Nothing Special   »   [go: up one dir, main page]

US421387A - Peters - Google Patents

Peters Download PDF

Info

Publication number
US421387A
US421387A US421387DA US421387A US 421387 A US421387 A US 421387A US 421387D A US421387D A US 421387DA US 421387 A US421387 A US 421387A
Authority
US
United States
Prior art keywords
tubes
plates
boiler
arches
tube
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Expired - Lifetime
Application number
Publication date
Application granted granted Critical
Publication of US421387A publication Critical patent/US421387A/en
Anticipated expiration legal-status Critical
Expired - Lifetime legal-status Critical Current

Links

Images

Classifications

    • CCHEMISTRY; METALLURGY
    • C10PETROLEUM, GAS OR COKE INDUSTRIES; TECHNICAL GASES CONTAINING CARBON MONOXIDE; FUELS; LUBRICANTS; PEAT
    • C10GCRACKING HYDROCARBON OILS; PRODUCTION OF LIQUID HYDROCARBON MIXTURES, e.g. BY DESTRUCTIVE HYDROGENATION, OLIGOMERISATION, POLYMERISATION; RECOVERY OF HYDROCARBON OILS FROM OIL-SHALE, OIL-SAND, OR GASES; REFINING MIXTURES MAINLY CONSISTING OF HYDROCARBONS; REFORMING OF NAPHTHA; MINERAL WAXES
    • C10G9/00Thermal non-catalytic cracking, in the absence of hydrogen, of hydrocarbon oils
    • C10G9/14Thermal non-catalytic cracking, in the absence of hydrogen, of hydrocarbon oils in pipes or coils with or without auxiliary means, e.g. digesters, soaking drums, expansion means
    • C10G9/18Apparatus
    • C10G9/20Tube furnaces
    • GPHYSICS
    • G21NUCLEAR PHYSICS; NUCLEAR ENGINEERING
    • G21CNUCLEAR REACTORS
    • G21C1/00Reactor types
    • G21C1/04Thermal reactors ; Epithermal reactors
    • G21C1/06Heterogeneous reactors, i.e. in which fuel and moderator are separated
    • G21C1/08Heterogeneous reactors, i.e. in which fuel and moderator are separated moderator being highly pressurised, e.g. boiling water reactor, integral super-heat reactor, pressurised water reactor
    • G21C1/084Boiling water reactors
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02EREDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
    • Y02E30/00Energy generation of nuclear origin
    • Y02E30/30Nuclear fission reactors

