, passing the island of Palma in the Canaries on New Year’s Day 1775,
and arriving at Santa Cruz Bay in the Canaries on January 6th (Map 4). On January 18th Pallas
and Weasel sailed south from Tenerife, running down the Senegal Bar. On January 28th the two
vessels anchored off the Senegal fort and Pallas sent 25 half barrels of powder ashore to the fort
at the request of the Governor there. (Figs. 35 and 36). The following day Pallas and Weasel
continued south, taking two French prizes before coming to anchor on February 4th in the
Gambia River off James Island where they delivered 15 half barrels of powder to Fort James. On
February 10th they ran down the Gambia River and continued south down the West African
coast. On February 17th they moored in Frenchman’s Bay on the Sierra Leone River and on
March 2nd continued south arriving at the English fort at Whydah on April 3rd. There they found
numerous ships of all nationalities (map 4).
On April 5, 1775, Pallas parted company with Weasel and began her first trans-Atlantic
crossing and on April 18th she passed south of the equator for the first time in her career. She
remained in the southern hemisphere for the next two weeks as she sailed west but at no point
did she venture more than two degrees south. On May 31st, 55 days after sailing from Whydah,
126
Pallas arrived at Barbados and dropped anchor in Carlisle Bay the following day. There are few
comments in the logbooks regarding this passage other than the decks were washed regularly
with vinegar and the guns were exercised more frequently than usual. 41 However, it is known
that the crew was suffering from scurvy upon Pallas’ arrival in the Caribbean. 42 On June 1, 1775
Pallas sailed from Barbados for Port Royal, Jamaica (Map 5). She spent several weeks at Port
Royal taking on provisions and undergoing a general overhaul. It was probably there that the
crew of Pallas learned that war had broken out with the American colonies. On July 13th she
sailed from Port Royal, patrolled around Jamaica and the Caribbean and then returned to
England arriving at Spithead on August 28th.
During the next two months, Pallas took on provisions, had her rigging overhauled,
received a new bowsprit, new gammoning, and new shrouds and spent two and a half weeks in
dry dock. 43 On November 16, 1775, she sailed with orders to once again patrol down the Atlantic
coast of Africa supporting England’s commercial interests and suppressing smuggling and gunrunning ventures by the American rebels. 44 Pallas called at Madeira and Santa Cruz Bay in the
Canary Islands before arriving at Goree on January 8, 1776 (Map 4). The following day she
continued south past the mouth of the Gambia River and down the African coast, arriving at
Whydah on March 31st.
Between January 22nd and 30th, Pallas was in Frenchman’s Bay at the mouth of the
Sierra Leone River investigating rumors of an American ships hiding up the river. Unable to take
Pallas into the shallow river, Captain Cornwallis exceeded his authority by acquiring the St.
John sloop from the local proprietors of the Bence Island plantation. The St. John was fitted out
and armed with eight guns and small contingent of officers and men were transferred from
Pallas under the overall command of Lieutenant Alexander Agnew. Cornwallis ordered Agnew
to patrol around Cape Coast interdicting American ships attempting to buy arms and
127
ammunition. Agnew was immediately successful, taking a schooner belonging to South
Carolina. Also during this period Weasel sloop captured an American brig with the assistance of
First Lieutenant Gabriel Bray of Pallas who had taken command of a prize ship, presumably the
schooner captured by St. John. Bray was then ordered to sail the prize to Antigua in the
Caribbean. 45
On May 3, 1776 Pallas began her second transatlantic crossing, arriving at Port Royal,
Jamaica on June 21st without notable incident. She remained moored in Port Royal harbor until
July 6th when she sailed with the frigate Maidstone, and 22 sail of merchant vessels bound north
up the American coast but the convoy was forced to return to Port Royal. By July 10th, the fleet
had grown to include Pallas, Maidstone, the West Florida packet, and 105 merchant vessels.
Further delayed by a shortage of water, the convoy did not sail until late September. 46 On
October 1st Pallas liberated the Anne, an English vessel bound from Dominica to London that
had been taken by an American privateer. On October 3rd Pallas and Maidstone chased off what
appeared to be an American privateer and on October 12th the convoy entered St. Lawrence
harbor, Newfoundland, and came to anchor. On October 29th they sailed with a convoy bound for
England arriving at Spithead on November 17th without any notable incidents being recorded in
the logbooks. However, other documents make it clear that the crossing was anything but
uneventful. They were plagued by poor weather, hounded by American privateers and Captain
Cornwallis complained bitterly of the poor discipline of the convoy. Only 44 of the
merchantmen arrived in England in convoy with Pallas. 47
There is a gap in the logbooks from November 17th until December 28, 1776 but it is
reasonable to assume that Pallas remained moored at Spithead for that period. On December
28th, Pallas was moved into Portsmouth harbor where she remained for a month receiving a refit,
general maintenance, and provisioning. 48 At some point during this layover, Captain Cornwallis
128
was reassigned and Captain Rowland Cotton took command of Pallas. 49 On January 24, 1777,
Pallas was moved back to Spithead where she remained moored through the following month. 50
March 1st Pallas sailed with orders to escort a convoy to Tenerife and Grand Canary
(Map 4). They arrived at Tenerife on March 20th and patrolled the African coast until June 2nd
when she again headed across the Atlantic arriving at Carlisle Bay, Barbados, without incident
on July 26th. On November 10th Pallas, the hired armed ship Bute (10), and Nancy sloop, with a
convoy of 17 merchant vessels, sailed north up the American coast. 51 The following week Pallas
and Bute liberated an unidentified schooner that had been taken by an American privateer. 52 On
November 29th, Bute started taking on water and a carpenter from Pallas was sent aboard to
assist. By December 3rd Bute was determined to be beyond saving and was scuttled by her
captain. There is no record of the Atlantic crossing but Pallas came to anchor at Spithead on
January 14, 1778 without apparent incident. 53
The already overextended resources of the Royal Navy were stretched further when
France’s signed an alliance with the United States on February 6, 1778. The need to protect
England’s commercial fleet overseas and now increasingly closer to home placed a much greater
burden on the Navy and the frigates in particular.
At some point in early 1778, Captain Rowland Cotton was reassigned and Captain
Richard King took command of Pallas. 54 From January 17th to 29th Pallas sat in Portsmouth
harbor waiting to enter the dry dock; she was moved there on January 30th and remained until
April 24th. 55 Almost three months in dock suggests a major overhaul or refit, but the only notes
regarding the work being done simply state that the iron ballast was removed, the holds were
cleared and rummaged, and that there was fitting and rigging done. It is almost certain that
Pallas was coppered during this period in dry dock. Pallas left dry dock on April 25th but
remained in Portsmouth harbor until May 18th presumably taking on stores, provisions, guns and
129
powder. On May 19th she was moved to Spithead where she remained at anchor until the 27th
when she sailed to Torbay. From May 28th to June 12th Pallas rode at the fleet anchorage at
Torbay.
At this point there is another gap in the logbook account. There is no suggestion in the
logbooks that Pallas took part in the Battle of Ushant off the French coast on July 27, 1778. The
next place that Pallas can be firmly located is arriving at the mouth of St. Lawrence River on
August 24, 1778. It is doubtful that Pallas again undertook her annual patrol down the Atlantic
coast of Africa as these patrols typically took eight months to a year. It is more likely that the
frigate was employed escorting troop and supply convoys needed to combat the rebelling
colonies in North America. During September and October Pallas engaged in several short
cruises around Cape Race, Cape Chapeau Rouge, and Newfoundland (Map. 5). At some point in
October of 1778, Captain King was reassigned and Captain Thomas Spry took command of
Pallas. 56 On November 1st, Pallas sailed from St. John’s, Newfoundland, in company with HMS
Invincible (74) escorting 40 merchant sail to Gibraltar, arriving there on November 29th with no
notable incident. On December 30th, after taking on provisions at Cadiz, she sailed for Spithead
arriving on January 25, 1779, where she remained undergoing a refit. 57
The Royal Navy now faced war on its doorstep and wasted no time responding to the
new threat. On May 3rd Pallas sailed from Spithead to patrol the French coast and the English
Channel, in and around ‘Gernsey’, Gravedela Bay, Concale Bay, and Cawsand Bay. There is
some indication that she engaged in some sort of action at Concale Bay but no specific details
were found. 58 Pallas returned to Spithead on May 22nd and remained at anchor there until June
16th.
On June 17, 1779, Pallas departed Spithead in company with Cameleon sloop escorting
a convoy of 28 sail bound for Jamaica. They sailed south through the Bay of Biscay and along
130
the Portuguese coast calling at the island of Madeira on July 3rd and continuing on to Port Royal
arriving on August 25th, arriving too late to participate in the Battle of Grenada on July 6th. For
the next twenty-one months Pallas patrolled the Caribbean around Port Royal interdicting
American and French ships in the region (Map 5). During this period, either alone or in company
with other Royal Navy warships, Pallas was involved in the taking of at least eight prizes,
including an American ship. 59 There is no suggestion in the logbooks that Pallas participated in
the Battle of Martinique on April 17, 1780. It was probably during this extended period in
warmer waters that the teredo infestation established itself in Pallas hull.
On August 21, 1781 Pallas sailed with a fleet including HMS Ramillies (90). Pallas was
apparently detached from the fleet and joined company with HMS Diamond (32) on September
15th. The two frigates circled south past Puerto Rico and Bonaire before arriving back at Port
Royal Jamaica on November 6, 1781. At some point late in 1782 Captain Spry was replaced by
Captain John Thomas. It is unclear where and when this occurred, only that it was before the end
of 1781. 60 However, orders sent to the captain of Pallas by Admiral George Rodney, then in
command of the fleet at Port Royal, between March 6th and July 8th were addressed to Captain
John Thomas.
From December 12th 1781 to February 28, 1782, Pallas patrolled around the Turks and
Isabella Point with HMS Resource (24) returning to Kingston on March 1st and Port Royal on
March 6th. There is no suggestion in the logbooks that Pallas participated in the Battle of St.
Kitts on January 25-26, 1782. Pallas remained at Port Royal until May 21st replacing the main
mast and therefore also missed taking part in the Battle of the Saints on April 12, 1782. While in
Port Royal Admiral Rodney ordered Pallas’ boatswain to participate in a survey of the
boatswain’s stores of HMS Royal Oak (74), her gunner to participate in a survey of the powder
and gunner’s stores of HMS Fame (74), and her master to participate in an overall survey of
131
HMS Ajax (74). Pallas herself had her fore topsail surveyed. There is also a curious order by
Rodney to supplement Pallas with a further compliment of surgeons. 61
From May 22nd Pallas carried out a short patrol returning Port Royal on June 27th where
she remained until July 11th. While there Captain Thomas received orders from Rodney for
Pallas’ gunner to provide one twelve-pound gun to the gunner of HMS Barfleur (98) 62 He was
also ordered to discharge 50 able seamen to help man the prizes taken at the Battle of the Saints
and to take on board 50 French prisoners-of-war. On July 8th or 9th, with no reason given,
Thomas was replaced as captain of Pallas by Captain Christopher Parker. The logbooks make no
note of this but on July 8 Rodney’s orders to Pallas’ captain were addressed to Captain Thomas
of His Majesty’s Ship Pallas, on July 9 his orders were addressed to Captain Parker of His
Majesty’s Ship Pallas. 63
On July 25, 1782 Pallas sailed with Admiral Samuel Graves and a large fleet including
HMS Ramillies (90), HMS Canada (74), HMS Centaur (74), the French prizes Ville de Paris
(104), Le Glorieux (74), L’Ardent (64), Le Jason (64), Le Caton (64), and a large convoy of
merchant vessels bound for England. The French ships had been taken on April 12th at the Battle
of the Saints off Dominica where Admirals Rodney and Samuel Hood decisively defeated
French Admiral De Grasse. En route to England, the convoy encountered severe weather off the
American coast (Map 5). On September 8th, Le Caton developed a serious leak and was ordered
to Halifax, Nova Scotia, accompanied by Pallas. Ultimately, Ramillies and Centaur would be
lost and several of the French prizes were damaged beyond salvage. 64
There is a gap in the logbooks from September 1782 to January 1783. However, it is
known that once Pallas had delivered Le Caton safely to Halifax, she immediately returned to
sea to round-up and lend assistance to what remained of the scattered convoy. In late September
1782, Pallas arrived in England towing the damaged merchantman Lady Juliana (Fig. 44). 65
132
From October 1782 until January 1783, the whereabouts of Pallas are unknown. There is not
enough time for her have to once again patrolled down the African coast before crossing the
Atlantic. It is more likely that Pallas returned directly to North America, perhaps still searching
for remnants of the scattered convoy. Whatever the case, Pallas ended up in Halifax sometime in
January of 1783. 66
In late January, Pallas sailed from Halifax escorting a convoy bound for England.
