Ufc 4-860-01fa Railroad Design and Rehabilitation (16 January 2004)
Ufc 4-860-01fa Railroad Design and Rehabilitation (16 January 2004)
Ufc 4-860-01fa Railroad Design and Rehabilitation (16 January 2004)
16 January 2004
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Use of the copyrighted material apart from this UFC must have the permission of the
copyright holder.
This UFC supersedes TI 850-02, dated 1 March 2000. The format of this UFC does not conform to
UFC 1-300-01; however, the format will be adjusted to conform at the next revision. The body of
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1
UFC 4-860-01FA
16 January 2004
FOREWORD
\1\
The Unified Facilities Criteria (UFC) system is prescribed by MIL-STD 3007 and provides
planning, design, construction, sustainment, restoration, and modernization criteria, and applies
to the Military Departments, the Defense Agencies, and the DoD Field Activities in accordance
with USD(AT&L) Memorandum dated 29 May 2002. UFC will be used for all DoD projects and
work for other customers where appropriate. All construction outside of the United States is
also governed by Status of forces Agreements (SOFA), Host Nation Funded Construction
Agreements (HNFA), and in some instances, Bilateral Infrastructure Agreements (BIA.)
Therefore, the acquisition team must ensure compliance with the more stringent of the UFC, the
SOFA, the HNFA, and the BIA, as applicable.
UFC are living documents and will be periodically reviewed, updated, and made available to
users as part of the Services’ responsibility for providing technical criteria for military
construction. Headquarters, U.S. Army Corps of Engineers (HQUSACE), Naval Facilities
Engineering Command (NAVFAC), and Air Force Civil Engineer Support Agency (AFCESA) are
responsible for administration of the UFC system. Defense agencies should contact the
preparing service for document interpretation and improvements. Technical content of UFC is
the responsibility of the cognizant DoD working group. Recommended changes with supporting
rationale should be sent to the respective service proponent office by the following electronic
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UFC are effective upon issuance and are distributed only in electronic media from the following
source:
Hard copies of UFC printed from electronic media should be checked against the current
electronic version prior to use to ensure that they are current.
AUTHORIZED BY:
______________________________________ ______________________________________
DONALD L. BASHAM, P.E. DR. JAMES W WRIGHT, P.E.
Chief, Engineering and Construction Chief Engineer
U.S. Army Corps of Engineers Naval Facilities Engineering Command
______________________________________ ______________________________________
KATHLEEN I. FERGUSON, P.E. Dr. GET W. MOY, P.E.
The Deputy Civil Engineer Director, Installations Requirements and
DCS/Installations & Logistics Management
Department of the Air Force Office of the Deputy Under Secretary of Defense
(Installations and Environment)
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TI 850-02
AIR FORCE AFMAN 32-1125(I)
1 MARCH 2000
US Army Corps
of Engineers ®
Technical Instructions
Headquarters
U.S. Army Corps of Engineers
Engineering and Construction Division
Directorate of Military Programs
Washington, DC 20314-1000
CEMP-E TI 850-02
AFMAN 32-1125(I)
1 MARCH 2000
TECHNICAL INSTRUCTIONS
Any copyrighted material included in this document is identified at its point of use.
Use of the copyrighted material apart from this document must have the permission of the copyright
holder.
FOREWORD
These technical instructions (TI) provide design and construction criteria and apply to all U.S. Army Corps
of Engineers (USACE) commands having military construction responsibilities. TI will be used for all
Army projects and for projects executed for other military services or work for other customers where
appropriate.
TI are living documents and will be periodically reviewed, updated, and made available to users as part of
the HQUSACE responsibility for technical criteria and policy for new military construction. CEMP-ED is
responsible for administration of the TI system; technical content of the TI is the responsibility of the
HQUSACE element of the discipline involved. Recommended changes to the TI, with rationale for the
changes, should be sent to HQUSACE, ATTN: CEMP-ED, 20 Massachusetts Ave., NW, Washington, DC,
20314-1000.
TI are effective upon issuance. TI are distributed only in electronic media through the TECHINFO
Internet site http://www.hnd.usace.army.mil/techinfo/index.htm and the Construction Criteria Base (CCB)
system maintained by the National Institute of Building Sciences at website: http://www.nibs.org/ccb/.
Hard copies of these instructions should be checked against the current electronic version prior to use to
assure that the latest instructions are used.
Table of Contents
Page
2. APPLICABILITY 1-1
3. REFERENCES. 1-1
1. INTRODUCTION. 2-1
1. INTRODUCTION. 3-1
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1. INTRODUCTION. 4-1
3. RECONNAISSANCE. 4-2
1. ROADWAY. 6-1
4. CLEARANCES. 6-8
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8. SUBGRADE. 6-20
2. BRIDGES. 7-22
1. INTRODUCTION. 8-1
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FIGURES
Figures Title
2-1 Common freight cars.............................................................................................................2-3
3-1 Combining curves .................................................................................................................3-3
5-1 Example turnout inspection information .................................................................................5-2
6-1 Typical cross section - tangent track......................................................................................6-1
6-2 Typical cross section with sub-ballast layer - tangent track ....................................................6-2
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TABLES
Table Title
2-1 Common cargo types and loading requirements ....................................................................2-2
2-2 Common car types and design wheel loads...........................................................................2-4
3-1 Grade design categories for main running tracks ...................................................................3-1
3-2 Recommended minimum grade lengths.................................................................................3-2
3-3 Curve design categories for main running tracks ...................................................................3-2
3-4 Curve compensation for a 1 percent grade ............................................................................3-4
3-5 Estimating locomotive tractive effort ......................................................................................3-5
3-6 Design gross car weights ......................................................................................................3-6
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6-1 Recommended transition rates between grades on main running tracks ................................6-5
6-2 Design superelevation for curved track..................................................................................6-7
6-3 Overhead and side clearances for tangent track....................................................................6-9
6-4 Clearance increases adjacent to curved track...................................................................... 6-10
6-5 Track center distances ........................................................................................................ 6-11
6-6 Suggested design track modulus values.............................................................................. 6-16
6-7 Rail sections ....................................................................................................................... 6-17
6-8 Recommended ballast gradations ....................................................................................... 6-28
6-9 Switch ties for standard turnouts.......................................................................................... 6-31
6-10 Dimension and surface specifications for relay (secondhand) rail ........................................ 6-33
6-11 Common joint bolt diameters ............................................................................................... 6-37
6-12 Turnout size selection criteria .............................................................................................. 6-43
7-1 Recommended crossing surfaces..........................................................................................7-2
7-2 Clear visibility distance at road crossings............................................................................. 7-21
7-3 Recommended cooper design load for bridges .................................................................... 7-25
9-1 Suggested stake intervals for final survey..............................................................................9-1
9-2 Rail joint gap. ........................................................................................................................9-4
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CHAPTER 1
GENERAL
1. PURPOSE AND SCOPE. This manual provides guidance for design and rehabilitation of railroad
track, terminals, and loading facilities, along with some information on construction.