Definitions

  • a TTOR/VEY N FUCHS. Phnln-Lllhognphnr. Washinglon. II C- 3Sheets-Sheet 2.
  • This invention relates to steam-boilers, an d is especially intended for marine boilers, although applicable to other uses.
  • the object of the invention is to produce a boiler in which the parts shall be strong and [5 somewhat elastic, the circulation rapid, and
  • the casing exposed to the fire shall be largely protected by water-tubes.
  • Figure 1 is a top plan with part broken away to show a longitudinal section on the level of the water-tubes, which are partly omitted.
  • Fig. 2 is a side elevation with part of easing removed.
  • Fig. 3 is a cross-section about on the line of one of the water-pipes forming grate-supports, say on line y y, Fig. 4.
  • Fig. 3 is an enlarged detail of Fig. 3.
  • Fig. 4 is a longitudinal section about on line w m
  • Fig. 5 is a broken sectional detailof the manifold and side casing.
  • Fig. 6 is a broken inner side elevation of manifold and casing.
  • Fig. 7 is a broken detail of one of the connectingtubes and ties, partly in section.
  • Fig. 8 is a similar side view of de tail, Fig. 7.
  • Fig. 9 is a broken cross-sectional detail of central tie -plate and fastenings.
  • Fig. 10 is an enlarged horizontal section of downcast conduit protecting tubes and casing on lines A B, Fig. 11.
  • Fig. 11 is a section about on line z c, Fig. 10.
  • the shell of the boiler is composed of continuous convoluted sheets of metal, the convolutions consisting of arches or curves of different radii, there being a reverse curve of small radii between each twoarches of large radii. Tie-braces are attached tangentially to the large arcs.
  • the small arcs may be very small, and need not necessarily conform to a circle.
  • the numeral 1 indicates the shell-plate of the intermediate top sections, of which any convenient number may be employed.
  • the plates forming the top shell may be integral or not.
  • the plates at the junction of the arches 1 1 are secured to a tie-plate 3, the joint-pieces being stayed or strengthened by angleplates 4 4, held by rivets or bolts in any usual manner.
  • The-front and rear end walls of the arched portions of the shell are formed of convolute plates 5 5, as indicated in Figs. 1 and 2 of the drawings.
  • the tieplate 3 is held to the tube-sheet 7 at the lower edge by angle-pieces 8 8.
  • the bottom member of the boiler is somewhat similar to the top member, having arches or convolutions in reverse direction and having the edges of the arches Iconnected to the bottom tubesheet 17.
  • the space between the tube-sheets 7 and 17 is pretty well filled with vertical water-tubes 11.
  • a plate 13 below the tieplate 3 connects the tube-sheet 7 to the bottom member of the boiler.
  • the lower edge of plate 13 is riveted or otherwise fastened to the upturned edges of the arched or convolute plates 21, which form the shell of the lower member of the boiler. (See Fig. 9.)
  • the tie-plate and casing at the sides of the space filled by tubes 11 are substantially like the tie-plate 13, but protected on the inner surface only.
  • the plate 3 is preferably perforated, and plate 13 may also be perforated for lightness.
  • Plate 13 is protected by asbestus, soapstone, or other refractory slabs or sheets 14, and the water-tubes 11 next these protective sheets serve to protect them also from the intense heat of the flame which passes between the tubes 11.
  • the edges of the lower tube-sheet 17 are corrugated at 22, and riveted to the arch-plates below the corrugations to permit. a slight elasticity and difference of expansion in the parts.
  • the space 23 within the corrugations may be filled with asbestus or other refractory packing, and the space 21 between the edges of the arch-platesmay be similarly filled, the latter filling being retained by binding-strips 25, secured to the arches.
  • the side plates 2 and the central shell-plates 1, Fig. 3, are riveted or otherwise fastened to tie-plates 33 one at each side of the entering angle or curve. Tie-plates 33 reach down nearly to the tube-sheet 7.
  • the lower edges of the plates 33 are bolted or otherwise fastened to flanges 34 on open thimbles 35, which thimbles have internal screw-threads.
  • Tie-tubes 36 extend from the upper t-himbles 35 to a corresponding set of thimbles 35 to which the upturned edges 21 of the lower arched plates 21 are bolted or riveted. (See Figs. 7 and S.)
  • the convolute plates are secured at the convolutions by angle-plates 21 to the thimbles.