Several leaks became apparent soon after sailing and, to compound the difficulties, Pallas
became separated from her charges in a storm. By the 5th of February, despite non-stop pumping,
there was eight feet (2.44 m.) of water in the hold. The guns and most of the stores were thrown
overboard and Pallas made a desperate run for the Azores (Map 1). On February 10th Pallas
arrived off the island of Fayal but stormy weather prevented her from anchoring. On February
12th the exhausted officers and crew managed to bring Pallas into Calheta harbor on the south
shore of the island of São Jorge. Upon examination of the hull it was found that the keel and
garboards were so riddled with teredo worm that they were nearly non-existent. The crew
unloaded the remaining stores, salvaged what they could and set Pallas on fire. 67
Notes
1
Gardiner, First Frigates, 22-28.
This was the first HMS Pallas commissioned in Royal Navy history.
3
Richmond and Juno. Thames, Boston, Lark and Jason would follow between 1758 and 1763.
4
Southampton, Vestal, Minerva, and Diana.
5
Pallas, Venus, and Brilliant.
6
Gardiner, First Frigates, 22-28.Existing British 24-gun –36-gun, 9-pound vessels possessed similar
sailing qualities but carried considerably less broadside weight than the new French 36-gun, 12-pound
frigates. British 44-gun two-deck heavy cruisers possessed superior firepower to the French design but
they were inferior sailors. Also, the low freeboard of the lower deck gunports on the 44-gun heavy cruisers
often meant that they could not be opened in heavy seas thereby limiting them to the same broadside as a
20-gun, 9-pound sloop.
7
For daily activities as recorded in the ship’s logbooks, see Appendix C.
8
TNA: PRO ADM 51/666, Lieutenant’s Logbooks from HMS Pallas. Unless otherwise noted, following
information is extracted from TNA: PRO ADM 51/666 Lieutenant’s Logbooks from HMS Pallas.
9
TNA: PRO ADM 1/1606, Admiralty Correspondence.
2
133
10
TNA: PRO ADM 51/666, Lieutenant’s Logbooks from HMS Pallas.
Beatson, Naval and Military Memoirs, Vol 2, 263-4, Sainsbury, Royal Navy Day by Day, 164, 229, and
Clowes, Royal Navy, Vol. 3, 193-194. For a detailed description of this action and Pallas’ role based on
Admiral Howe’s correspondence with the fleet, see N.A.M. Rodger, Naval Miscellany, Vol. 5, 213-43.
12
TNA: PRO ADM 51/666, Lieutenant’s Logbooks from HMS Pallas. The logbook is not specific about
what prizes were being paid for.
13
Marsh, “Taking of Goree,” 121.
14
TNA: PRO ADM 51/666, Lieutenant’s Logbooks from HMS Pallas. Note the longitudes given 39º lat.
6º long. on Nov. 20 and 40º lat. x6º long. on Nov 22 are incorrect coordinates that would place Pallas high
and dry in Western Spain.
15
TNA: PRO ADM 51/666, Lieutenant’s Logbooks from HMS Pallas. There is no indication regarding
the circumstances of this change of command.
16
NMM: PJ/JC Vol. 1, National Maritime Museum Warship History Continuation Sheet microfilm.
17
TNA: PRO ADM 51/666, Lieutenant’s Logbooks from HMS Pallas. It is unclear why there is this gap
in the activity of Pallas.
18
Beatson, Naval and Military Memoirs, Vol.2, 416.
19
Spavens, Seaman’s Narrative, 48-50.
20
TNA: PRO ADM 51/666, Lieutenant’s Logbooks from HMS Pallas. Beatson, Naval and Military
Memoirs, Vol 3, 53-5.
21
Jenkins, History of the French Navy, 129-136
22
TNA: PRO ADM 51/666, Lieutenant’s Logbooks from HMS Pallas.
23
TNA: PRO ADM 51/666, Lieutenant’s Logbooks from HMS Pallas No information is given regarding
the ship type but there is little chance that it was a warship but more likely a French privateer or smuggler.
24
TNA: PRO ADM 51/666, Lieutenant’s Logbooks from HMS Pallas.
25
Beatson, Naval and Military Memoirs, Vol 3, 48,57. Clowes, Royal Navy, Vol. 3, 303.
26
TNA: PRO ADM 51/666, Lieutenant’s Logbooks from HMS Pallas.
27
TNA: PRO ADM 51/666, Lieutenant’s Logbooks from HMS Pallas.
28
TNA: PRO ADM 51/666, Lieutenant’s Logbooks from HMS Pallas. This is a clear reference to hull
sheathing. However, NMM: PJ/JC Vol.1 National Maritime Museum Warship History Continuation Sheet
microfilm, records that Pallas was coppered between October 1778 and May 1779.
29
Clowes, Royal Navy, Vol. 3, 253. At this time the area around Villefranche was independent and not a
part of France.
30
Beatson, Naval and Military Memoirs, Vol 3, 217.
31
TNA: PRO ADM 51/666, Lieutenant’s Logbooks from HMS Pallas. This is the end of the logbooks
designated NMM: ADM 51/666.
32
TNA: PRO ADM 51/667, Lieutenant’s Logbooks from HMS Pallas. Unless otherwise noted following
information is extracted from TNA: PRO ADM 51/667 Lieutenant’s Logbooks from HMS Pallas.
33
TNA: PRO ADM 1/2053.
34
NMM: PJ/JC Vol. 1, National Maritime Museum Warship History Continuation Sheet microfilm.
35
TNA: PRO SP 97/58, Admiralty Correspondence.
36
TNA: PRO SP 97/58, Admiralty Correspondence.
37
TNA: PRO ADM 51/667 Lieutenant’s Logbooks from HMS Pallas . There is a gap in TNA: PRO ADM
51/667, Lieutenant’s Logbooks from HMS Pallas, from April 1st until December 9th that is partially
covered in TNA: PRO ADM 51/4283, Lieutenant’s Logbooks from HMS Pallas.
38
TNA: PRO ADM 51/667, Lieutenant’s Logbooks from HMS Pallas. The record recommences after gap
filled by TNA: PRO ADM 51/4283, Lieutenant’s Logbooks from HMS Pallas.
39
NMM: PJ/JC Vol. 1, National Maritime Museum Warship History Continuation Sheet microfilm.
40
NMM: PJ/JC Vol. 1, National Maritime Museum Warship History Continuation Sheet microfilm.
41
TNA: PRO ADM 51/667, Lieutenant’s Logbooks from HMS Pallas.
42
Clark (ed.), Naval Documents, Vol. 3, 906.
43
TNA: PRO ADM 51/667, Lieutenant’s Logbooks from HMS Pallas. No specifics are given regarding
the nature of the repair undertaken while in dry dock.
11
134
44
Clark (ed.), Naval Documents, Vol. 3, 363-6.
Clark (ed.), Naval Documents, Vol. 3, 540, 544, Vol. 6, 76, Vol. 8, 598 and TNA: PRO ADM 1/1611,
Admiralty Correspondence.
46
Clark (ed.), Naval Documents, Vol. 6, 867.
47
Clark (ed.), Naval Documents, Vol. 7, 734, 736, 750-1, 756, 761.
48
TNA: PRO ADM 51/667, Lieutenant’s Logbooks from HMS Pallas.
49
PJ/JC Vol. 1, NMM Warship History Continuation Sheet microfilm.
50
TNA: PRO ADM 51/667, Lieutenant’s Logbooks from HMS Pallas.
51
TNA: PRO ADM 51/667, Lieutenant’s Logbooks from HMS Pallas.
52
Clark (ed.), Naval Documents, Vol. 10, 535.
53
TNA: PRO ADM 51/667, Lieutenant’s Logbooks from HMS Pallas. This is where the logbook TNA:
PRO ADM 51/667 ends.
54
NMM: PJ/JC Vol. 1, National Maritime Museum Warship History Continuation Sheet microfilm.
55
NMM: PJ/JC Vol. 1, National Maritime Museum Warship History Continuation Sheet microfilm. Pallas
was coppered between October 1778 and May 1779. However January to April 1778 is the only period
noted in the logbooks that she was brought into dry dock. TNA: PRO ADM 51/668, Lieutenant’s
Logbooks from HMS Pallas. It is reasonable to assume that the new logbook coincides with the change of
command. Captain King does not offer much in the way of useful remarks to the lieutenant’s logbook.
Unless otherwise noted following information is extracted from TNA: PRO ADM 51/668 Lieutenant’s
Logbooks from HMS Pallas.
56
NMM: PJ/JC Vol. 1, National Maritime Museum Warship History Continuation Sheet microfilm.
57
TNA: PRO ADM 51/668, Lieutenant’s Logbooks from HMS Pallas. NMM: PJ/JC Vol. 1, National
Maritime Museum Warship History Continuation Sheet microfilm. It is possible that Pallas was coppered
during this overhaul but there is no suggestion that she was brought into dry dock.
58
NMM: PJ/JC Vol. 1, National Maritime Museum Warship History Continuation Sheet microfilm. I have
found references to an action at Concale around this date but so far this is the only reference that I have
found suggesting Pallas’ involvement.
59
TNA: PRO ADM 51/668, Lieutenant’s Logbooks from HMS Pallas. It is reasonable to assume that the
word ship here refers to the rig type, i.e. a full-rigged, three mast ship No name is given.
60
NMM: PJ/JC Vol. 1, National Maritime Museum Warship History Continuation Sheet microfilm.
Neither the logbooks nor the National Maritime Museum Warship Continuation Sheet for Pallas make any
note of a new captain being assigned during this period. However The Continuation sheet does show
Captain Spry leaving Pallas before the end of 1781.
61
Rodney, Letter-Books and Order-Book, 683, 692, 695, 711, 745.
62
Ibid., 811.
63
Ibid., 816-17, 25.
64
Breen, “Foundering of the HMS Ramilles,” 190 and Rodney, Letter-Books and Order-Book, 834, 840.
65
Rodger, Command of the Ocean, 510 Plate 22b.
66
TNA: PRO ADM 51/668, Lieutenant’s Logbooks from HMS Pallas.
67
TNA: PRO ADM 1/5322, Capt Parker’s report to the Admiralty informing of the loss of Pallas.
45
135
CHAPTER VII
ARCHAEOLOGY OF PALLAS SITE
The remains of Pallas lay in three meters of water within Calheta harbor, forgotten but
not officially lost. The site, south and west of the existing harbor, is little affected by modern
commercial boat traffic and has, for the most part, been sheltered from the worst of Atlantic
storms. Because Royal Navy records confirmed that the crew made an effort to remove what
remained of the valuable fixtures before destroying her, no subsequent effort was made to
salvage the remains of Pallas. 1 There is little evidence of previous disturbance or removal of
material culture, but a certain amount of salvage by local residents probably took place after
1783, and scuba divers may have collected souvenirs in recent decades.
The first officially-sanctioned investigation of the site took place in the summer of 1998
as part of a general shipwreck survey of the Azores sponsored by the Institute of Nautical
Archaeology (INA), the Azorean Government’s Direcção Regional da Cultura (DRC) and the
Centro Nacional de Arqueologia Náutica e Subaquática (CNANS) in Lisbon. The Azorean
government was planning improvements of Calheta harbor and had contracted for a formal
archaeological survey of the harbor to be carried out by the DRC and INA.
The primary investigators, Catarina Garcia, Paulo Monteiro and Kevin Crisman carried
out a cursory survey, photographing the site, drawing and mapping visible debris (Fig. 44), and
collecting samples. Visible remains at the site include two iron cannon (Figs. 44, 45 and 46), one
row of rectangular iron ingots, and a single massive concretion of iron ballast and shot
protruding above the sand and cobble bottom (Figs. 44 and 45).