a. The guidance in this manual is primarily for railroad lines operated at lower speeds and with lower
traffic volumes than those most commonly found in the commercial industry. The guidance on terminal
design is for small terminals handling military cargo: primarily tracked or wheeled vehicles and intermodal
containers.
b. This manual, supplemented with the specified references, should provide sufficient information for
general purposes. Most projects, however, include some aspects that are very site-specific or some
conditions that are not common. Designers are encouraged to obtain assistance when unusual or
unfamiliar situations are encountered.
2. APPLICABILITY. These instructions are applicable to all USACE elements and their contractors
involved with railroad design, construction, and rehabilitation
a. Applying the Material in this Manual. Designing a railroad involves satisfying many objectives that
often conflict. Throughout the process, the designer must prioritize project objectives and decide to what
extent one objective may be sacrificed to satisfy another. It is the proper balance of these compromises,
specifically matched to each situation that produces a good railroad design.
b. New Lines and Terminals. For designing new railroad lines and terminals, chapters 2 through 4 and
6 through 8 of this instruction are required. The design process is summarized in these steps:
(1) Determine the traffic and load carrying requirements. Estimate the number of cars to be handled
over the line and the magnitude of the wheel loads the track must support.
(2) Determine the terminal and support facilities requirements. From the type and magnitude of traffic
to be handled, determine the number, size, and location of loading and unloading facilities (terminals),
sidings, wyes, and other support facilities and auxiliary tracks.
(3) Establish route profile and alignment guidelines. Based on load carrying requirements, maximum
desired speed, locomotive pulling capability, and other operating needs and conditions, select maximum
effective grade, horizontal and vertical curvature, and other profile and alignment specifications.
(4) Select the route. Through an iterative process, select the best route and profile between the
terminals and the connecting commercial carrier (usually the nearest commercial railroad line).
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(5) Design the track, roadway, and terminal and support facilities. From the traffic and wheel load
estimates and the characteristics of the selected route, determine track, roadway, and drainage
requirements.
c. Rehabilitation. For rehabilitating existing lines and facilities, chapters 5 through 8 are required, along
with portions of chapter 2.
5. SUPPLEMENTARY MATERIAL. Listed below are references and other material generally required for
railroad design and rehabilitation. Full citation of references is given in appendix A:
e. Detailed maps (including contour maps) of the area through which the railroad will run.
a. The American Railway Engineering and Maintenance-of-Way Association’s Manual for Railway
Engineering is a standard industry reference and is cited throughout this technical manual. It contains a
wide range of guidance to cover a variety of needs, with emphasis on commercial lines carrying
substantial freight traffic. As a broad range of specifications is often given, proper use of the AREMA
manual requires that the designer select the particular specifications that are most appropriate for a
particular project.
b. The AREMA manual is written primarily for the commercial carriers, that have their own company
policies and procedures. The material was prepared with the assumption that many details need not be
covered, as a company’s own practices would govern. Therefore, it is usually necessary for military
designers to provide details above and beyond the material contained in the AREMA manual. In addition,
requirements for operation on military railroads may sometimes differ from those commonly found on
commercial carriers. In these cases, the design guidance in this technical manual may vary from that
found in the AREMA manual.
c. For these reasons, when preparing designs and specifications, the use of general statements such
as “meeting AREMA specifications” should be avoided. Such statements often leave the choice of
materials or procedures wide open and can lead to an undesirable or unsatisfactory product. Designers
should clearly specify the work to be done and the acceptable materials for use in construction.
a. States often have standards, particularly for clearances, which should be met during new
construction or rehabilitation. These standards may be obtained from the appropriate State departments
of transportation and public utilities.
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b. In addition, designers should assure that any new or rehabilitated track that will be regularly
operated over by a commercial railroad will be in compliance with their track requirements.
8. SOURCES OF ASSISTANCE.
a. Designers are encouraged to call for assistance when questions arise on the best choice to suit a
particular situation or for further interpretation of material in this technical manual or other references.
Assistance may be obtained through the Army Transportation Systems Center, Omaha, NE (CENWO-
ED-TX) or Air Force HQ ARCESA/CESC.
b. Particularly for installations that depend on the connecting commercial carrier for service, either for
routine traffic or only during a mobilization, that carrier should be consulted at least about the
arrangement of the interchange yard and preferably for other suggestions on track arrangement to
promote more convenient service.
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CHAPTER 2
DETERMINING TRAFFIC AND LOAD CARRYING REQUIREMENTS
1. INTRODUCTION.
a. The first step in designing a railroad is to determine the type and volume of traffic to be handled.
Traffic type and volume will generally govern the size and arrangement of terminal facilities, the number
of auxiliary tracks required, and track structure design.
b. The traffic handling capability at an installation must cover existing and foreseeable requirements,
that usually include:
c. Once assembled, data on traffic volume and type should be reviewed and approved before
proceeding with the design process.
d. Height and width of cargo (for clearance requirements) handled on open cars (flatcars and gondolas).
e. Special requirements or restrictions for loading, unloading, or moving the cargo (especially when
handling hazardous cargo).
f. From this information the required type of loading facilities can be determined. Planning and design
for loading facilities are covered in chapter 8. Table 2-1 lists the most common cargo types along with the
freight cars and loading facilities usually required to handle the cargo. Figure 2-1 shows common freight
car types.
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3. TRAFFIC VOLUME. In addition to the type of traffic, the amount of traffic must also be estimated.
This information should include:
a. Maximum number of cars (for each traffic type) that might be on the installation at any one time,
including empty cars.
c. Maximum number of cars (of all types) that might be on the installation at any one time, including
empty cars.
d. Maximum number of cars that each loading facility or terminal area might be required to handle in a
single loading or unloading cycle.