  • the plates constituting; the arches may be of any width which is a multiple of an arch, the edges of sheets being secured and the convolutions braced.
  • the tubesheets 7 and 17, through which the tie-tubes pass, may be stopped by packing bushes with grommets 37, which engage the external screw-threaded portion of the tie-tubes 36 and hold the tube-sheets fast to the tie-tubes.
  • the upper arched sections of the boiler are connected to the lower reversed sections, at the rear of the fire-box, by downcast conduits 23, which may connectwith a slight offset at the rear of the tube-sheet 7.
  • the downcast conduits 23 extend below the level of the lower arches 21, and each downcast connects with a corresponding lower arch by a conduit-1S, which terminates inside the downcast in a scoop or spoon 19.
  • the downcasts 23 are of ample capacity and convey large volumes of water from the upper to the lower arches, the
  • Curved shields 24 are therefore placed in the downcasts near this face, forming curved chambers 25, up
  • Figs. 10 and 11 These plates 24 are curved forward at the upper ends to'catch the steam, and pipes 26 extend upward to convey steam up into the steam-space of the boiler.
  • the downcasts 23 are connected together below the pipes 18 by cross-pipes 28, .and below the conduits may form sedimenttraps.
  • the cross-pipes 28 are connected to the tube-sheet 7 by tubes 41, Figs. 10 and 11.
  • the lower boiler member has branches 60 leading to manifold boxes 61 about on a level with the top of the furnace and parallel with pipes 51. and can be separately replaced.
  • the rear box 61% is connected to the top member of the boiler instead of the bottom member.
  • the boxes 61 are made of short lengths, with The boxes 61 are short sections single points of attachment, in order to 'overcome the effects of expansion and contraction.
  • Each manifold box 61 has a number of water-tubes 62 connected to pipe '51, these water-tubes forming the inner sidewall of the furnace.
  • the box 61 should be long enough to contain about six of these tubes 62, andat the top of the box, over each tube, there is a hole covered by a cap 63, held down by a suitable clamp 64.
  • the caps 63 may be removed and the tubes 62 withdrawn through the opening, the tubes being secured or expanded into place in usual manner.
  • tubes 62 we place plates of soapstone, fire-brick, or other refractory material 54, then a packing of asbestus or similar material 55, and then a covering of corrugated metallic plates 56, this outer covering being supported by angle-plates 57 and removable fastenings 58. may be closed by a refractory covering 59.
  • the boxes are preferably malleable castings.
  • the shell-plates are preferably rolled sheets of steel.
  • a boiler consisting, essentially, of a top member composed of connected arched sections, a bottom member of sections arched in reverse direction, and downcasts at the rear connecting the two members and extending below the lower arches, thus forming a rear water-wall to the furnace, substantially as described.
  • a steam-boiler consisting, essentially, of v a top member composed of connected arches, a bottom member composed of arches in reverse directions, tie plates connecting the curves formed by the junction of the arches to the transverse tube-sheets, and ties connecting these' tie-plates, and also the tubesheets, all combined substantially as described.
  • a boiler-shell consisting, essentially, of a series of horizontal arches connected together side by side, the ends of said arches consisting of a similar number of substantially vertical arches united at their edges to the horizontal arches, substantially as described.
  • top and bottom members having tube-sheets facing each other, a tie-plate between the tubesheets, and a refractory protective covering for said tieplate, substantially as described.
  • top and bottom members substantially as described, tieplates connecting the same, a refractory cov- 4 ering for said tie-plates, and Water-tubes connecting the boiler members and bearing against the said refractory covering, substan tially as set forth.
  • tie-tubes connecting the thimbles and passing through and tied to the tube-sh eets, all the elements in combination, substantially as described.
  • top and bottom members downcasts connecting the same, and cross-pipes and vertical pipes connecting said cross-pipes to the top member, and a refractory covering or casing rest-ing against said vertical pipes and downcasts, all combined substantially as described.