A subsequent more thorough investigation carried out by Garcia and Monteiro involved
digging several test trenches that exposed a variety of copper nails, tacks, and possible wedge
136
from a forelock bolt (Fig. 48), fragments of copper sheathing (Fig. 49), lead sounding weights
(Figs. 50 and 51), an assortment of lead and iron shot (Fig. 52 and 53), four types of pottery
fragments (Fig. 54), and a variety of copper coins (Fig. 55). 2
Pallas’ logbooks for her last few months of service have unfortunately gone missing.
However, Royal Navy records provide a clear account of the final voyage of Pallas including her
destruction in Calheta harbor. 3 This is further corroborated by the Navy records progress sheets.
Furthermore, Azorean historical accounts record that the local populace objected to having
Pallas burn in close proximity to their town. 4
There is little doubt that the 6-pound guns found at the site are from Pallas. They have
the unmistakable appearance of British-manufactured guns from the mid-18th century and are in
fact examples of the 6-pound ‘shorts,’ designed specifically for Royal Navy frigates, and
introduced in August 1757. 5 The copper sheathing and iron ballast ingots can also be considered
diagnostic and strongly suggest the remains of an 18th-century Royal Navy warship. The iron
shot are also convincing evidence of the presence of a warship. 6 Measuring about 4 cm. in
diameter, they could be grape shot but are more likely shot for the ½-pound swivel guns
mounted along the rails of 18th-century English frigates. Unfortunately copper nails, spikes, and
drift pins were common throughout most 18th-century shipbuilding traditions and therefore these
finds cannot be considered diagnostic artifacts on their own. Nevertheless, it is possible that
future comparative analysis may establish some or all as the unique product of the 18th-century
Royal Navy. It is equally likely that analysis of the pottery fragments and coins will confirm a
date consistent with the destruction of Pallas. However, they do not, by themselves, provide any
conclusive data and could easily be coincidental intrusions. The same is true for the lead musket
balls. Standing alone they cannot be considered diagnostic. Almost all maritime vessels carried
(and still carry) some small arms. However, taken in context with the other artifacts found at the
137
site, they do reinforce the identification of the wreck. Given this collective body of evidence,
both archaeological and historical, there is little doubt that the site has been properly identified as
that of the frigate HMS Pallas of 1757 -1783.
It is possible that more remains to be discovered. However, given the hard, compacted
nature of the bottom it is unlikely. As already stated, the two guns were probably the only two
remaining aboard Pallas upon her arrival at São Jorge. A cursory investigation of the site yielded
sufficient data to conclusively identify the site and yielded both quantity and variety of artifacts
scattered around the site but failed to locate any structural remains of Pallas’ hull. While it is
possible that the large concretion of iron ballast and shot may conceal some surviving portions of
the wooden hull, the archaeological significance of any concealed remains is questionable. While
the Pallas site is worthy of further investigation, it does not represent a period or shipbuilding
tradition previously unrecorded. The knowledge gained could be considerable but costly, and
would more likely serve to fill in small details currently missing from the historical record. The
expense and feasibility of lifting, dismantling, or otherwise circumventing the large concretion
weigh heavily against the potentially meager returns of future excavation. However, further
thorough and systematic survey of the site may prove otherwise.
Notes
1
TNA: PRO ADM 1/5322, Courts Martial account accounts and Captain Parker’s letter to the Admiralty
reporting the lost of Pallas.
2
Garcia and Monteiro, Intervenção Arquelógica Subaquática, 14-22.
3
NMM: PJ/JC Vol. 1, Warship History Continuation Sheet microfilm, TNA: PRO ADM 1/5322, Courts
Martial account accounts and Captain Parker’s letter to the Admiralty reporting the lost of Pallas, and
TNA: PRO ADM 2/1116, Orders from the Admiralty to Captain Jonathan Faulknor HMS Princess Royal,
to convene Captain Parker’s courts martial.
4
Crisman, “Looking for Ships,” 7.
5
Caruana, History of British Sea Ordnance, Vol. 2, 152, Gardiner, First Frigates, 81, and Lavery,
Construction and Fitting, 101.
6
Knight, “Copper Sheathing,”, 299-309, Steffy, 1981, 131, and Lavery, Construction and Fitting, 62-3.
138
CHAPTER VIII
CONCLUSIONS
A carefully researched graphic reconstruction of the hull and fittings of HMS Pallas has
been produced using the surviving Admiralty drafts for Pallas as a starting point and refining
them with the 1745 Establishment lists, extant contemporary literary sources, period models and
artwork, and, where required, modern literary sources. The most significant deficiency would be
the absence of exact information regarding the size and types of fasteners used. Nevertheless,
data regarding most of the large, and most important, fastenings were established or can be
reasonably deduced. Unfortunately, yard records were not readily accessible during this study. It
is highly probable that records from Deptford, or even other yards, would contribute
significantly to the reconstruction.
While it was possible to recreate a reasonably accurate representation of the spar plan
and rigging plan for Pallas, a considerable amount of detail is still lacking. Some of this
deficiency may be addressed by further examination of contemporary representations. However,
an exact reproduction of the rigging of a specific vessel is a virtual impossibility. Captains
frequently altered the rigs of their ships, sometimes on a daily basis, to suit their individual
preference and sailing styles. They were often unable to exactly reproduce lost or damaged
rigging elements due to shortages of materials, and were compelled to resort to altering their
ship’s rig to make do with what they had. The most that can be hoped for is to recreate, as
accurately as possible, the vessel’s ideal rigging plan based on Royal Navy standards and
accepted practices of the period.
Examination of life aboard a Royal Navy warship gives personality to the ship and,
taken in the intimate context of a specific ship, confers a more dynamic feel for the day-to-day
139
existence of the 18th-century Royal Navy sailor. While the service history provided by the
logbooks is often sterile and repetitive, it does offer occasional glimpses of historical events
from a unique perspective, and further contributes to the personality of the ship. Finally, Gabriel
Bray’s watercolors provide a powerful visual catalyst, transporting the viewer directly to the
decks of Pallas.
Most Royal Navy historians consider the Pallas class a failure. 1 This is not based on any
deficiency in capability or performance; rather it is an issue of economy and Navy Board
conservatism of the time. The Pallas class frigates successfully fulfilled the requirements set out
for their development. They were fast, seaworthy and maneuverable. They were able to remain
at sea and operate independently for long periods, and their durability was especially apparent in
their longevity. 2 They were capable of projecting strategic influence on a global scale, policing
Britain’s widespread colonial possessions and suppressing piracy. At war they proved highly
successful as commerce raiders and equally successful at protecting British maritime commerce
from enemy commerce raiders and privateers. They proved effective at blockading smaller
enemy ports to stop important war material from reaching Britain’s enemies. They efficiently
gathered valuable intelligence often enabling timely deployment of the battle fleet or other
resources.
Along with the contemporary 32’s, they served as the prototype for all subsequent Royal
Navy frigates. Furthermore, there is credible evidence that early frigates of the Continental Navy
were influenced by the Pallas design. 3 They served as platforms on which numerous
improvements were tested and eventually accepted for general use within the Royal Navy.
During the course of her career, Pallas was retrofitted with copper sheathing, a mizzen driver
boom, and additional ventilation scuttles. 4
140
In some ways, the 36’s were unnecessarily overbuilt. They possessed no significant
advantage over the 32-gun Southampton-class, Richmond-class and Niger-class frigates—the
four additional 6-pound guns carried by the 36’s made no significant contribution to broadside
firepower and served only to make the ship unnecessarily larger and increase topside weight.
The Southamptons, Richmonds and Nigers were only marginally smaller but were significantly
lighter (670 rather than 720 tons), required less wood to construct and were, at least theoretically,
better sailors. Royal Navy performance evaluations state that the Pallas class frigates were faster
than their 32-gun counterparts, otherwise they were comparable to the Southamptons, not
outstandingly weatherly, but very maneuverable. 5 The logbooks of eleven different captains,
over the course of Pallas’ 25-year history, record no negative comment regarding her sailing
quality, performance, or capacity.
Ultimately the conservative minded and cost-conscious Navy Board found its 32-gun
frigates to be a more cost effective solution. They served the same purpose as the 36’s and were
cheaper to produce and maintain. It was not until the introduction of the carronade to the Royal
Navy’s arsenal towards the end of the century that 36-gun frigates were reintroduced.
Notes
1
Gardiner, “First English Frigates,” 168.
Gardiner, First Frigates, 28 Brilliant was sold in 1776 after 19 years of service, Pallas was beached as
unserviceable in 1783 after 25 years of service and Venus was sold in 1828 after an incredible 72 years of
service.
3
Clark (ed.), Naval Documents, Vol. 3, 1115, Vol. 4, 12 and Fowler, Rebels Under Sail, 220-1, 231. The
correspondence between Josiah Bartlett of The Marine Committee and shipbuilder John Langdon
(February 3rd and 19th, 1776) strongly suggest that the 32-gun Raleigh was at the very least loosely based
on the drafts of Pallas.
4
TNA: PRO ADM 51/666, Gardiner, First Frigates, 77 and NMM: PJ/JC Vol. 1, National Maritime
Museum Warship History Continuation Sheet microfilm.
5
Gardiner, First Frigates, 98.
2
141
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149
APPENDIX A
FIGURES
Fig. 1. Frigate believed to be Pallas. Painted by Charles Brooking, 1759. From Brooking, 8
Fig. 2. Frigate entering Portsmouth. Painted by Thomas Mitchell, 1780. From Brooking, 100
150
Fig. 3. Ship’s lines for frigate HMS Pallas. Based on NMM: ADM 2042 - Admiralty drawings for Pallas’ sister ship HMS Brilliant
Fig. 4. Keel and keelson assembly detail. From White, 31
151
152
Fig. 5. Interior profile plan for frigate HMS Pallas. Based on NMM: ADM 2196 Admiralty drawings HMS Pallas
153
Fig. 6. Various types of scarfs used in construction of Pallas.
154
Fig. 7. Stem assembly detail. After Goodwin, 37
Fig. 8. Bow construction detail of frigate Pandora. From McKay and Coleman, 30
155
Fig. 9. Stern construction detail of frigate Pandora. From McKay and Coleman, 31
Fig.10. Stem boxing detail. From White, 31
156
Fig. 11. Interior construction detail for frigate HMS Pallas.
© 2005 by P. Erik Flynn. All Rights Reserved
157
Fig. 12. Frame assembly detail. From White, 39
Fig. 13. Hawse pieces detail. From Ollivier, 57
Fig. 14. Midship section detail frigate HMS Pallas.
© 2005 by P. Erik Flynn. All Rights Reserved
158
Fig. 15. Spirketting and quickwork detail. From Ollivier, 57
159
160
Fig. 16. Gun deck construction detail for frigate HMS Pallas.
© 2005 by P. Erik Flynn. All Rights Reserved
161
Fig. 17. Lower deck construction detail for frigate HMS Pallas.
© 2005 by P. Erik Flynn. All Rights Reserved
162
Fig. 18. Fore and aft orlop construction detail for frigate HMS Pallas.
© 2005 by P. Erik Flynn. All Rights Reserved
163
Fig. 19. Quarterdeck and forecastle construction detail for frigate HMS Pallas.
© 2005 by P. Erik Flynn. All Rights Reserved
Fig. 20. Detail of capstan. Based on ADM 2196 Admiralty drawings HMS Pallas
164
Fig. 21. Wheel and tiller detail. From White, 112
165
166
Fig. 22. Contemporary engraving of gun founding process. From Diderot, 1123
167
Fig. 23. Gun carriage. From Millan, Plate V.
Fig. 24. Detail of gun tackle and operation from the late 18th century. From Falconer, 203,
Plate VII
168
Fig. 25. Mid 18th-century chain-pump detail. From Falconer,.217, Plate VI
Fig. 26. Overhead view of chain-pump, Lavery, 1987, 71
169
Fig. 27. Contemporary engraving of anchor making process. From Diderot, 1683
170
Fig. 28. Iron stove from HMS Dorsetshire,1757. From Lavery, 1987, 197
Fig. 29. Copper sheathing on hull of Pandora. From McKay and Coleman, 26-7
171
172
Fig. 30. Spar plan for frigate HMS Pallas.