4. WHEEL LOADS.
a. Track structure design is greatly influenced by the magnitude of the wheel loads that the track must
support. While many different types of cars and loadings may be handled aboard an installation, for
planning purposes the design wheel load is based on the heaviest type of loaded car that will most
commonly run over a particular track.
b. In many cases, the wheel loads from an engine (either Army-owned or from the commercial carrier)
will represent the heaviest single load on the track. However, the number of wheels from loaded cars will
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typically far exceed the number of locomotive wheels over much of the track, and it is therefore the
magnitude of the car wheel load that should govern in most cases. In either case, both loading conditions
must be checked before final design.
c. The design wheel load is usually obtained by taking the static wheel load for the heaviest commonly
used car and adding a factor to account for the dynamic affects of travel speed combined with track and
wheel irregularities.
d. Table 2-2 lists suggested design wheel loads for planning purposes. To use the table, select the car
type in the first column that most closely matches the heaviest car in common use over the track. For
terminal areas and around an installation, where speeds will usually be limited to 10 mph, select the
design wheel load in the column labeled “<= 10 mph.” For track connecting the installation with the
commercial carrier where train speed will likely exceed 10 mph, use the column labeled “10-25 mph.” For
track mostly used by an engine during switching, or where mostly empty cars will be stored, or that will
otherwise see only occasional use, select from the column labeled “Light Use.”
Table 2-2. Common Car Types and Design Wheel Loads
Design Wheel Load
Most Common Heavy Car 10-25 mph <= 10 mph Light Use
Box, 40T 20,000 lb 17,600 lb 16,000 lb
Box, 50T 26,250 lb 23,100 lb 21,000 lb
Box, 70T 34,375 lb 30,250 lb 27,500 lb
Flat, 40T 17,500 lb 15,400 lb 14,000 lb
Flat, 50 T 23,750 lb 20,900 lb 19,000 lb
Flat, 80T (6-axle) 23,750 lb 20,900 lb 19,000 lb
Flat, 100T (6-axle) 32,500 lb 28,600 lb 26,000 lb
Flat, 140T (6-axle) 38,750 lb 34,100 lb 31,000 lb
COFC, 70T 30,000 lb 26,400 lb 24,000 lb
COFC-Double Stack 50,000 lb 44,000 lb 40,000 lb
TOFC, 70T 30,000 lb 26,400 lb 24,000 lb
Gondola, 40T High Side 18,750 lb 16,500 lb 15,000 lb
Gondola, 50T 22,500 lb 19,800 lb 18,000 lb
Tank, 7500 gallon 16,250 lb 14,300 lb 13,000 lb
Tank, 10,000 gallon 22,500 lb 19,800 lb 18,000 lb
Tank, 20,000 gallon 36,250 lb 31,900 lb 29,000 lb
Hopper, 50T 21,250 lb 18,700 lb 17,000 lb
Hopper, 70T 30,000 lb 26,400 lb 24,000 lb
Hopper, 100T (263 K) 41,125 lb 36,190 lb 32,900 lb
Hopper, 120T (286 K) 44,750 lb 39,380 lb 35,800 lb
Hopper, 125T (315 K) 49,250 lb 43,340 lb 39,400 lb
Locomotive, EMD GP-7 or 9 37,500 lb 33,000 lb 30,000 lb
Locomotive, EMD SW-8 31,250 lb 27,500 lb 25,000 lb
Locomotive, DAV-BES 80T 25,000 lb 22,000 lb 20,000 lb
Locomotive, GE 65T 20,000 lb 17,600 lb 16,000 lb
Locomotive, GE 40T 13,750 lb 12,100 lb 11,000 lb
Locomotive, GE 25T 31,250 lb 27,500 lb 25,000 lb
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a. Definition. When designing a railroad route, it is necessary to know how much pulling force a
locomotive is capable of exerting. This pulling force is known as tractive effort. Tractive effort is
maximum at starting and diminishes as speed increases.
b. Application. Locomotive tractive effort, along with the route gradient and curvature, will largely
determine how many cars can be pulled over the route in a single train. From another perspective,
locomotive tractive effort and minimum desired train size may determine the maximum grade and
curvature tolerable on a given route.
c. Tractive Effort Data. Tractive effort data (or graphs) are often available for both military and
commercial locomotives. When not readily obtainable, the data can be estimated from the locomotive
weight and engine horsepower rating. This procedure is covered in chapter 3, paragraph 5.
6. TRAFFIC AND TERMINALS. Once the traffic handling requirements have been identified, as
described in chapter 2, paragraphs 1 to 3, the process of designing the terminal and support facilities can
begin. The number and size (or length) of the required facilities and serving trackage is based on these
traffic requirements. Chapter 8 covers planning and design for terminals.
7. SOURCES FOR TRAFFIC INFORMATION. Information about traffic types, car types, and volume,
and mobilization requirements should be obtained from the Installation Transportation Officer (ITO) and
from the installation Transportation System Capability Study prepared by the Transportation Engineering
Agency of the Military Traffic Management Command (MTTE-SEF).
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CHAPTER 3
ESTABLISHING ROUTE PROFILE AND ALIGNMENT SPECIFICATIONS
1. INTRODUCTION.
a. The procedures outlined in this chapter (along with information on locomotive propulsion force,
desired train capacity, propulsion resistances, and train operating requirements) can be used to select the
maximum grade and curvature and minimum transitions between grades and reverse curves.
b. Initially, these specifications should be treated only as guidelines, as analyses of route topography
may require changes to keep construction costs within acceptable limits. Typically, the information and
procedures described in this chapter will be used iteratively with those in chapter 4 until a suitable
compromise is reached.
d. The specifications listed in this chapter are primarily for main running tracks. Chapter 8 gives
additional profile and alignment specifications for terminal areas. Paragraphs 2 and 3 of chapter 6 detail
field layout of horizontal and vertical curves.
a. Definition. Railroad grades are designated by the amount of elevation change in 100 ft of length,
expressed in percent. The additional force required to move a train, due to the presence of a grade, is
known as grade resistance. Grade resistance equals 20 lb for each ton of train weight and percent of
grade. Thus, it takes twice the force to pull a train up a 2-percent grade as it does a 1-percent grade. For
this reason, the choice of maximum gradient (the rate of elevation change on a particular grade) can have
a great effect on operations over a route.
b. Ruling Grade. When a particular grade limits train size (tonnage) and speed over a route, that grade
is known as the ruling grade. The ruling grade is not always the steepest grade, as a train’s momentum
may help carry it over a grade steeper, but shorter, than the ruling grade.
c. Grade Design Categories. Table 3-1 lists grade design categories for main running tracks.