Landscapes

  • Physics & Mathematics (AREA)
  • Engineering & Computer Science (AREA)
  • Chemical & Material Sciences (AREA)
  • Oil, Petroleum & Natural Gas (AREA)
  • Plasma & Fusion (AREA)
  • General Engineering & Computer Science (AREA)
  • High Energy & Nuclear Physics (AREA)
  • Thermal Sciences (AREA)
  • Chemical Kinetics & Catalysis (AREA)
  • General Chemical & Material Sciences (AREA)
  • Organic Chemistry (AREA)
  • Heat-Exchange Devices With Radiators And Conduit Assemblies (AREA)

Description

(No Model.) 3 Sheets-Sheet l.
N. B CLARK & F. B; KING.
STEAM BOILER.
Patented Feb.
A TTOR/VEY N. FUCHS. Phnln-Lllhognphnr. Washinglon. II C- 3Sheets-Sheet 2.
(No Model.)
N; B. CLARK 82 F. B. KING.
STEAM BOILER.
6M 0 v 9 00 1 n mg I 1D Q G F Q N d 9 & T W mm U s w E a P flrmmlp l1 k MWHHUMW V M Q Q 8% u 1. & E 2 l 4 V 0. o I. 0 0 U E N mm M M H Suva/14 601;
2mph ncooeo I N. PFIERS. PholwL'rlhcgrapher. wmm mn, DJ).
3 Sheets'Sheet 3.
N. B. CLARK & F. B. KING.
(No Model.)
STEAM BOILER.
No. 421,387. Patented Feb. 18, 1890.
' amuemtoz 72m /5. 6M FMW/J/Z ,MMM.
N. PETERS, Phnfio-LlKhogF-lphel: Washingtnn. [1.13.
UNITED STATES PATENT OFFICE.
NATHAN B. CLARK, OF UNITED STATES NAVY, AND FRANK B. KING, OF WVASI-IINGTON, DISTRICT OF COLUMBIA.
STEAM-BOILER.
SPECIFICATION forming part of Letters Patent No. 421,387, dated February 18, 18 90. Application filed June 8, 1889. Serial No. 313,548. (No model.)
I all whom, it may concern:
Be it known that we, NATHAN B. CLARK, United States Navy, and FRANK B. KING, both residing at Washington, in the District of Columbia, have invented certain new and useful Improvements in Steam-Boilers, of which the following is a specification, reference being had therein to the accompanying drawings.
1o This invention relates to steam-boilers, an d is especially intended for marine boilers, although applicable to other uses.
The object of the invention is to producea boiler in which the parts shall be strong and [5 somewhat elastic, the circulation rapid, and
the casing exposed to the fire shall be largely protected by water-tubes.
Figure 1 is a top plan with part broken away to show a longitudinal section on the level of the water-tubes, which are partly omitted. Fig. 2 is a side elevation with part of easing removed. Fig. 3 is a cross-section about on the line of one of the water-pipes forming grate-supports, say on line y y, Fig. 4. Fig. 3 is an enlarged detail of Fig. 3. Fig. 4 is a longitudinal section about on line w m, Fig. 3. Fig. 5 is a broken sectional detailof the manifold and side casing. Fig. 6 is a broken inner side elevation of manifold and casing. Fig. 7 is a broken detail of one of the connectingtubes and ties, partly in section. Fig. 8 is a similar side view of de tail, Fig. 7. Fig. 9 is a broken cross-sectional detail of central tie -plate and fastenings. Fig. 10 is an enlarged horizontal section of downcast conduit protecting tubes and casing on lines A B, Fig. 11. Fig. 11 is a section about on line z c, Fig. 10.
The shell of the boiler is composed of continuous convoluted sheets of metal, the convolutions consisting of arches or curves of different radii, there being a reverse curve of small radii between each twoarches of large radii. Tie-braces are attached tangentially to the large arcs. The small arcs may be very small, and need not necessarily conform to a circle.
The numeral 1 indicates the shell-plate of the intermediate top sections, of which any convenient number may be employed.
2 2 denote the side shell-plates.
The plates forming the top shell may be integral or not. The plates at the junction of the arches 1 1 are secured to a tie-plate 3, the joint-pieces being stayed or strengthened by angleplates 4 4, held by rivets or bolts in any usual manner. The-front and rear end walls of the arched portions of the shell are formed of convolute plates 5 5, as indicated in Figs. 1 and 2 of the drawings. The tieplate 3 is held to the tube-sheet 7 at the lower edge by angle-pieces 8 8. The bottom member of the boiler is somewhat similar to the top member, having arches or convolutions in reverse direction and having the edges of the arches Iconnected to the bottom tubesheet 17. The space between the tube-sheets 7 and 17 is pretty well filled with vertical water-tubes 11. A plate 13 below the tieplate 3 connects the tube-sheet 7 to the bottom member of the boiler. The lower edge of plate 13 is riveted or otherwise fastened to the upturned edges of the arched or convolute plates 21, which form the shell of the lower member of the boiler. (See Fig. 9.)
The tie-plate and casing at the sides of the space filled by tubes 11 are substantially like the tie-plate 13, but protected on the inner surface only. The plate 3 is preferably perforated, and plate 13 may also be perforated for lightness. Plate 13 is protected by asbestus, soapstone, or other refractory slabs or sheets 14, and the water-tubes 11 next these protective sheets serve to protect them also from the intense heat of the flame which passes between the tubes 11. The edges of the lower tube-sheet 17 are corrugated at 22, and riveted to the arch-plates below the corrugations to permit. a slight elasticity and difference of expansion in the parts. The space 23 within the corrugations may be filled with asbestus or other refractory packing, and the space 21 between the edges of the arch-platesmay be similarly filled, the latter filling being retained by binding-strips 25, secured to the arches. The side plates 2 and the central shell-plates 1, Fig. 3, are riveted or otherwise fastened to tie-plates 33 one at each side of the entering angle or curve. Tie-plates 33 reach down nearly to the tube-sheet 7. The lower edges of the plates 33 are bolted or otherwise fastened to flanges 34 on open thimbles 35, which thimbles have internal screw-threads. Tie-tubes 36 extend from the upper t-himbles 35 to a