© 2005 by P. Erik Flynn. All Rights Reserved
173
Fig. 31. Rigging plan detail for frigate HMS Pallas.
© 2005 by P. Erik Flynn. All Rights Reserved
174
Fig. 32. Draft of 1745 Establishment, 44-gun ship showing spar details. From Lees, 37, Plate 21
Fig. 33. Watercolor of 50-gun ship HMS Lion showing rigging details. From Ollivier, 44
175
Fig. 34 The Isle of Man Action, 1760. Painted by Richard Wright. From Warner, 90
Fig.35. Two British frigates off the African coast. The one on the left is probably Pallas.
Watercolor by Lt. Gabriel Bray, From Spavens, 91
176
Fig. 36. Fishing from the anchor on board Pallas
in Senegal Road. Watercolor by Lt. Gabriel
Bray, From Spavens, 74
Fig. 37. Sail-maker ticketing hammocks on
board Pallas. Watercolor by Lt. Gabriel Bray,
From Spavens, 123
Fig. 38. Wardroom leisure on board Pallas.
Watercolor by Lt. Gabriel Bray, From Spavens,
74
Fig.39. Marines mess on board Pallas.
Watercolor by Lt. Gabriel Bray, From Spavens,
107
Fig 40. Lower deck on board Pallas (note pump
crank handle) Watercolor by Lt. Gabriel Bray,
From Spavens, 123
177
Fig. 41. Gun deck onboard Pallas. Watercolor by
Lt. Gabriel Bray, From Spavens, 91
Fig. 43. Fishing off a gun onboard Pallas.
Watercolor by Lt. Gabriel Bray, From W.
Spavens, 90
Fig. 42. Marine sentinel on board Pallas.
Watercolor by Lt. Gabriel Bray, From Spavens,
75
Fig. 44. A Homeward-bound West India convoy September 1782 By Robert Dodd, with the merchantman Lady Juliana in the foreground,
in the tow of the frigate Pallas. From Rodger, Command of the Ocean, 510 Plate 22b.
178
179
Fig. 45. Site plan of Pallas Wreck, Calheta harbor, São Jorge, Azores.
Courtesy of Kevin Crisman
Fig. 46. One of two concreted 6-pound cannon in situ at the site. Garcia and Monteiro p. XVIII
180
Fig. 47. Drawings of the 6-pound cannon found at the site. Courtesy of Kevin Crisman
Fig. 48. Concreted cast iron ingots from ballast. Garcia and Monteiro p. XIX
181
Fig. 49 Copper nails and a possible wedge from a forelock bolt found at the site. Garcia and
Monteiro p. XIII
Fig. 50 Copper sheathing found in test trench at the site. Garcia and Monteiro p. XIV
182
Fig. 51. Lead sounding weight (CAL/ 00-191) found at the site. Garcia and Monteiro p. XII
Fig. 52. Lead sounding weight (CAL/ 00-12) found at the site. Garcia and Monteiro p. XII
183
Fig. 53. Lead musket shot found at the site. Garcia and Monteiro p. XVI
Fig. 54. Iron shot found at the site. Garcia and Monteiro p. XVI
184
Fig. 55. Four types of pottery found in test trench at the site. Garcia and Monteiro p. X
Fig. 56. A variety of copper coins found at the site. Garcia and Monteiro p. XV
185
APPENDIX B
MAPS
Map 1. The Central Azores and the Island of Sao Jorge in the North Atlantic.
Courtesy of Dr. Kevin Crisman.
186
Map 2. British home waters and western approaches. (after National Geographic Atlas
of the world, p.53)
187
Map 3. Theatre of operations: July 1760 – Dec. 1763 and Dec. 1771 – Mar. 1773. (after National Geographic Atlas of the World, p.53)
187
188
Map 4. Theatre of operations: Jan. – Apr. 1775, Dec. 1775 – May 1776 and Mar. – June 1777.
(after National Geographic Atlas of the World, p.91)
189
Map 5. Theatre of operations: May – July 1775, June – Oct. 1776, July – Dec. 1777 and Aug. –
Jan. 1783. (after National Geographic Atlas of the World, p.17)
190
APPENDIX C
HMS PALLAS TIMELINE
Year
1757
Month &
Day
08/31
Coordinates
09/03
09/05
09/06
09/07
09/08
09/09-10
09/11-17
09/18
09/19-10/07
10/08
10/09-11
10/12
10/13
10/14
10/15
10/17
10/19
10/22
10/29
10/30
10/31
11/02
11/03
11/04
49°28 x 00°08
11/08
11/10
46°38 x 4°44
46°38 x 5°12
11/11-28
47°04 x 3°58
48°36 x 3°20
46°50 x 4°30
48°57 x 5°58
11/29
Activity
moved hull of HMS Pallas from Wells shipbuilding firm at
Deptford into Thames River 1,2
lashed alongside HMS Gibraltar @ Deptford; Captain
Archibald Cleveland took possession at Deptford
took on 35 tons of iron ballast and 35 tons of shingle ballast;
trimmed
began rigging ship and clearing holds
another 24 tons of shingle ballast
took on water, officers’ stores
loaded provisions of all species including fresh beef
continued running rigging, provisioning
received 47 pressed men; read Articles of War to ship’s
company
rigging and final fitting out 3
sailed with HMS Shannon to Long Reaches
took on guns, gunner’s stores
took on powder
sailed with Shannon to Gravesend; sealed the guns
sailed to Nore; saluted Commodore Grey with 13 guns
men paid; new men received bounties and advances
exercised great guns and small arms
read Articles of War
fired 17-gun salute for King’s coronation
sailed with Shannon and HMS Hussar
lost sight of Shannon; brought to several Dutch vessels
rejoined Shannon
with Shannon joined company with HMS Medway, HMS
Dolphin, and HMS Unicorn
spotted sail near Le Havre; Pallas gave chase through the
night
proved to be a French privateer; put a prize crew aboard to
bring her in; lost sight of the fleet
rejoined Medway, Unicorn and Dolphin
joined Edward Hawke in HMS Ramillies ,and Vice Admiral
Boscawen on HMS Royal George with 18 sail under their
command
patrolled with fleet
generally poor weather; no notable encounters
joined by HMS Southampton
191
Year
1757
continued
Month &
Day
12/08
48°12 x 5°05
12/11
12/14
49°45 x 1°38
Coordinates
12/15
12/16
12/21
12/22-27
12/28-30
12/31
1758
01/01
01/02
01/03
01/05
01/10
01/12
01/15
01/17
01/21
01/22
49º26 x 1º17w
46º23 x 11º40
45º53 x 12º13
01/24-25
44º35 x 10º59
01/26
01/29
44º11 x 9º07
45º32 x 8º58
01/30
45º58 x 8º43
01/31
02/01
47º05 x 7º43
47º29 x 7º48
02/02
02/03
02/04
02/05
02/06
47º11 x 8º07
47º37 x 7º44
47º25 x 6º23
47º22 x 5º50
02/07
02/10
02/11
02/12
48º45 x 4º42
49º16 x 2º10
49º30 x 1º42
49º42 x 1º21
Activity
Medway and Southampton part company taking nine of the
sail with them
read Articles of War to ship’s company
fired on an unknown vessel believed to be French; proved to
be an English privateer
remainder of fleet begin working into Spithead to ride out
weather
anchored at Spithead
pilot came aboard to bring her into Portsmouth
overhauling blocks and rigging, replaced main and mizzen
shrouds, installed new bowsprit gammoning; removed iron
ballast to adjust trim, and re-caulked hull
reloaded ballast and loaded provisions
re-provisioning completed
completed rigging; masts scraped and payed with varnish of
pine
guns on board
gunner’s stores and powder
quartering the ship’s company
exercised great guns and small arms; fresh beef
pilot aboard to move Pallas out of harbor; Bembridge Point
sailed
joined company with HMS Eagle.
joined company with HMS Torbay
chased and brought to Danish ship bound from Cadiz to
Copenhagen and an English ship bound from Newcastle to
New York
chased and fired on ship which hoisted English colors; snow
bound from Falmouth to New York with mail
four more sail sighted; proved to be English
chased sail; proved to be the British Willshire privateer out
of Bristol
gave chase; proved to be a Portuguese brig from Lisbon;
read Articles of War to ship’s company
gave chase; Spanish snow from Seville bound for Dublin
pursued by three sail–fired at foremost; proved to be
privateer Willshire, HMS Achilles and the third Veteran
privateer of London
exercised great guns and small arms
Veteran privateer in sight
Veteran privateer in sight
Veteran privateer in sight
saw two sails; one proved be Veteran privateer, the other a
Dutch bound from Lisbon to Rotterdam
rejoined Eagle
saw two sail – gave chase; HMS Lizard and Speedwell sloop
saw sail, gave chase
turned out to be Eagle.
192
Year
1758
continued
Month &
Day
02/14
Coordinates
anchored Plymouth Sound
02/15-19
general maintenance, tarring shrouds, scraping and paying
lower masts
removed guns and powder; found foremast sprung under the
upper wedges and employed unrigging the foremast
removed foremast
officers’ stores brought onboard
hauled into dock; caulkers employed in breaming ship’s
bottom; stores brought onboard
26 tons of shingle ballast brought on board
water brought on board
foremast re-installed and rigged
read Articles of War and punished several crew members
(crimes unknown)
guns, powder and gunners stores loaded; payed ship sides
sealed guns; read Articles of War
moved out of harbor and anchored with several other of HM
ships
came to sail in company with the HMS America; John Head
fell from mizzen yard and died of injuries
02/20
02/21
02/22
02/23
02/24
02/25
02/25-26
02/26
02/27-28
03/01
03/02
03/03
03/04
03/05
03/09
49º52 x 2º23
49º03 x 3º04
50º30 x 4º56
03/11
49º59 x 5º45
03/17
03/18
03/20
03/21
03/22
03/23
03/27
03/31
04/01
04/09
04/15
04/16
04/17
04/18
04/24
04/25
04/26
Activity
49º36 x 6º21
49º16 x 2º31
48-50º x 2-6º
49º17 x 3º46
49º14 x 1º50
49º41 x 0º10
fore topmast stay broke
chased Portuguese brig and snow; saw 8 sail; proved to be
the York with a convoy bound for America
encountered HMS Antelope with a convoy for the West
Indies
re-entered Plymouth sound
employed in fixing the lower rigging, unreaving the bad
running rigging, and reaving new
unrigged the fore and main topmasts
employed re-rigging fore and main topmasts
made sail
brought to and spoke with several Dutch vessels; saw 13 sail
to southwest and gave chase; turned out to be HMS
Greyhound with convoy from Lisbon
got on board a new driver boom
Land’s End; saw and chased French frigate in little or no
wind; Frenchman used oars to evade
chased ship−turned out to be Southampton
patrolled
brought to a Portuguese ship bound for Lisbon from England
spoke with Defiance privateer of Bristol
liberated a British ship taken by a French privateer
returned to anchor at Portsmouth
taken by pilot into harbor; yards and topmasts were struck
unrigging and overhauling blocks
main and mizzen mast found to be sprung
193
Year
1758
continued
Month &
Day
04/27
Coordinates
Activity
transported alongside the sheer hulk and masts were
removed
officers’ stores aboard
provisions aboard
new main and mizzen installed at sheer hulk
rigging and provisioning
guns and powder
ready for sailing−found foremast sprung under woolding
scraped and payed sides with varnish
Spithead general maintenance
05/03
05/04
05/08
05/10
05/11
05/12
05/13
05/14-06/01
June to October gap: Cherbourg raid September 1758 4
10/06
10/07
10/16
10/17-18
10/19-21
10/22
10/23
10/24
10/25
10/26
10/27
10/28
10/29-30
10/30
10/31
11/01
11/06
11/07-11
11/12
11/15
11/17
11/20
11/22
11/23
11/25
11/28
12/01-05
12/05
12/16
47º00 x 5º40
45º07 x 6º21
39º17 x 6º21
40º30 x 5º53
45º00 x 4º12
47º10 x 1º25
47º18 x 0º131º55
47°18 x 1°55
47º48 x 2º50
guns out
clearing and washing hold; major overhaul and replacement
of rigging?
carpenters and caulkers hard at work; 30 tons of shingle
ballast
sheer hulk for painters, removal of lower masts, a new best
bower cable
new lower mast and rigging
yards installed
painters, caulkers, and rigging
topmasts and top gallants
hauled into dock for blacking; stores on board
caulking and breaming
out of dock
topsail yards, beer and water
guns and gunners’ stores
boatswain’s and carpenter’s stores
powder
ship’s company received prize money
pilot came aboard to convey the ship out of Portsmouth
harbor
at anchor in Spithead
set sail in company withHMS Saltash
saw two sail and gave chase; found to be Dutch bound from
Lisbon to Holland
saw fleet; joined Torbay with 16 sails
parted company 5
saw sail – gave chase – lost contact [incorrect longitude]
read Articles of War to company
spoke with Dane bound from Lisbon to Hamburg
brought to several Dutch ships–
came into company with HMS Actæon, HMS Deptford and
one other (HMS Rochester?)