Table 3-1. Grade Design Categories for Main Running Tracks
Grade Description
0.0 to 0.4 % Light
0.4 to 1.0 % Moderate
1.0 to 2.0 % Steep
1.5 % Suggested Limit for Ruling Grades
2.0 to 3.0 % Very Steep: To be avoided if possible
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a. Profile and Grade Length. A route’s profile is characterized by the steepness of grades and changes
in grade along the route. Train operations are enhanced by avoiding frequent changes between
ascending and descending grades (a rolling profile). Route design and construction are often simplified
by avoiding frequent changes in grade steepness. Table 3-2 shows recommended minimum grade
lengths.
Table 3-2. Recommended Minimum Grade Lengths
Between Different Ascending or Between Ascending and
Maximum Speed Descending Grades Descending Grades
15 MPH or Less 500 Feet 1000 Feet
Above 15 MPH 1000 Feet 1500 Feet
(1) Transitions between grades are made with vertical curves. These transitions are necessary for
smooth train operation, but they increase the amount of surveying and staking required and are more
difficult to construct than uniform grades.
a. Minimizing Curvature. In general, sharper curves require more maintenance than gradual curves;
they experience more rail side wear and gage widening. They also create more propulsion resistance.
Thus, long term benefits are gained by minimizing curvature in a route.
b. Curve Design Categories. Table 3-3 shows curve design categories for main running tracks.
Table 3-3. Curve Design Categories for Main Running Tracks
Degree of Curve Design Category
0-3 Gradual.
3-6 Moderate.
4 Preferred limit, especially where speeds will exceed 15 MPH.
6-8 Sharp.
8 Maximum allowable where speeds may exceed 10 MPH.
10 Maximum allowable where speeds will not exceed 10 MPH.
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d. Curve Resistance. Curvature adds to propulsion resistance at an average rate of 0.8 lb for each ton
of train weight for each degree of curve. As a 1-percent grade adds resistance of 20 lb per ton, a one-
degree curve is then equivalent (in resistance) to 0.04-percent grade.
e. Curve Compensation.
(1) When laying out a route, the additional resistance due to curvature must be accounted for in the
design. This procedure is known as curve compensation. Compensating a grade for curvature is almost
always required for ruling grades, and is recommended for grades in moderate and higher categories.
(Curve compensation is sometimes omitted where curves are very short or of gradual degree).
(2) Where curve compensation is needed, grades on curved track will be reduced by the following:
G r = 0 .04 x D Eq. 3-1
(a) Actual and Effective Grade. Table 3-4 illustrates curve compensation for a 1-percent grade. As
shown, if a train travels around a long curve of 4 degrees on a 1-percent grade (uncompensated), the
combined resistance is equal to a 1.16-percent grade. To maintain an effective grade (as experienced by
the train) of 1-percent, the actual grade constructed through the 4-degree curve must be limited to 0.84-
percent. Since the actual grade is reduced, compensating for curvature requires a longer track length to
reach a given elevation.
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a. Definition. The maximum weight of train that a locomotive is capable of pulling over a route is known
as its tonnage rating. Tonnage ratings are affected by many factors, but locomotive tractive effort and
ruling gradient are among the most important.
b. Application of the Procedures. The procedures for estimating locomotive tractive effort and tonnage
ratings presented below are simplified versions intended for route design purposes. They are not
intended to be used for the actual make-up and dispatching of trains.
(1) Tonnage Requirements, Locomotive Assignments, and their Effect on Route Design.
(2) The route must be designed to allow trains of sufficient size to travel over the finished line.
Maximum train size is determined primarily from usable locomotive tractive effort and the gradients and
curvature along the line.
(3) Designers must verify tonnage requirements with the appropriate transportation officers, as well
as understand the general operating plan for routine traffic, training exercises, and mobilization.
(4) On military railroads where government owned and operated engines are used, these engines
might handle all routine traffic, but during training exercises or mobilization, a commercial engine may be
expected to handle over-the-road operations, while the installation’s engine takes care of switching and
short moves. Another option, when installations have more than one engine, is to use two engines for
maximum tonnage trains when such single train movements are required. Thus, in addition to tonnage
requirements, plans for locomotive use must also be known.
(1) Locomotive Capability. When tractive effort curves are available for the locomotives to be used
on the line, tonnage ratings should be based on these curves. Otherwise, tractive effort may be
sufficiently estimated with the expressions in table 3-5.
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(2) Adhesion Limit. Regardless of locomotive power, usable tractive effort is always limited by wheel-
rail adhesion. For design purposes, usable locomotive tractive effort should not exceed W/4, where W is
the weight of the locomotive in pounds.
(1) While tonnage ratings are commonly given in gross trailing tons (total weight of cars and loads), a
convenient practice is to express tonnage ratings as the number of loaded cars a locomotive can pull,
using an average or representative car and load for estimating purposes. This can be done using
equation 3-2, along with table 3-6 for selecting design car gross weight based on the nominal car carrying
capacity.
TE
NCars = Eq 3-1
[3 + ( 20 × %G )] Wg
%G = Maximum ascending gradient long enough to contain the whole train (percent).
The constants 3 and 20 in equation 3-2 indicate that an average car has a rolling resistance of 3 lb for
each ton of its gross weight and that all equipment requires 20 lb to lift each ton of weight up each
percent of grade. Any curvature on the maximum grade is assumed to be grade compensated, as
TE
G= − 0.15 Eq 3-2
20 [ Weng + (Ncars × Wg )]
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(2) For field check, car capacity is normally stenciled on the side of each car in pounds, labeled
CAPY. For example, the marking on a 70-ton car would appear as: CAPY 140000.
a. A trial percentage for the ruling grade can be determined for guiding the first stages of route
selection, using equation 3-3. (The 0.15 constant in the equation indicates that the average rolling
resistance for each car is equivalent to pulling the car up an additional 0.15-percent grade).
G= TE
20(WEng + Ncars x Wg )
− 0.15
Eq 3-3
G = Effective ruling gradient (percent), where the grade length is equal or greater than train
length.
TE = Usable locomotive tractive effort (pounds).
W Eng = Weight of Engine(s) (tons).
b. All curvature within the limits of the ruling grade should be grade compensated, as described in
paragraph 4 of chapter 3.
c. A ruling grade that is steeper, but shorter, than the calculated ruling grade can also be used as long
as the total train resistance of the cars on the grade and the cars off the grade does not exceed usable
locomotive tractive force.