corresponding set of thimbles 35 to which the upturned edges 21 of the lower arched plates 21 are bolted or riveted. (See Figs. 7 and S.) The convolute plates are secured at the convolutions by angle-plates 21 to the thimbles. Thus the plates constituting; the arches may be of any width which is a multiple of an arch, the edges of sheets being secured and the convolutions braced. the tubesheets 7 and 17, through which the tie-tubes pass, may be stopped by packing bushes with grommets 37, which engage the external screw-threaded portion of the tie-tubes 36 and hold the tube-sheets fast to the tie-tubes. As the upper arched plates 2 throw a heavy stress on the tube-plate 7 ,itis advisable that this tube be thicker than plate 17. This plate 7 forms a transverse tie between the sides of the boiler. The upper arched sections of the boiler are connected to the lower reversed sections, at the rear of the fire-box, by downcast conduits 23, which may connectwith a slight offset at the rear of the tube-sheet 7. The downcast conduits 23 extend below the level of the lower arches 21, and each downcast connects with a corresponding lower arch by a conduit-1S, which terminates inside the downcast in a scoop or spoon 19. The downcasts 23 are of ample capacity and convey large volumes of water from the upper to the lower arches, the
scoops 19 tending to deflect the downwardlymoving current into the lower arches.
As the side of the downcasts 23 toward the fire-box will be exposed to intense heat, there will be a tendency to the formation of an upward current of mixed steam and water on this face of the downcasts. Curved shields 24 are therefore placed in the downcasts near this face, forming curved chambers 25, up
I which the steam and water may pass, as
shown in Figs. 10 and 11. These plates 24 are curved forward at the upper ends to'catch the steam, and pipes 26 extend upward to convey steam up into the steam-space of the boiler. The downcasts 23 are connected together below the pipes 18 by cross-pipes 28, .and below the conduits may form sedimenttraps. The cross-pipes 28 are connected to the tube-sheet 7 by tubes 41, Figs. 10 and 11.
1 These tubes serve as supports for the refrac- The openings through heat of such a furnace as We employif fully exposed to the flame, it is found that a protection by water-pipes covering a part of the surface adds greatly to the durability. Thus the downcasts 23 and water-tubes 41 protect the casing 44 45 46 quite efficiently. (See Figs. 10 and 11.) Should the length of' the arches be great, the front of the top member may be connected to the bottom member by a large downcast 20, extending from tubesheet 7 to tube-sheet 17. The theory of upward circulation through small water-tubes and downward circulation through large tubes is well understood.
The direction of the hot gases is from the furnace 47 backward under the bottom boiler member to the downcasts 23, then upward boiler, pipes 51 extend forward to the front end of the furnace to supply water to the vertical tubes of the manifold. (See Fig. '2.) These pipes should taper, as the water-supply will be proportioned to the distance from the downcast, and a convenient construction is shown in Figs. 5 and 6, where the bottom and sides of the pipev are shown composed of a horseshoe curved plate 52 and the top of a flat plate 53, flanged downward, the joints being riveted.
The lower boiler member has branches 60 leading to manifold boxes 61 about on a level with the top of the furnace and parallel with pipes 51. and can be separately replaced. The rear box 61% is connected to the top member of the boiler instead of the bottom member. The boxes 61 are made of short lengths, with The boxes 61 are short sections single points of attachment, in order to 'overcome the effects of expansion and contraction.
Each manifold box 61 has a number of water-tubes 62 connected to pipe '51, these water-tubes forming the inner sidewall of the furnace. The box 61 .should be long enough to contain about six of these tubes 62, andat the top of the box, over each tube, there is a hole covered by a cap 63, held down by a suitable clamp 64. The caps 63 may be removed and the tubes 62 withdrawn through the opening, the tubes being secured or expanded into place in usual manner.
Outside the tubes 62 we place plates of soapstone, fire-brick, or other refractory material 54, then a packing of asbestus or similar material 55, and then a covering of corrugated metallic plates 56, this outer covering being supported by angle-plates 57 and removable fastenings 58. may be closed by a refractory covering 59.
The side walls of the tube-space filled with The space between tubes 60 tubes 11 are covered by light open plates 73,
ted lines, Fig. 4, thus giving access to the upper ends of tubes 11 for cleaning or replacement. It will thus appear that the skeleton of the furnace is composed of the grate, vertical Water-tubes at the sides, and nearly ver- ,removed and readily replaced.
tical downcasts at the rear, the top of the furnace being the arches of the lower boiler member. The heat from the furnace passes backward, then upward between pipes 18, then forward among water- tubes 11 and 36, and so to the uptake. heavy, and will not require replacement. Tubes 11 can be readily replaced.
It will be seen that there is considerable elasticity allowed in some parts of the structure, as in the connections of shell-plates 2 21 to their respective tube-sheets All small parts exposed to high temperature can be The boxes are preferably malleable castings. The shell-plates are preferably rolled sheets of steel.
What we claim.is
1. A boiler consisting, essentially, of a top member composed of connected arched sections, a bottom member of sections arched in reverse direction, and downcasts at the rear connecting the two members and extending below the lower arches, thus forming a rear water-wall to the furnace, substantially as described.