Actæon parted company
saw sail – gave chase; turned out to be English Bristol
privateer
194
Year
1758
continued
Month &
Day
12/17
47º51 x 1º57
12/19
48º40 x 4º30
12/20
48º31 x 4º45
12/21
12/22
12/23
12/24-25
48º08 x 4º59
47º37 x 5º38
46º40 x 5º56
45º48 x 6º42 to
44º52 x 6º56
45º00 x 6º06
12/28
12/30-31
1759
Coordinates
45º20 x 2º28 to
45º30 x 3º41
01/01-09
01/10
01/10-16
01/17
01/18-19
01/20
01/22-23
01/24
01/25-27
01/28
01/29
01/30
02/01
02/02
02/03-05
02/08
02/09
02/10
02/11-13
02/14
02/16
02/18
49º30 x 00º20
02/20
02/21
02/22
46º36 x 06º10
45º40 x 7º35
45º11 x 9º17
02/24
45º18 x 11º53
Activity
saw sail – gave chase; turned out to be Danish dogger from
Petersburg for Lisbon
lost contact with Deptford and Rochester; carpenters
employed repairing bumpkin
saw sails – gave chase; turned out to be Rochester and
unknown privateer
spoke with HMS Essex and HMS Windsor
remained in company with Essex, Windsor and Rochester
chased sail; Dane from Norway for Lisbon
chased and brought to a Dutch East Indiaman
chased and brought to ship; turned out to be British
privateer; lost contact with Essex, Windsor and Rochester
chased and brought to Danish ketch
in Spithead; general maintenance
fresh beef taken aboard
continue general maintenance
pilot moved Pallas into Portsmouth harbor
cleared holds – guns removed
blacking the yards
caulking and paying masts
carpenter’s and boatswain’s stores taken aboard
rigging, maintenance, and fitting for sea
guns loaded
scraped and payed lower masts; finished provisioning for 3
months
powder loaded
exit harbor anchor at Spithead; joined with large fleet there
under Admiral Holmes; mostly transports and Indiamen
scraping and paying sides
general maintenance
exercised great guns
took on beer
read Articles of War and punished sailor for neglect of duty
general maintenance
set sail in company with HMS Chichester, HMS Chatham,
HMS Faulkland, and HMS Boreas with East India convoy
Chatham and Boreas chased Spaniard Bilboa for Amsterdam
and spoke with same
saw sail, Boreas chased; turned out to be Lizard in company
of 21 sail convoy
chased and brought to Hassa privateer of London
parted company with ship bound for Guinea
Pallas and Chatham chased and brought to a Spaniard from
‘Carachis’ to St. Sebastian’s
Faulkland took command of convoy and parted company;
Chichester and Chatham
195
Year
1759
continued
Month &
Day
02/27
Coordinates
47º09 x 09º44
Activity
spoke with two vessels that had been attacked by French
privateers at 49º20 and proceeded there with Boreas
03/01-04
49º31 x 09º09
Patrolled; no finds
chased sail turned out to be Dane from St. Cruz bound for
Copenhagen
03/12
met up with Chichester and Chatham; main mast found to be
sprung
03/13
carpenter from Boreas came aboard to assist woolding the
mast
03/14
parted company with Boreas
03/16
reached Spithead and anchored
03/17
taken into Portsmouth harbor by pilot
03/18
unrigging ship
03/19-20
removed guns and powder, clearing hold, water casks put
ashore; carpenters and caulkers aboard
03/21-25
new mainmast installed; overhauled rigging
03/26
officers’ stores aboard
03/27-30
provisioning
03/31
guns aboard
04/01
powder aboard; moved to anchor at Spithead
04/03
fresh beef 6
04/04
set sail with Essex, Jamaica sloop; anchored at Needle Point
04/05
joined by Chatham
04/07
47º49 x 1º03
saw sail – gave chase – fired guns
04/08
47º02 x 0º48
proved to be HMS Juno
04/09
45º46 x 1º34
chased sail – Dutch dogger from Calais for Rochfort
04/10
sighted 20 sail – Dutch convoy
04/13
46º10 x 1º34
chased sail − Spaniard from Bristol for Bordeaux
04/15
45º33 x 0º22
chased sail; turned out to be Jamaican ship taken by French;
liberated; prize
04/17
45º34 x 5º24
parted company with Jamaica sloop
04/22
45º54 x 7º14
chased sail − packet from Falmouth
04/26
Essex and Chatham bore aft to Plymouth with prize; Pallas
made for Portsmouth
04/29 to
Spithead and Portsmouth general maintenance; assembled
05/21
fleet including HMS Nottingham, HMS Hercules, Chatham,
HMS Venus, Essex and HMS Minerva
In early June of 1759, Captain Archibald Cleveland departed and Captain Michael Clements
took command of HMS Pallas. 7 Clements would remain captain until Pallas was paid off in
January 1764. 8
06/18
sailed from Spithead
06/23 to
patrolled channel coast of France near Brest in company of
07/04
Rochester and a cutter
07/05
fired on French ships in Brest harbor and shore batteries at
St. Matthews Convent
07/06-16
harried French at St. Matthews and in Brest harbor
07/18
Plymouth Sound; heeled and scrubbed
07/19-21
provisioned
07/22-27
general maintenance
196
Year
1759
continued
Month &
Day
07/28
Coordinates
Activity
sailed in company with HMS Hero, Southampton, Venus,
HMS Sapphire; blockaded French ports of Brest and Le
Havre
Logbook gap from July 28 to October 3, 1759
10/03
10/04
10/05
10/06
10/07
10/08-11
10/13
10/14
10/15-18
10/19
10/20
10/21-28
47º16 x 00º38
10/29
10/30
10/31
11/02
11/03
11/04-13
11/14
Logbook gap 11/15 to end of 1759
1760
01/05
01/07
01/08
01/09
01/10-19
01/20
01/21
01/22
01/23
01/24-29
01/30
02/01
02/07
02/14
02/16
02/18
02/19-24
02/25
49º16 x 7º15
47º51 x 15º26
50º48 x 16º59
50º55 x 15º6
Plymouth Sound
provisioning
moved to sheer hulk to remove sprung bowsprit; caulkers
came aboard to caulk ship
clearing hold; overhauling rigging
new bowsprit installed; new gammoning; provisioning for 3
months
ballast, water and beer
company received 6 months pay
moved out into Plymouth sound
scraping, paying and general maintenance
set sail
saw two Dutch vessels; spoke with one
patrol French channel coast; Quiberon Bay, Belle Isle, Isle of
Groa; 27th came to sail with Chatham
met with Sapphire and HMS Vengeance and parted company
continued patrol; met Venus, Swallow sloop and a convoy of
victuallers
joined HMS Firm
joined company with HMS Maidstone
joined Chatham and Vengeance; parted company with all
Quiberon Bay−came to anchor; found here squadron and
several victuallers; gun maintenance
sailed in company with Firm, Southampton and Vengeance
returned to Plymouth Sound
pilot came to bring Pallas into harbor
replaced sprung main [top]mast; unloaded powder
unloaded and overhauled rigging
provisioning
took on guns
took on powder
scraped sides and lower masts and payed; tallowed topmasts
pilot aboard to take Pallas back into sound
general maintenance
sailed with HMS Brilliant
with Brilliant
with Brilliant
with Brilliant
with Brilliant
Kinsale Harbor
general maintenance
sailed with Brilliant and HMS Æolus
197
Year
1760
continued
Month &
Day
02/28
Coordinates
02/29
03/1-5
03/6-25
03/27
03/28
03/30
04/06
04/08
04/09
04/16
04/17 to
05/23
05/24
05/25
05/28 to
06/17
06/18
06/21
47º20 x 6º04
06/22
45º49 x 6º56
06/23
45º49 x 7º25
06/24
45º44 x 6º53
06/25
44º16 x 8º11
06/26
44º30 x 7º58
06/27
45º08 x 8º42
06/28
44º06 x 8º47
06/29
44º40 x 9º41
06/30
44º30 x 10º21
07/01
42º47 x 10º6
07/03
37º59 x 9º59
07/04
36º24 x 8º27
07/06
07/07-11
07/12-17
07/19-20
0724
37º26 x 00º14
07/25
37º35 x 00º14
07/29
08/07
38º50 x 10º15e
08/10
36º50 x 13º45e
08/11
Logbook gap August to October 10
Activity
encountered 3 strange ships and gave chase; proved to be
Fench frigates Marshal Bell Isle 44, Lablond 36 and
Terpsichor 24 9 Pallas—sails and rigging damaged, shot
through mainmast, best bower shot away
three ships were taken to Ramsay Bay
prisoners were put ashore and temporary repairs were made
Pallas, Brilliant, Æolus, Weasel sloop and the three prizes
sailed for Plymouth, stopping at Kinsale Harbor on the way
Pallas brought into Plymouth Harbor
guns and powder off loaded
bower cables replaced; rigging overhauled
mainmast replaced and re-rigged
company paid 6 months wages
returned to patrolling the French channel coast near St.