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CHAPTER 4
ROUTE SELECTION
1. INTRODUCTION.
a. This chapter describes the process of selecting the route for the track connecting the terminal
facilities with the commercial railroad serving the installation.
b. The location process begins by roughly defining potential routes or areas through which a railroad
might practically run. Additional and more detailed information is then collected, and the route
alternatives are gradually reduced until the final route is chosen. Before this process begins, the initial
location and orientation of terminal facilities (as described in chapter 8) should be completed.
(5) Most conveniently serves the installation and all terminal areas, as well as connecting carriers.
(6) Causes the least interference with other activities and modes of transportation.
d. Since the above-listed objectives often conflict, the engineer’s job is to determine the appropriate
compromises that will produce the best route under the circumstances the one that best meets all
objectives.
e. If initial line locations prove unsatisfactory in some important aspect, it may be desirable to look for a
different terminal location or to re-orient a terminal so that the line can serve it from a different direction.
f. Throughout the route selection process, it is essential to have good maps (including contour maps) of
the area through which the railroad may run. If not currently available, these should be obtained as the
first step.
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a. Control points serve to limit location alternatives. They represent places through which the railroad
must pass or would ideally pass.
b. The most obvious control points are end points: the terminals and the connections with the
commercial railroad. Intermediate control points may be established by facilities or geographic features
that must be avoided, such as firing ranges, areas that cannot be drained well, or environmentally
sensitive areas. Control points can also be places that offer significant construction and operating
advantages, such as narrow or shallow river crossings and areas with naturally good drainage.
c. After control points are marked on contour or aerial maps, approximate boundaries of potential route
corridors are sketched. More control points, and other information needed to define a specific route, are
identified during the next stage (reconnaissance).
3. RECONNAISSANCE.
a. The reconnaissance is a quick examination of a wide strip of land between control points the strip
representing rough boundaries of a potential line location. Several routes (or alternatives for portions of a
route) may be examined.
b. The purpose of a reconnaissance is to identify routes that might allow the easiest construction effort
consistent with the purpose and requirements of the railroad.
c. Contour maps, aerial photographs, and previous survey information are good sources to use during
the reconnaissance. A small set of maps and diagrams (with control points and potential routes
identified) is convenient for field use. The information gathered during the reconnaissance can then be
transferred to larger maps and computer files back in the office.
d. The reconnaissance may be done by any means appropriate for the terrain and distances to be
covered: walking, driving, or from the air. Generally, take note of terrain features and anything that might
affect route location and construction. Look especially for:
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(9) Potential for future additions to the railroad (as per the Installation Master Plan).
e. Snow conditions along the proposed routes should be observed for at least one winter to identify
locations where drifts form. Winter aerial photographs may also be helpful for this purpose. Sites
downwind of frozen lakes should be avoided unless there is adequate room between the shore and the
roadway to install snow fences.
f. After the reconnaissance has been completed, prepare maps showing all control points and potential
alternative routes. Then, make general comparisons between the routes with respect to length, grades,
curvature, relative amount of earthwork and drainage work required, bridge work, special construction
requirements, and potential operating advantages and disadvantages.
g. If sufficient information is available at this point, recommend the best route; otherwise, prioritize the
routes. Also note any special requirements for the initial survey.
4. INITIAL SURVEY.
a. The objective of the initial survey is to obtain sufficient information to allow preparation of initial
earthwork and construction estimates and to establish a location for the track and drainage paths on
maps back at the office. When the route choice is clear from the reconnaissance, the initial and final
surveys are often combined.
b. The initial survey is done by approximating the routes as a series of tangents, taking elevations and
cross section data at selected intervals (perhaps every 100 to 250 ft) along the route. Generally, where
terrain is fairly uniform, the longer survey intervals can be used. Elevations and cross section data should
also be taken at points representing a rapid change in terrain or at other points of special interest that
may be useful to aid construction estimating. All useful landmarks should also be tied into the survey.
Stakes need to be driven in sufficient number to clearly show the survey centerline - about every 200 to
400 ft.
c. For cross sections (nearby elevations at right angles to the route), simply take elevations at points
that will show the shape of the adjacent terrain - local peaks, low points, and other points of special
interest. The width of the required cross section will be dictated by the character of the terrain, right-of-
way ownership, and distance needed to show local drainage and topographical features. It is not
necessary for cross sections to be of equal distance on each side of the route centerline or of equal width
at each station along the route.
d. Where terrain is open (and easily accessible) cross section data is often taken from 300 to 500 ft on
each side of the route centerline. In areas where the route location is fairly well defined, cross sections
may be much narrower; sometimes only a 50-ft wide strip is needed. The situation should govern the
choice of width.
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e. When approaching points where a change in direction will occur, it will often prove useful to take an
extra wide cross section on the inside of the angle, as a curve must eventually connect the two tangents
through this area.
f. During the initial survey, be sure to take sufficient information to establish drainage paths on both
sides of the track. Also note paths that drain runoff into the right-of-way as well as outlets where water
can exit the right-of-way to nearby streams, drop inlets, or other runoff channels.
5. TRIAL LOCATION.
a. Trial location is the process of determining potentially practical routes (trial routes) through a
particular area. The objective of trial location is to produce the best combination of tangents, curves, and
grades for the routes surveyed. This is done by combining survey information with design and economic
guidelines, operating requirements, and engineering judgment. During this process, many factors must
be weighed and prioritized, and conflicting objectives must be balanced.
b. After the first trial routes are located, construction estimates are made. Then, the location (of the
track or drainage path) is usually modified in an attempt to reduce construction cost (while still
maintaining satisfactory operating characteristics) or to improve operating characteristics (while keeping
construction costs at a reasonable level). Adjustments are made to each route until the most satisfactory
set of compromises has been produced.
c. For track through an installation or in a terminal area, this process can usually be simplified and done
with fewer iterations. Likewise, the construction estimates might be done only once.
d. Trial location begins by lightly sketching the boundaries of the initial survey on a contour map. The
first trial route drawn through this strip is often done by minimizing grades, or in flatter territory, by
minimizing the number of curves needed. As with the initial survey, the route begins as a series of
connected tangents, with curves chosen and drawn in later.
e. After the route is sketched, a profile is drawn. The elevations of the railroad come from the
elevations of end and intermediate points and the different grades chosen between these points. The
elevations of existing ground level are obtained by approximating the point where the route would pass
through each cross section taken in the initial survey. When an initial survey is not done, the ground
elevations are taken from the points where the route crosses map contours.
f. With the trial routes drawn, earthwork and construction estimates are made using standard
procedures. At this stage, embankment and cut widths and slope angles may be estimated using the
typical roadway cross sections in chapter 6, paragraph 1. If one route does not yet appear clearly
superior, an additional iteration of modifications and analysis may be needed to produce the final location.