2. A steam-boiler consisting, essentially, of v a top member composed of connected arches, a bottom member composed of arches in reverse directions, tie plates connecting the curves formed by the junction of the arches to the transverse tube-sheets, and ties connecting these' tie-plates, and also the tubesheets, all combined substantially as described.
3. A boiler-shell consisting, essentially, of a series of horizontal arches connected together side by side, the ends of said arches consisting of a similar number of substantially vertical arches united at their edges to the horizontal arches, substantially as described.
4. The combination of the top arched sections connected at theinturned angle to a tieplate, the bottom arches connected to a tieplate, and a connection uniting the said tieplates to the top and bottom members, substantially as described.
5. The combination of the top arched memher, the bottom arched member, tube-sheets The tubes 36 areto which the arches are connected, and a tieplate extending from one tube-sheet to the other, substantially as described.
6. The combination with the top and bottom members having tube-sheets facing each other, a tie-plate between the tubesheets, and a refractory protective covering for said tieplate, substantially as described.
7. The combination of the top and bottom members, substantially as described, tieplates connecting the same, a refractory cov- 4 ering for said tie-plates, and Water-tubes connecting the boiler members and bearing against the said refractory covering, substan tially as set forth.
8. The combination, with the arched shellplates, of ties connecting the edges of the top and bottom plates to open thimbles and tubes connecting said thimbles, substantially as described.
9. The top and bottom arched members, the tube-sheets facing each other, ties connecting the edges of the arches to open thimbles,
as described, and tie-tubes connecting the thimbles and passing through and tied to the tube-sh eets, all the elements in combination, substantially as described.
10. In a steam-boiler, the combination of an outer shell composed of convolute sheets, tiepieces secured to the sheets at the lines of contra flexure, and ties joining these tiepieces from the opposite sides of the boiler, substantially as described.
11. In a steam-boiler of the character dcscribed, the combination, with an inturned arch-plate, of the flue-sheet secured thereto, one of said plates having a corrugation near its edge to permit a slight elasticity and allow for expansion.
12. The combination, with the tube-sheet and the shell-plate, one of the plates having a corrugation near the joint, of a non-conducting packing filling said corrugation, substantially as described.
13. The combination, with the inturned edges of the arched plates, as 21, of a tieplate to which said arches are secured, a nonconducting or refractory packing between the edges of the arches, and a supportingpiece for said packing, substantially as described.
14. The combination, with the top and bottom members, of the downcast conduits connecting the two and ashield inside the downcast, forming a partition separating that part next the fire from the main part of the downcast.
15. The combination, with the downcasts, of deflecting curved shields inside the same and steam-pipes 26, extending through and above the deflecting-shields.
16. The combination, with the arched top and bottom members and downcasts connecting the arches of said members, of cross-tubes connecting said downcasts, substantially as described.
17. The combination, with the top and bottom members, downcasts, and connectingpipes, of the refractory covering resting on said pipes and secured to said downcasts, substantially as described.
18. The top and bottom members, downcasts connecting the same, and cross-pipes and vertical pipes connecting said cross-pipes to the top member, and a refractory covering or casing rest-ing against said vertical pipes and downcasts, all combined substantially as described.
19. The combination of the upper and lower members and downcasts, the refractory casing between the downcasts, the outer covering of said casing, consisting of corrugated plates, and the angle-plates by which said casing is secured to the downcasts, substantially as described.
20. The combination, with one of the boiler members and a box at the side thereof, of 'a tapering pipe extending nearly parallel with said box and connected to the main boiler-sections and to said box by vertical tubes, substantially as described.
21. The combination, with the arched boiler member, the box connected therewith, and vertical tubes leading to said box, of the downcast and branch pipes 51, leading therefrom to said tubes, said pipes composed of a tapering horseshoe-shaped trough, and a fiat flanged cap through which the vertical tubes pass, as set forth.
22'. The combination, with the arched bottom member, the boxes connected thereto, and the downcast and branch pipes, of the vertical tubes connecting said boxes and branch pipes and the refractory casing resting against said vertical tubes.
23. The combination, with the top and bottom members and vertical water-tubes, of a jointed deflecting-plate in said top member, substantially as described.
24:. The steam-boiler described having a shell composed of continuous convoluted plates disposed horizontally and vertically forming similar arches, the concave faces of said arches being toward each other at top, bottom, and sides of the boiler, all secured together and tied in by braces attached so as to draw tangentially on the curved surfaces.
In testimony whereof we affix our signatures in presence of two witnesses.
NATHAN B. CLARK. FRANK B. KING. Witnesses:
WILLIAM W. BROWN, 'JOHN R. FARNUM.
US421387D Peters Expired - Lifetime US421387A (en)