Matthews Convent, Brest
saw ship and gave chase; turned out to be French; exchanged
fire; French ship ran aground so violently that her masts fell;
Pallas wore and raked her to finish the job
in company of HMS Shrewsbury
returned to Plymouth Sound
clearing hold
major overhaul; new masts and bowsprit, re-rigged, scraping
and paying decks and sides and lower masts; provisioning
depart Plymouth
foremast sprung
rock of Lisbon
Cadiz
Gibraltar
repaired foremast and took on provisions
Europa Point patrol
near Gibraltar
Majorca
Malta
198
Year
1760
continued
Month &
Day
October
10/19-23
10/29
11/07
11/12
11/16-17
12/02
12/03-09
12/13
12/18
12/20-23
12/28
1761
01/02
01/04
01/24
01/28
01/29
01/30
01/31
02/04
02/11-13
02/19-22
Coordinates
Activity
patrolled western Mediterranean around Malta and Cape
Angelo with Dunkirk, Shannon, Shrewsbury, and HMS
Somerset
Messina Road; provisioning and general maintenance
36º22 x 15º23
Malta
36º43 x 13º27
Cape Carthage
38º59 x 7º50
patrolled between Sardinia and Majorca
at anchor in Tunis; provisions and general maintenance
exchanged broadsides with three French vessels
patrolled off Tunis
took a French prize off Cape Negro
35º36 x 11º08
moored in Malta; provisions and general maintenance
37º58 x 10º25
42º03 x 6º32
42º23x 5º37
41º42 x 5º00
41º59 x 4º58
moored in Leghorn [Legorno] Road
anchored in Tunis; provisions and general maintenance
anchored in Leghorn Road; provisions and out general
maintenance
03/20
anchor in Cagliari Bay; overhauling rigging and scrubbing
bottom
04/5-16
patrolled southeast approaches to Malta
04/22-29
moored in Milo Harbor; provisions and general maintenance
Logbook gap April 30 to June 6, 1761
06/06-19
moored in Malta; provisions, overhauling rigging; general
maintenance
Logbook gap June 19 to July 24, 1761
07/24 to
09/01
09 - 11/04
11/04-17
12/30 to
01/04
1762
01/10-12
01/19-26
02/09-15
03/16-04/30
moored in Leghorn; complete refit, caulking, careening and
breeming; new masts; painting, painting gun carriages, new
rigging; scraping and paying decks, masts and sides;
provisioning
patrolled between Sardinia and Majorca
moored in Messina; rigging adjustments; provisions and
general maintenance
moored in Tunis Bay; provisions and general maintenance
moored in Malta; provisions and general maintenance
Patrol
at anchor in Cagliari Bay; provisions and general
maintenance
in Gibraltar; overhaul; picking oakum before sheathing
199
Year
1762
continued
Month &
Day
05/08
Coordinates
41º44 x 5º50e
05/11
06/06-15
moored in Villefranche Bay; provisions and general
maintenance 11
mainly at anchor in Gibraltar
06/15-08/12
patrol between Cadiz and Trafalgar
08/13-22
moored in Gibraltar harbor; provisioning, rigging and
general maintenance
patrol
08/23
09/23
10/05
09/24-10/04
10/16-11/20
11/22-12/14
12/16-21
12/22-01/05
1763
Activity
01/06-02/16
02/17
02/26-03/14
03/14-17
03/18-04/08
04/09-28
04/29-05/01
05/02-06
05/07-09
05/10-13
05/14-22
05/23-25
05/26-06/11
07/01-05
07/06
08/10
08/11-28
08/29-30
09/01-11/02
11/03-05
11/06-21
11/22-12/02
12/03-08
12/09
35°39 x 1°49w
33°31 x 2°09
36°12 x 6°00
36°33 x 7°27
38°33 x 7°07
42°24 x 8°55
39°40 x 6°00
40°35 x 7°05
34-36° x 0-3°
mostly
36°x 0-1°
moored in Gibraltar Bay
On patrol
at anchor in Lagos Bay; provisions and general maintenance
patrol
moored in Gibraltar
sailed from Gibraltar with HMS Dunkirk, Chichester and
some merchant vessels bound for England
moored in Lisbon Harbor
returned to Gibraltar
moored in Gibraltar
moored in Cadiz
moored in Gibraltar
short cruise to Cagliari
Cagliari Bay
Cagliari to Genoa
moored in Genoa
Genoa to Leghorn Road
moored at Leghorn Road
patrolled around Gibraltar
moored at Gibraltar; carried out general maintenance
sailed from Gibraltar to Cadiz
moored in Cadiz harbor
sailed from Cadiz to Gibraltar
moored in Gibraltar; provisions and general maintenance
moved to Cadiz
moored in Cadiz
Moved to Lisbon
Moored in Lisbon; general maintenance
sailed from Lisbon
200
Year
1763
continued
Month &
Day
12/21
Coordinates
Activity
moored at Spithead
12/22-01/13
ship stripped
1764
01/14
crew paid off 12
1770
10/26-11/11
alongside Jetty Head working up for sea, taking on a new
crew, provisions, ballast, rigging; new Captain named
LaForey 13
moored in Portsmouth harbor; tops, yards and shrouds;
cleaning and trimming; blacking yards; carpenter, boatswain
and gunner stores; ballast and trim
read Articles of War to the ship’s company; ballast; heavy
cables and anchors; Clerk of the Cheque came aboard to
muster crew; provisions
11/12-26
11/26-12/19
1771
12/20-03/27
03/28-04/11
04/12-05/02
05/05
05/08
05/09
05/10
05/11
05/12
05/13
05/14
05/15
05/16
05/17
05/18
05/19
05/20-27
05/28
05/29
05/30
05/31
06/01
06/02
06/04
06/05
06/10
06/13
06/14
06/15
06/18-22
06/23
06/24
06/26-07/01
moored at Spithead
final working up, guns brought aboard 14
anchored at Spithead, Captain Watson assumes command 15
sailed for the Mediterranean
48º38 x 1º25w
48º22 x 2º13w
45º42 x 4º21w
43º47 x 5º14w
42º10 x 0º43w
40º58 x 0º55w
41º19 x 2º12w
40º55 x 2º19
40º39 x 0º12
40º20 x 0º20
37º54
36º33 x 1º41
[incorrect coordinates] 16
Minerva and HMS Pearl in company
Gibraltar at anchor
sailed on patrol with Minerva
36º40 x 0º51e
37º8 x 0º44e
36º50 x 2º22e
37º08 x 0º34
38º24 x 0º34
39º10
39º47 x 00º51
sailed still in company with Minerva
38º30 x 0º57e
39º09 x 2º17
38º23 x 2º37
36°9 x 2°39
36º28 x 5º59
moored in Malta harbor
sailed with Minerva
moored in Milo harbor
201
Year
1771
continued
Month &
Day
07/07-11/29
11/30
12/02
12/03
12/04
12/05
12/06
12/07
12/08
12/09-18
12/19
12/20
12/21
12/22
12/23
12/24
12/25
12/26
12/27
12/28
12/29
12/30
12/31
1772
01/01-08
01/09
01/10
01/13
01/14-15
01/16
01/17
01/18
01/19
01/20-28
01/29
01/30
01/31
02/01
02/02
02/04
02/05
02/06
02/07
02/08
02/09
02/10-04/04
Coordinates
Activity
moored in Smyrna harbor; general maintenance
36º20
sailed
Moses Ward, sailmaker, runs gauntlet for sin of attempted
sodomy
35º43
35º15 x 0º55w[?]
36º0
36º24 x 2º22w[?]
36º16 x 5º42w[?]
36º28 x 6º45w[?]
moored in Malta harbor
36º39 x 0º38e
36º36 x 1º17e
36º27 x 0º27e
36º46
36º44
36º35
36º53
37º23
38º28 x 0º45w[?]
37º49 x 2º21w[?]
37º53 x 3º22w[?]
37º30
37º01
37º07
37º42
39º53
moored in Bona Bay
sailed
at anchor off Cape Mola
39º18 x 0º30e
39º21 x 0º48e
39º18
39º21
moored in Mahon harbor overhauling rigging
38º48 x 0º37e
38º43 x 2º29e
38º24 x 0º30e
38º14 x 0º23e
37º51 x 0º04e
36º57
36º54
37º06
36º26
Europa Point
anchored in squall; obliged to cut away small bower
moored in Gibraltar harbor; general maintenance; scraping,
paying, painting, etc. 17
202
Year
1772
continued
Month &
Day
04/06
04/07
04/12-29
04/30-31
05/01-06
05/08
05/25-06/24
06/25-07/01
Coordinates
Activity
shock thought to be rock turned out to be an earthquake
37°07 x 6°14w
moored in Tagus River (Lisbon)
Gibraltar
moored in Gibraltar
36°47 x 00°55e
37°06-37°10 x
1°58-0°45e
07/02-07/21
moored in Mahon Harbor
short patrol
Mahon Harbor
07/22-28
07/29-09/03
09/04-16
short patrol
Mahon Harbor
patrol around Cape Mola, cape Paul, Cape Palus, Malaga,
Gibraltar, Ceuta Point
09/17
moored in Gibraltar
Logbook gap September 18, 1772 through December 8, 1772
1773
1774
12/09/1772
to
03/16/1773
03/16-25
03/26
03/27
03/28
03/29
03/30
03/31
04/01-11
alongside the wharf at Gibraltar 18
36º26 x 2º54w
36º26 x 3º30w
36º26 x 4º29w
36º51 x 5º44
36º49 x 5º46w
38º52 x 6º01w
39°57 x 7°02w
39°57 x 7°02w
40°43 x 7°1
41°30 x 5°45w
43°49 x 4°46w
45°31 x 3°01w
47°12 x 1°23
49°24 x 0°14e
49°39 x 1°14
50°29
04/12-23
10/05-11/12
return trip to England; recorded following daily coordinates
moored in Spithead
moored in Portsmouth harbor working up; new captain,
Honorable William Cornwallis took command effective
September 1774 19
anchored at Spithead
11/13- 12/11
12/12
12/20
12/21
moved into Gibraltar Bay
sailed from Gibraltar on patrol
sailed in company with Weasel sloop
48º42 x 2º53w
46º10 x 4º52w
203
Year
1774
continued
1775
Month &
Day
12/22
43º11 x 7º06w
12/23
12/24
12/25
12/26
12/27
12/28
12/29
12/30
12/31
40º57 x 8º36w
39º14 x 9º36w
37º40 x 10º45w
35º16 x 11º15w
33º11 x 11º43w
32º35
30º55 x 00º24e
29º54 x 00º16w
29º16 x 00º49w
01/01
01/02
01/03
01/04
01/05
01/06-17
28º57 x 0º27w
28º38
29º19
28º53
01/18
01/19
01/20
01/21
01/22
01/23
28º06
27º07
25º56 x 0º18e
24°18 x 0°01e
21°38 x 0°41w
18°49 x 0°27w
01/24
01/25
01/26
01/27
01/28-29
01/30
01/31
16°47
15°58
02/01
02/02
13°39n
13°29n
Coordinates
island of Palma
16°00
15°29
02/03
02/04-09
02/10
02/11
02/12
02/13
02/14
02/15
02/16
Activity
in Santa Cruz Bay, Tenerife; provisions and general
maintenance
sailed in company with Weasel sloop
running down Senegal Bar; spoke to sloop from Dominica
anchored off Senegal Bar
in company with Weasel sloop
anchored off Senegal Fort
anchored off Senegal Bar
sent 25 half barrels of powder ashore for use by [Senegal]
fort at the request of the governor
anchored in Gambia River; fired on and brought to French
sloop
fired on and brought to French sloop and cutter
in Gambia River off James Island; delivered 15 half barrels
of powder to Fort James
ran down river
12°17 x 0°55w
10°12 x 0°52w
9°3 x 0°27e
8°47 x 1°25e
8°44 x 2°10e
8°31
204
Year
1775
continued
Month &
Day
02/17-03/01
03/02
03/03
03/04
03/05
03/06
03/07
03/08
03/09
03/10
03/11
03/12
03/13
03/15
03/16
03/17
03/18
03/19
03/20-26
03/27
03/28
03/29
03/30
03/31
04/01
04/02
04/03
04/04
04/05
04/06
04/07
04/08
04/09
04/10
04/11
04/12
04/13
04/14
04/15
04/16
04/17
Coordinates
Activity
moored in Frenchman’s Bay, Sierra Leone River; found
several French ships and small vessels in Frenchman’s Bay
and an English ship and several small vessels in Whiteman’s
Bay; at anchor, general maintenance
sailed
8°32 x 0°42w
7°52 x 0°45w
7°16 x 0°18
6°57 x 0°11e
6°22
5°41n
5°20n
5°12
4°53
4°25
4°34
5°05
5°09
4°57
4°59n
5°09n
5°18n
5°32n
Cape Monserado
mouth of ‘Cochroe’ River; spoke to two Dutch vessels
Cape Apollonia; spoke with English sloop
anchored off Dick’s Cove
Commenda Fort; spoke to French sloop
off Cape Coast Castle (Dutch fort)
anchored off Annamaboe (Dutch fort)
Winnebah Fort (Dutch); Dutch ship at anchor
English Fort at Accra (English, Danish and Dutch forts all in
proximity)
5°43n
6°13n
6°12
anchored off Whydah; English, French and Portuguese forts;
numerous ships of all nationalities
visited English fort
sailed
5°28 x 1°49w
5°12 x 0°37w
4°52 x 0°6w
4°27 x 0°6e
3°22 x 0°40e
2°41 x 0°56e
1°56 x 1°13e