6. FINAL LOCATION.
a. To finalize the route selection, modifications may be made to the trial routes in an attempt to even cut
and fill amounts in adjacent areas or to reduce the total earthwork and grading required.
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b. Where grades or curvature exceed the most desirable limits, the routes should be modified, if
feasible, to reduce these. The criteria listed in chapter 4, paragraph 1, should also be reviewed for each
trial route.
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CHAPTER 5
REHABILITATION: TRACK, BRIDGES, AND TERMINALS
a. As used here, “rehabilitation” refers to work that falls between routine maintenance and new
construction. It is often categorized as repair, minor construction, or a combination of the two.
Rehabilitation involves restoring facilities to a “like new” condition and/or upgrading existing facilities to
current design standards or installation requirements.
b. During the planning process, current and future installation requirements should first be clearly
established. If subsequent investigations and analyses show that existing facilities could meet installation
requirements through improving their condition and/or minor modifications, then rehabilitation is an
appropriate option.
a. Installation traffic and load carrying requirements should be reviewed, as described in chapter 2.
Then, structural and operational requirements should be checked according to the criteria in chapters 6,
7, and 8.
b. The purpose of evaluations should be to determine whether the track and facilities meet installation
(mission) requirements, and if not, in what respect they are deficient. These determinations are made
through condition, structural, and operational evaluations.
3. CONDITION EVALUATION.
a. Level of Detail Required. Condition evaluations may occur in three stages or levels, depending on
the size and scope of the project:
(1) At the first stage, a quick condition assessment may be appropriate, based on recent inspection
reports and inventory information and a brief field survey. This assessment may be used to establish a
general need for rehabilitation.
(2) The second stage may be an evaluation for developing a rehabilitation plan. This information will
be sufficiently detailed to determine what work needs to be done at which locations, and to develop cost
estimates for planning and budgeting purposes.
(3) At the third level, exact work requirements, quantities, and locations are determined for final
contract plans and specifications.
b. Track.
(1) Track condition evaluation should be based on the criteria given in Army TM 5-628/Air Force
Regulation 91-44 as well as other major rehabilitation requirements. The evaluation should also allow for
major deficiencies that are likely to occur within the next 3 to 5 years if rehabilitation is not performed.
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(2) Current track deficiencies should be recorded on a field report form. Figure 5-1 shows an
example of the type of turnout inspection information commonly collected. Other available forms,
designed for routine maintenance requirements, may be used if convenient.
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(3) If records of an internal rail inspection are more than 3 years old, a new inspection should be
made before the rehabilitation plan is completed.
(4) All turnouts in the track intended for rehabilitation should receive a thorough inspection, including
operating the points.
c. Bridges.
(1) Railroad rehabilitation plans will include a condition assessment of the bridges on any line to be
rehabilitated. This assessment may come from the last annual inspection, if that inspection is less than 6
months old. Otherwise, a new condition assessment will be done.
(2) If a triennial inspection is due within 6 months for any bridge on a line to be rehabilitated, the
triennial inspection and load rating (per chapter 5, paragraph 4) will be done as part of the rehabilitation
plan.
(3) If the last annual inspection indicates any significant change in condition of a main bridge member
since the previous load rating was done, at least the included span (or spans) of the bridge will be
thoroughly inspected and load rated (per chapter 5, paragraph 4) as part of the rehabilitation plan.
d. Terminal and Support Facilities. The condition of all terminal and support facilities should also be
evaluated. This evaluation may be done and reported separately from the track evaluation.
4. STRUCTURAL EVALUATION.
a. To determine current load carrying capacity, a structural evaluation will be performed for all track,
bridges, loading ramps, and other structures needed for railroad and terminal operations.
b. Track structural evaluation should be done using the computer program described in appendix C.
c. Bridges.
(1) The load-carrying capability of a railroad line is often determined by the design capacity and
present condition of the bridges along the route.
(2) All bridges that have not been thoroughly inspected and load rated within the previous three years
will be examined and rated by a practicing railroad bridge engineer. The rating will be done in
accordance with the AREMA manual for timber bridges, concrete bridges, and steel bridges.
(3) Most military railroad bridges are of conventional timber design, built to an E60 rating. If these
bridges are in very good condition, this capacity is sufficient for typical military traffic levels, including
handling of 140-ton heavy equipment flatcars.
(4) By the AREMA rating guidelines, the in-service rating for bridges in very good condition may
actually exceed their design rating.
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5. OPERATIONAL EVALUATION.
a. To determine general suitability for mission requirements, an operational evaluation will be performed
on track and facilities. This evaluation should begin with a check of track and facility capability as well as
basic geometric requirements, including:
(1) Number of loading and service tracks, along with usable car capacity of each.
(3) Clearances.
b. For terminals, the adequacy of lighting, service roads, and security features should be evaluated.
d. Previous derailment sites and chronic problem areas should be included in the evaluation.
a. Purpose and Content. The rehabilitation plan is used, in part, to justify the need for the
recommended work. Thus, it should demonstrate a thoughtful analysis of the existing facilities combined
with a clear understanding of mission requirements. The plan should include:
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(4) A work plan of remedial actions to correct deficiencies, including an explanation of why the
proposed actions were chosen over other alternatives.
(5) Cost estimates for each item in the work plan. Each of these items is discussed below. Appendix
C contains an example track rehabilitation report; a similar format would also be used for bridges and
terminal and support facilities. Appendix C presents realistic rehabilitation requirements and illustrates
how track rehabilitation is commonly done. This plan, and particularly the sequential description of work,
should be studied and used as a guide in preparing track rehabilitation plans.
b. Mission Requirements. These are the current and expected future needs for regular traffic, training
exercises, and mobilization, including amount and type of cargo, number and type of railroad cars to be
handled, and terminal and support facilities requirements.
(1) This includes a written description of facilities and their condition, along with track maps and
photographs.