Publications (1)

Publication Number Publication Date
US421387A true US421387A (en) 1890-02-18

Family

ID=2490306

Family Applications (1)

Application Number Title Priority Date Filing Date
US421387D Expired - Lifetime US421387A (en) Peters

Country Status (1)

Country Link
US (1) US421387A (en)

Similar Documents

Publication Publication Date Title
US421387A (en) Peters
US1999984A (en) Steam boiler
US1304499A (en) Charlotta i
US451734A (en) Steam-boiler
US1193304A (en) simonds
US357019A (en) Steam-generator
US797107A (en) Steam-boiler.
US330126A (en) Steam-boiler
US456689A (en) Edward blass
US558778A (en) Steam-generator
US187200A (en) Improvement in sectional steam-boilers
US1096917A (en) Water-tube arch for fire-boxes.
US809518A (en) Marine boiler.
US386526A (en) Steam-boiler
US570229A (en) steam generator
US618770A (en) baumann
US1271634A (en) Hot-water boiler.
US618501A (en) Samuel fraser
US468501A (en) Water-tube boiler
US402127A (en) baie-d
US800906A (en) Steam-boiler.
US544245A (en) Sectional steam or hot-water boiler
US396373A (en) Steam-boiler setting
US402356A (en) Steam boilek
US1064175A (en) Boiler-furnace.