1°01 x 0°27e
0°52 x 0°46w
0°46 x 1°58w
0°46 x 2°31w
0°23 x 2°30w
205
Year
1775
continued
Month &
Day
04/18
0°10s x 2°10w
04/19
04/20
04/21
04/22
0°47s x 1°26w
1°03s x 1°42w
1°11s x 2°22w
1°20s x 3°22w
04/23
1°28s x 4°43w
04/24
04/25
04/26
04/27
04/28
04/29
04/30
05/01
05/02
05/03
05/04
05/05
05/06
05/07
05/08
05/09
05/10
05/11
05/12
05/13
05/14
05/15
05/16
05/17
05/18
05/19
05/20
05/21
05/22
05/23
05/24
05/25
05/26
05/27
05/28
1°40s x 7°02
1°27s x 9°55
1°33s x 11°32w
1°30s x 13°12w
1°25 x 15°34
1°21 x 18°02
1°16 x 20°22
0°47s x 22°28
0°9s x 24°43
0°29n x 26°34
1°5n x 27°10
1°42n x 27°32
2°42n x 28°7
3°26n x 28°35w
4°6n x 28°45w
4°57n x 28°57w
5°26n x 28°52w
5°49n x 29°15w
6°07n x 29°47w
6°22 x 30°48w
6°33 x 31°19w
6°42 x 32°26w
7°04 x 33°40w
8°03 x 35°22w
9°11 x 37°27w
10°22 x 40°13w
11°34 x 43°15w
12°23 x 46°13w
12°46n x 49°4w
12°55 x 57°57w
13°04 x 54°45w
13°14 x 57°34w
13°09 x 60°03w
12°58 x 62°40w
13°23n x
64°20w
13°17 x 66°04
13°10n
05/29
05/30
Coordinates
Activity
washed decks regularly with vinegar; exercised guns more
often
Barbados
206
Year
1775
continued
Month &
Day
05/31
06/01
06/02
06/03
06/09-07/12
Coordinates
anchored in Carlisle Bay, Barbados
13°25
13°47
14°57
west end of Barbados
moored in Port Royal, Jamaica; general overhaul and
provisioning
sailed; patrolled around Jamaica and Caribbean and returned
to England
arrived Spithead
Spithead
refit, rigging
in dock 20
in Portsmouth harbor; new bowsprit, new gammoning, new
rigging, shrouds, provisions
moored in Spithead
sailed; cruising
07/13
08/28
08/28-09/05
09/06-22
09/23-10/10
10/11-11/03
11/04-16
11/16
11/23
11/24
11/25
11/26
11/27
11/29
11/30
12/01
12/02
12/03
12/04
12/05
12/06
12/07
12/08
12/09
12/10
12/11
12/12
12/13
12/14
12/15
12/16
12/17
12/18
12/19
12/20
12/21-29
12/30
12/31
Activity
49°10 x 1°47w
48°20 x 2°36w
46°40 x 3°36w
46°05 x 5°31w
44°30 x 5°08w
44°04 x 00°04w
44°41 x 1°01w
45°00 x 1°17w
44°58 x 1°22w
44°14 x 1°41w
43°15 x 2°03w
42°39 x 2°19w
40°49 x 3°00w
38°47 x 3°47w
37°12 x 4°24w
34°45 x 5°20w
32°40
Madeira
Madeira
31°59
32°43 x 1°15e
32°06 x 2°53e
31°38 x 3°35e
30°40 x 3°27e
29°25
29°10
28°53
26°43
23°46 x 0°43w
in Santa Cruz Bay, Tenerife
Grand Canary
207
Year
1776
Month &
Day
01/01
01/02
01/03
01/04
20°32 x 0°12w
18°29 x 0°40e
01/05
01/06
01/07
01/08
17°34
16°06
14°55
14°19 x 0°20e
01/09
01/10
01/11-13
01/13
01/14
01/15
01/16
01/17
01/18
01/19-02/04
02/05-06
02/07-08
02/09-13
02/14-16
02/17
02/18
02/19
02/20
02/21
02/22
02/23
02/24
02/25
02/26
02/27
02/28
02/29
03/01
03/02
03/03
03/04
03/05
03/06
03/07
03/08-17
03/18-22
03/23
13°34
13°35
13°10 x 00°36w
13°10 x 00°36w
11°40 x 00°47w
9°57 x 00°16w
9°8 x 1°22e
8°44 x 2°36e
Coordinates
21°29n
7°59n
8°08 x 00°34w
7°11 x 00°22w
7°09 x 00°31e
7°04 x 1°11e
6°58n
6°42n
6°23n
6°09n
5°54n
5°38n
5°18
4°43
4°18
4°32n
5°03
5°08
4°57
4°47
4°58
5°10
Activity
running along Barbary coast
anchored off Cape Blanco
Senegal Fort
Goree; fired at and brought to French brig forcing it to show
colors
mouth of Gambia river
anchored at mouth of Gambia river
Anchored at Cape St. Mary
Cape St. Mary
Cape St. Mary
Cape St. Mary
Cape St. Mary
Cape St. Mary
Cape Sierra Leone
anchored in Frenchman’s Bay
Cape Sierra Leone
off Banana Islands
anchored off Banana Islands
around Banana Islands
Cape Sierra Leone
Cape Sierra Leone
Cape Sierra Leone
Cape Sierra Leone
Cape Marte
Cape Palmas
Cape Apollonia
Dick’s Cove Castle
English fort at Commenda
anchored off Cape Coast Castle
anchored off Cormantyne Fort (Dutch) 21
anchored off Assam (Alsam?)
208
Year
1776
continued
Month &
Day
03/24
03/25-27
03/28
03/29
03/30
03/31-04/01
04/02-20
04/21
04/22-05/02
05/06
05/07
05/08
05/09
05/10
05/11
05/12
05/14
05/15
05/16
05/17
05/19
05/20
05/21
05/22
05/23
05/24
05/25
05/26
05/27
05/28
05/29
05/31
06/01
06/02
06/03
06/04
06/05
06/06
06/07
06/08
06/09
06/10
06/11
06/12
Coordinates
5°20
Activity
Winnebah
anchored off Accra (English fort); Dutch, Danish forts also
5°43
5°44
6°13
6°07 to 0°23n x
0°42 to 5°3e
00°16n
anchored at Whydah (English fort)
off the coast of Whydah
north end of the island of St. Thomas
in Annadechoros Bay, St. Thomas island
00°45s x 0°52w
00°56s x 1°42w
1°05s x 2°51w
1°07s x 3°48w
1°48s x 5°15w
2°17s x 7°20w
2°04s x 9°14w
1°55s x 12°31w
2°26s x 13°54
2°31s x 15°18
2°11s x 16°41
2°07s x 19°29
2°19s x 21°08
2°41s x 23°06
2°57s x 25°29
3°21s x 27°10
3°34s x 28°37
3°06s x 30°32
2°19s x 32°29
0°59s x 34°09
0°33n x 35°42
2°06n x 36°47
4°22n x 37°57
3°17 x 38°50
5°52 x 39°19
6°56 x 40°19
8°28 x 41°55
9°44 x 44°18
10°58 x 46°48
12°00 x 49°10
12°23 x 51°14
12°37 x 53°14
13°22 x 55°23
south end of Barbados
Carlisle Bay, Barbados
209
Year
1776
continued
Month &
Day
06/13-18
Coordinates
Cape Solomon to Martinico
06/22-07/05
07/06
moored in Port Royal harbor
sailed with 22 vessels and Maidstone; bound up North
American coast
company added West Florida pacquet (sic) and now number
105 merchant
07/10
10/01
10/03
10/12
10/13-28
10/29-11/16
11/01
11/02
11/03
11/04
11/05
11/06
11/07
11/08
11/10
11/13
11/17
11/18-20
11/23-12/05
12/06
12/07-14
1777
12/15-26
12/28-01/23
01/24-02/28
03/01-20
03/21-04/02
04/05
04/06
04/08-15
04/16-25
04/26-05/10
05/11-22
05/23-06/01
06/01-04
06/05-09
06/10
06/10-22
06/23-07/25
Activity
liberated the Anne from Dominica bound for London and
taken by an American privateer
chased off what appeared to be an American privateer
entered St. Lawrence harbor
St. Lawrence harbor
Atlantic crossing 23
44°47 x 08°10
45°14 x 11°10
45°30 x 14°56
45°34 x 16°12
44°43 x 18°08
44°24 x 22°36
44°37 x 25°20
45°08 x 27°46
47°59 x 35°40
49°24 x 45°40 22
arrived at Spithead
anchored at Spithead
in Portsmouth Harbor
aside sheer hulk replacing mainmast
in Portsmouth Harbor
4°44n x 0°49e
4°44n x 00°49e
to 8°28s x 6°13w
in dock; no reason given
Portsmouth harbor; refit, maintenance, provisioning 24
at Spithead
sailed as escort to convoy to Tenerife, Grand Canary
in and around Tenerife and Grand Canary
anchored at Senegal Fort
anchored at Senegal Bar
mouth of Gambia River
worked from Cape St. Mary to Cape Sierra Leone
in Frenchman’s Bay, Sierra Leone
Cape Sierra Leone to Cape Palmas
Cape Palmas to Cape Apollonia
to Commenda Castle
Cape Coast Castle
Annamoboe
worked down African coast from Annamaboe
Atlantic crossing
210
Year
1777
continued
Month &
Day
07/26
arrived Carlisle Bay, Barbados
patrol around Dominica with HMS Jenny
08/07
arrived Port Royal
08/07-10/26
Port Royal; overhaul blocks and rigging, new gammoning
and bobstays, blacking yards and rigging, reeving the
running rigging, working up junk 25, scraped and payed deck,
lower masts, and sides
departed Port Royal with HMS Bute and six merchantmen
arrived Bluefields Bay, Jamaica
in Bluefields Bay
departed Bluefields Bay with Bute, Nancy sloop and 17 sail
Nancy sloop parted company and made for Pensacola
liberated schooner taken by American privateer
Bute started taking on water and Pallas’ carpenter sent to
assist
Bute scuttled by her captain
12/03
01/14-16
01/17-29
01/30-04/24
04/25-05/18
05/19-24
05/25-27
05/28-06/12
08/24
09/05-11
09/11-16
09/17-10/08
10/09-12
10/13-31
11/01-29
11/29-12/09
12/10-11
12/12-26
12/27-29
1779
Activity
07/27-08/07
10/27
11/07
11/08-09
11/10
11/15
11/18
11/29
1778
Coordinates
12/30-01/25
01/26-02/25
03/05-05/02
05/03-22
05/23-06/16
06/17
anchored at Spithead 26
in Portsmouth Harbor 27
in dock; iron ballast out; cleaned and rummaged; boatswain
and carpenter stores returned; fitting the rigging 28
in Portsmouth
at Spithead
sailed for Torbay
at Torbay
arrived at St. Lawrence
St. John’s, Newfoundland
local patrol; Cape Race; Cape Chapeau Rouge
moored at St. Peter’s Road, Newfoundland
local patrol
St. John’s harbor 29
escorted convoy to Gibraltar with Invincible and 40 plus sail
in Gibraltar Bay
in Cadiz Bay
patrol St. Mary and St. Sebastian
in Cadiz Bay
Cadiz to Spithead
Mitler [?] Banks and Spithead
in Hamoze near Spithead; refit, reeving running rigging,
provisioning, replaced canvas, masts and bowsprit, painted
lower masts, re-rigged
around Guernsey, Grovedela Bay, Cancale Bay, Cawsand
Bay 30
moored at Spithead
depart with convoy, 28 sail and HMS Cameleon
211
Year
1779
continued
Month &
Day
06/21
06/22
06/23
06/24
06/25
06/26
06/27
06/29
07/01
07/03
07/04-11
07/13
07/15
07/19
07/21
07/25
07/30
08/02
08/08
08/14
08/25-09/11
09/12-10/21
Coordinates
49°25 x 1°36w
49°16 x 3°01w
48°53 x 5°25
47°03 x 7°33
xxxx x 8°13
44°39 x 8°27
43°21 x 8°39
38°54 x 8°52
34°55 x 8°26
32°49 x 10°30
moored at Funchal Bay
west end of Madeira
30°54 x 00°47w
26°55 x 6°13
24°24 x 9°19
19°52 x 15°16
15°22 x 23°37
13°05 x 29°05w
off Carlisle Bay, Barbados
moored at English Harbor
moored at Port Royal
patrol around Cuba, Jamaica, Tortuga, Cape Nichola, Monte
Christie, Porto Plata, and Isabella Point
Port Royal Harbor
10/22-11/05
1780
11/06-01/01
01/02-23
01/24
02/08
02/12
02/16
02/20
02/23
02/28
03/01
03/04
03/07
03/11
03/13
03/21
04/08
04/10
04/25
05/01-06/10
Activity
patrol around Caribbean
moored at Port Royal
depart as part of large fleet of men of war and merchantmen
28°49n x
79°32w
32°23 x 86°28
29°49 x 83°33
29°45 x 69°40
28°59 x 66°57
29°00 x 65°37
28°34 x 65°10
26°15 x 65°44
19°58 x 65°06
17°15 x 70°20
17°19 x 73°52
17°18 x 75°02
12°33 x 75°18
13°54 x 71°25
joined with HMS Phoenix
Phoenix in company
Port Royal
212
Year
1780
continued
Month &
Day
06/11-21
Coordinates
short patrol with HMS Ulysses; Cape Tiberon and Isle of
Ash
Port Royal
Bluefields Bay
joined with HMS Lowestoffe
06/22-07/11
07/16-22
07/27
07/30
08/01
08/09
08/12
09/06
09/13
09/15
09/19
09/22
09/27
10/01
10/05
01/06-18
01/19-23
10/24-31
11/01-15
19°50 x 80°51
21°26 x 83°40
23°19 x 85°44
24°11 x 85°49
took Spanish prize 31
in and around Tortuga Bank
Key Largo
31°50 x 78°07
29°54 x 74°47
28°54 x 70°31
23°35 x 69°06
21°53 x 71°00
worked back to Jamaica
Port Royal
short local patrol
short local patrol; took Spanish pacquet [sic] prize on the
10th
Port Royal
sailed with HMS Diamond and HMS Pomona in company;
patrol
11/16-12/03
12/04
1781
01/09
01/17
02/03
02/03-10
02/11
19°27 x 65°30
20°05 x 63°59
02/24
02/26
03/03
03/07
03/13
03/18
03/20
03/21
03/22-04/10
04/11-05/14
05/15
16°17 x 71°13
14°15 x 68°56
12°35 x 69°25
15°08 x 70°05
12°23 x 65°47
06/17
06/21
07/21-08/20
08/21
Activity
took prize snow 32
took prize brig
return to Port Royal
in Port Royal
patrol with Diamond, Pomona, HMS Pelican, and Guay
Trouin (Frouin?)