(2) If not previously done, each track, bridge, and turnout should be assigned a unique number (or
other designation). Each track should be marked with standard surveyor’s stationing to help determine
work and material quantities (from track lengths) and work locations, and to provide permanent reference
location marks for future track inspections. In general, track stationing should start with 0+00 at the point
of the switch where the track branches from the main track, or for a main track, at the point where
government ownership begins (at the connection with the serving commercial carrier).
d. Deficiencies List and Analysis. This section should include a description of the major deficiencies
found and an explanation of how these conditions interfere with, or prevent, the facilities from effectively
supporting the required mission. As part of this explanation, a comparison of the existing facilities to
recommended design criteria can be useful. Photographs should also be included to help document
deficiencies.
e. Work Plan.
(1) The work plan includes a listing of recommended remedial actions for correcting deficiencies,
along with a list of the intended work limits. This section of the rehabilitation plan should also clarify why
these actions were chosen, and where appropriate, what advantages and benefits they have over other
alternatives. For example, when a structural analysis indicates the need for a heavier rail section,
eliminating the lighter rail often allows the installation to standardize with only one or two rail sections,
thus requiring fewer sections to be kept for maintenance requirements and perhaps eliminating a section
for which joint bars (or additional pieces of rail) are hard to find.
(2) If the rehabilitation plan will also serve for final plans and contract specifications, then the work
plan must include all details of work to be done.
(3) Where appropriate, plans should also allow for the elimination of unneeded track, the possibility of
re-using track materials elsewhere within the installation (where traffic and structural requirements are
lower), and the cost-effective sale, transfer (to another installation), or disposal of scrap and salvageable
materials.
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(4) For rehabilitation, track should be regaged if the existing gage is less than 56-1/4 in. or greater
than 57 in.
f. Cost Estimates. For plans for major rehabilitation, cost estimates are usually based on costing the
major work items, with extra allowances for minor work at other locations and additional minor work within
the major work locations or work categories. When the rehabilitation plan is done in one stage, the cost
estimates must also serve for the contract plans and specifications. In this case, the cost estimate
breakdown must be more detailed.
a. Detailed Work Plan. For final (contract) plans and specifications, all work must be spelled out in
detail. If not previously done, thorough inspections should be conducted for all included facilities to
assure correctness of work requirements, work locations, and work and material quantities.
b. Marking Parts to be Replaced. At this time, all ties, rail, joint bars, bridge members, and other
components intended for replacement should be individually marked, as well as the limits for all work
locations. When marking defective parts, especially ties, bridge members, switch points, and frogs, those
items that are in marginal condition (less than 3 to 5 years additional life) should also be included (and
marked) for replacement.
c. Top-of-Rail Profiles.
(1) When ballast is added to the track, and the track is to be raised by 3 in. or more, top-of-rail
profiles (elevations along the top of the rail at 50 to 200-ft intervals) should be taken so the final surface
can be checked. These profiles will also help in estimating ballast quantities; this is especially useful if
existing track surface is poor, as many low areas will likely need to be raised more than average to
restore a smooth final surface.
(2) Initial top-of-rail profiles may be useful for track along loading docks to ensure proper car floor
height at the dock.
(3) Top-of-rail profiles should be taken wherever overhead clearances are tight.
d. Drainage Profiles and Cross Sections. Before final plans and estimates are made, ditch profiles and
cross sections should be taken to determine final ditch gradients and check earthwork quantities. These
profiles are also needed to specify the exact work to be done and to guide the contractor’s work in the
field.
(1) Rehabilitation contracts and specifications should require that scrap rail and other track materials
be neatly stacked and/or bundled in a designated storage area for later disposal. Likewise, salvageable
rail and OTM should be separated by type and weight, stacked or containerized, and stored in a
designated area for reuse by the installation or shipment to another installation.
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(2) If scrap materials are to be retained by the contractor, a cost credit for the amount of scrap should
be received by the government. This cost credit should equal the fair scrap value less a small amount for
handling and transporting the material.
a. Quality on-site inspection, during all remedial work, is an essential element for a successful track
rehabilitation. While such inspection is certainly no substitute for professionally done track work, it is an
effective means of assuring that all work is, in fact, performed according to the contract specifications.
b. On-site inspection during rehabilitation work can discover deficiencies or errors that would be difficult
to detect during a completion inspection, or expensive to correct if discovered only after work was
completed. Such items include:
(1) Was all excess vegetation removed before ballast was unloaded?
(2) Where track in crossings was to be completely rebuilt, was the old ballast completely stripped?
Was the subgrade properly graded? Was drainage fabric installed? Were all new ties installed?
(3) Did the track actually receive a full 3-in. raise (or were the rough spots just smoothed out)?
(4) Was every tie tamped/? Did each tie get two insertions by the tamper? Did joint ties (on the joint
side only) get an additional (third) insertion? Likewise, correcting the following items after the work has
been done would be difficult, at best:
(b) Old, fouled ballast in shoulders not fully plowed out before new ballast was unloaded.
(c) Culvert improperly positioned, or site not graded properly before culvert was installed.
c. It is recommended that the work be inspected by the same people who did the design and
specifications.
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CHAPTER 6
TRACK AND ROADWAY DESIGN
1. ROADWAY.
a. Definition. The roadway (also called right-of-way) is the strip of land containing the track, ditches,
and other facilities needed for the operation of the railroad.
b. Roadway Width. The roadway must be wide enough to accommodate the track, side ditches,
portions of embankment or cut slopes, parallel service roads, and other structures and facilities necessary
for the operation of the railroad. The roadway must also allow sufficient clearances between the track
and adjacent structures, as covered in chapter 6, paragraph 4. Figures 6-1 through 6-7 indicate the width
required for the basic track structure.
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Figure 6-2. Typical Cross Section With Sub-ballast Layer - Tangent Track
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Figure 6-4. Typical Cross Section With Sub-ballast Layer - Curved Track
Figure 6-5. Typical Cross Section - Track with Adjacent Service Road
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Figure 6-7. Typical Cross Section with Sub-ballast Layer - Track with Geotextile
c. Snow Allowance. In areas with heavy snowfall, additional roadway width (or ditch width) may be
useful to provide sufficient room for snow plowed from the track.
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a. Grades. Chapter 3 gives gradient criteria for main running tracks. Chapter 8 gives gradient criteria
for terminal areas.
b. Vertical Curves. Vertical curves are required as a transition between different grades. Transition
rates are different for summits and sags. Here, summit refers to a convex curve where an ascending
grade changes to a flatter grade, where a descending grade changes to a steeper grade, or where an
ascending grade changes to a descending grade. Sags are concave curves that occur where an
ascending grade changes to steeper grade, where a descending grade changes to flatter grade, or where
a descending grade changes to an ascending grade. (Note: It is best to avoid locating turnouts in vertical
curves). Table 6-1 shows recommended transition rates between grades. The length of track required
for these transitions is determined from equation 6-1.