took two Spanish brigs and a 40-gun letter of marque
took American brig from Philadelphia
parted company with all but Pomona at Bon Aire [sic]
work back to Jamaica
Port Royal
sail in company with Diamond and Ulysses and eight sail
merchants
joined ‘active’ privateer from Jamaica
took American prize ship
Port Royal
sailed with fleet including Ramillies
213
Year
1781
continued
Month &
Day
09/13
10/24
10/31
11/06
11/07-12/17
1782
12/17-02/28
03/01-05
03/06
03/28-04/25
04/26-05/21
05/22-06/27
06/28-07/24
07/25
1783
January
1783
02/12
Coordinates
Activity
Diamond joined
Porto [sic] Rico
Bon Aire
return to Port Royal
Port Royal, Kingston and Fairway
patrol Turks, Isabella Point; HMS Resource in company
Kingston harbor
Port Royal
Kingston
Port Royal; sheer hulk, replacing main mast
Patrol
Port Royal
Departed Port Royal with Admiral Graves’ fleet prize fleet
from the Battle of the Saints, bound for England. 33
From Late September,1782 until January 1783, the whereabouts of Pallas are unknown.
1
Halifax. 34 Late January sailed from Halifax escorting a
convoy bound for England.
Calheta Harbor, São Jorge, Azores; Pallas set on fire 35
Until or unless otherwise noted, the following information comes from TNA: PRO ADM 51/666.
Lieutenant’s logbooks from HMS Pallas.
2
Gardiner, First Frigates, p. 22-28.
3
TNA: PRO ADM 51/666. Lieutenant’s logbooks from HMS Pallas. Both the quantity of information and
the degree of detail available about Pallas’ career varies considerably in the logs of her numerous
Captains; variance which is inevitably reflected in this table.
4
Clowes, Royal Navy, Vol. 3, p. 193-94. Although there is a gap in the Pallas logbooks for this period,
Clowes states that from August 6-17, Pallas participated in Admiral Howe’s raids on Cherbourg and that
Howe transferred his flag to Pallas in order to be able to stand in closer to shore during the operation.
5
TNA: PRO ADM 51/666. Lieutenant’s Logbooks from HMS Pallas. The longitudes given in the log
book for November 20 and 22 are incorrect coordinates that would place Pallas in Western Spain
6
TNA: PRO ADM 51/666. Lieutenant’s logbooks from HMS Pallas.
7
TNA: PRO ADM 51/666. Lieutenant’s logbooks from HMS Pallas. No explanation is given for this
change of command.
8
NMM: PJ/JC Vol. 1, National Maritime Museum Warship History Continuation Sheet microfilm.
9
Jenkins, History of the French Navy, 129-36. These were the French frigates Marshal Bell Isle (44),
Lablond (36) and Terpsichor (24). The two squadrons engaged and after a short, hour and a half long
battle all three French ships were taken. Pallas suffered sail and rigging damage, a shot through the
mainmast, and her best bower was shot away. The French frigates had been dispatched from Dunkirk in
October with a small detachment of troops under the command of the renowned privateer Captain Thurot
with orders to sail north and land a diversionary force in Ireland in preparation for the cross-channel
invasion.
10
Clowes, Royal Navy, Vol. 3, 303. At some point in the late summer of 1760, Pallas, Shrewsbury and
Argo engaged in a running battle with the French 74 Diadème escorting a convoy to Martinique.
Shrewsbury was a poor sailor and it was left to the frigates to harass and slow Diadème until Shrewsbury
214
could catch up. Unfortunately, Pallas exposed herself to a broadside from Diadème and was forced to
break off the pursuit.
11
Clowes, Royal Navy, Vol. 3, 253. This is interesting. Pallas was in a French port five months before
peace was suggested by the French.
12
All of the above information comes from TNA: PRO ADM 51/666 unless otherwise noted.
13
Unless otherwise noted the following information comes from TNA: PRO ADM 51/667 Lieutenant’s
Logbooks from HMS Pallas.
14
NMM: PJ/JC Vol. 1. National Maritime Museum Warship History Continuation Sheet microfilm. At
some point between January and May of 1771 Captain Laforey was relieved, because on May 7, 1771
when Pallas sets sail for the Mediterranean, Captain C. Watson was in command.
15
NMM: PJ/JC Vol. 1. National Maritime Museum Warship History Continuation Sheet microfilm.
16
Coordinates for May 12 through May 17, 1771 cannot be correct as they reference points on the Iberian
peninsula. Either little care was taken in the readings or the coordinates were transcribed incorrectly.
17
A gap in TNA: PRO ADM 51/667 Lieutenant’s Logbooks from HMS Pallas, for the period April 1 to
December 9, is partially covered in TNA: PRO ADM 51/4283.
18
TNA: PRO ADM 51/667. Lieutenant’s Logbooks from HMS Pallas. Record recommences after gap
filled by TNA: PRO ADM 51/4283. Lieutenant’s Logbooks from HMS Pallas.
19
Ibid.
20
TNA: PRO ADM 51/667. Lieutenant’s Logbooks from HMS Pallas. No specifics are given regarding
the repair undertaken while in dry dock.
21
TNA: PRO ADM 1/1611. Admiralty Correspondence. During this period, Captain Cornwallis received
news that an American brig in the Gabon River had arms and ammunition aboard. The brig was captured
with the assistance of Weasel sloop and 1st Lieutenant Bray of the Pallas was ordered to sail the prize to
Antigua.
22
Note that coordinates progress backwards from east to west. Presumably they were entered into the
logbook at a later date.
23
Information for November through December 1776 extracted from TNA: PRO ADM 51/4283.
24
NMM: PJ/JC Vol. 1. National Maritime Museum Warship History Continuation Sheet microfilm.
During this layover, Captain Cornwallis was reassigned and Captain Rowland Cotton took command.
25
Blanckley, Naval Expositor, 83. Junk was old rope cut into short lengths for use as swabs, nippers and to
be picked in oakum.
26
NMM: PJ/JC Vol. 1. National Maritime Museum Warship History Continuation Sheet microfilm. In
early 1778. Captain Rowland Cotton was reassigned and Captain Richard King took command.
27
TNA: PRO ADM 51/668. Lieutenant’s Logbooks from HMS Pallas. Unless otherwise noted the
following information comes from TNA: PRO ADM 51/668. Lieutenant’s Logbooks from HMS Pallas. It
is probable that the new logbook coincides with the change of command; Captain King records little in the
way of useful remarks during his tenure.
28
NMM: PJ/JC Vol. 1. National Maritime Museum Warship History Continuation Sheet microfilm. It is
almost certain that Pallas was coppered during this period in dry dock.
29
NMM: PJ/JC Vol. 1. National Maritime Museum Warship History Continuation Sheet microfilm.
During October 1778, Captain King was reassigned and Captain T. Spry took command.
30
NMM: PJ/JC Vol. 1. National Maritime Museum Warship History Continuation Sheet microfilm. I
have found references to an action at Concale around this date suggesting that Pallas was involved.
31
TNA: PRO ADM 51/668. Lieutenant’s Logbooks from HMS Pallas. The logbook contains no details as
to the ship type.
32
ibid., The nationality of the snow taken on January 9th and the brig taken on January 17th is not given.
33
Breen, “ Foundering of the HMS Ramillies,” 190. HMS Ramillies and several of the French prizes in the
convoy were lost in severe weather.
34
TNA: PRO ADM 51/668. Lieutenant’s Logbooks from HMS Pallas.
35
Crisman, “Looking for Ships,” 7-8.
215
VITA
Peter Erik Flynn
P.O. Box 1343
Helena MT 59624
eflynn13@yahoo.com
Education: M.A., Nautical Archaeology, Texas A&M University, 2006
B.A., Classics and History, University of Manitoba, 1998
Honors/Awards:
Phi Kappa Phi Honor Society, 2001- Present
Graduate Assistantship, J. Richard Steffy Ship Reconstruction Laboratory, 2001-2002
Travel Research Grant, Public Record Office and National Maritime Museum, London,
England; Summer 2002
Graduate Assistantship, J. Richard Steffy Ship Reconstruction Laboratory, 2002-2003
Publications:
Maintained and contributed to Texas A&M Nautical Archaeology Program Ship
Reconstruction Laboratory website
Contributed to “From Ships to Shore”, catalog for the Carrington Weems Antique Map and
Ship Model Exhibition at the J. Wayne Stark Galleries, Texas A&M University
Professional Experience:
Underwater Archaeological Excavation, Portimao harbor , Portugal, Summer 2002. F.
Castro
Archaeological Recording, Cais do Sodré project, Lisbon, Portugal, Summer 2002, C.
Rodriguez and F. Castro
Underwater Archaeological Excavation, Angra D expedition, Summer 2001. K. Crisman
Archaeological Recording, Cais do Sodré project, Summer 2001, C. Rodriguez and F. Castro
Underwater Archaeological Excavation, Combined Caesarea Expedition, Summers 2000 and
1999; Directors K. Holum and Professor Avner Raban
Archaeological Excavation/Asst. Supervisor/Acting Area Supervisor, Ein Gedi, Israel
Winter 1999; Y. Hirschfeld, Director; A.de Vincenz, Supervisor
Contract Archaeology / Cultural Resource Management, Environment and Archaeology,
LLC Florence, Kentucky, Fall 1999,;Summer-Fall 1998; V. Whitlatch, Supervisor
Archaeological Excavation / Artifact Restoration and Archiving, Ein Gedi, Israel, Winter
1998; Director, Y. Hirschfeld
Archaeological Excavation / Artifact Conservation and Archiving, Dnieprovskaya project,
Summer 1997; Professor D. Howorth, University of Manitoba and V.V. Bylkova,
Kherson Institute, Southern Ukraine
Archaeological Excavation, Summer 1997; Hermitage Museum, St. Petersburg Russia
excavation at Nymphaion, southern Ukraine; Expedition Leader, O. Sokolova
Archaeological Excavation / Geophysical Survey, Olbia project, southern Ukraine, Summer
1996; D. Howorth, University of Manitoba, Director
Archaeological Survey, Oropos project, (Euboa, Greece) Summer 1995; Director, M.
Cosmopoulos