G1 − G2
L= x 100 Eq 6-1
r
Table 6-1. Recommended Transition Rates Between Grades on Main Running Tracks
Summits Sags Operating Application
0.1 0.05 Average rate where speeds will exceed 15 MPH and right-of-way length is
ample.
0.2 0.1 Average rate where speeds will not exceed 15 MPH or where transition length
is limited.
0.3 0.15 Maximum rate where speeds will exceed 15 MPH.
0.4 0.2 Maximum rate where speeds will not exceed 15 MPH.
Notes: (1) Figures in table are given as percent change in grade per 100 feet of track length.
c. Track Profile. On either main running tracks or terminal tracks, a rolling profile (frequent changes in
gradient) in the roadbed or in the final track surface (top of rail elevation) is undesirable. The criteria in
table 3-2 should be followed to maintain an acceptably smooth track profile.
d. For auxiliary tracks, gradient criteria given in chapter 8, paragraph 3 may be used.
L = Length of track required for vertical curve (ft).
G1 and G2 = Slope of the two adjacent grades (percent), where ascending grades have a positive
value and descending grades have a negative value.
r = Rate of change in grade in 100 ft. (For main running tracks, use table 6-1. For
terminal tracks, also see chapter 8, paragraph 3).
3. HORIZONTAL CURVES.
a. Definition. Railroads are laid out with circular curves using the chord definition. Curvature is
measured in degrees, as indicated in equation 6-2.
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D =
R Eq 6-2
D = Degree of curve (decimal degrees).
R = Radius of curve (feet).
b. Design Criteria.
(1) Design categories for curves on main running tracks are shown in table 3-3; for terminals, also
use chapter 8, paragraph 3.
(2) During the design of major track rehabilitation projects, it is recommended that, where practical,
existing curvature above 10 degrees for main running tracks and 12 degrees in terminal areas be reduced
below these limits.
c. Minimum Tangent Length between Reverse Curves. When curves of different directions immediately
follow each other (reverse curves) there must be a length of tangent track between the two curves to
avoid train operating difficulties. The minimum tangent lengths between reverse curves are:
d. Super-elevation.
(1) For either new design or major rehabilitation, the outer rail in curves should be elevated above the
inner rail by the amount shown in table 6-2. Designs should not call for a combination of speed and
curvature that fall below the bottom-stepped ledger line in the table.
(2) Full super-elevation must be provided around the entire curve. For curves with 1-in. super-
elevation, that elevation may be run out (transitioned back to level) in 40 ft of tangent at the beginning and
end of the curve. Where super-elevation is more than 1-in., spirals will be provided at each end of the
curve.
e. Spirals.
(1) When used, spiral transition curves will be designed as shown in chapter 5, part 3 of the AREMA
Manual. Super-elevation will uniformly increase from zero at the beginning of the spiral (at the tangent) to
the full elevation at the end of the spiral (where full curvature is reached).
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f. Increase in Gage on Very Sharp Curves. Where curves of 12 degrees or more cannot be avoided,
finished track gage will be as follows:
4. CLEARANCES.
a. Clearances will be Checked. For either new construction or rehabilitation work, the location and
position of all tracks will be checked for proper clearances before the final design is prepared and after
construction is complete. Allowances will be provided for future track surfacing (adding ballast and
raising track) and for small changes in alignment during maintenance.
b. Recommended Minimum. Minimum clearances are shown in figure 6-8 and table 6-3. Vertical
clearances are measured from the top of the rail, and horizontal clearances are measured from the center
line of track.
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0 to 750 volts 28 ft
750 to 15000 volts 30 ft
Exceeding 15000 volts 33 ft
Other overhead wires 28 ft
Building entrances (including engine-houses) 18 ft
Overhead bridges 23 ft
Other overhead obstructions 23 ft
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c. State Requirements. Each State has legal requirements for railroad clearances. These are
summarized in a table in chapter 28, paragraph 3.6 of the AREMA Manual. Where a State requires
greater clearances than shown in figure 6-8 or table 6-3, the State requirement will be met.
d. Curved Track. For each degree of curvature, side clearances will be increased 1-1/2 in. over that
required in figure 6-8 and table 6-3. When an obstruction is located adjacent to tangent track, but the
track begins to curve within 80 ft of the obstruction, the side clearances shall be increased by the
amounts shown in table 6-4.
e. Minimum Track Centers. The recommended minimum distance between the center lines of adjacent
tracks is given in table 6-5. Where M1 tanks are handled, increase track center spacing by 1 ft.
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(1) Figure 6-9 shows how to determine the location of clearance points at turnouts, ladder tracks, and
rail crossings. As no car or piece of equipment may be left standing on a track with any part of it
extending past the clearance point (toward the track junction), the clearance point will determine the
usable length of sidings, loading, yard, and storage tracks.
(2) Clearance points will be marked by a 12-in. yellow bar painted on both sides of the rail base.
(3) If derails are used, they must be set to derail equipment before it reaches the clearance point.
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5. TRACK STRUCTURE.
a. Design Objective. Among its various functions, the track system serves to distribute the large,
concentrated wheel loads longitudinally, laterally, and vertically away from the wheel contact area on the
rail surface. A well designed, constructed, and maintained track will distribute the loads in a relatively
uniform fashion, with each component supporting its share of the load. The role of the designer is to
select a track structure (or changes to an existing track) so that the intended wheel loads will be properly
supported, without overstressing any of the four main track system components: rail, ties, ballast, and
subgrade.
b. Load Distribution. As figure 6-10 shows, when a wheel is centered over a tie, the tie directly beneath
the load will generally carry less than half of that wheel load, with the remainder supported by two ties on
either side. Beneath the wheel, the pressures are distributed (reduced) approximately as shown in figure
6-11. With a wheel-rail contact area of about ½ sq in., stresses are reduced from 60,000 psi at the top of
the rail to about 10 psi at the depth of the subgrade surface. While the actual load and pressure
distributions will vary with wheel load, track design, and track condition, the two figures illustrate a realistic
case for good track.
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c. Behavior under Load. It is important to note that, while track construction is relatively simple, its
behavior under load is not. An improvement (or increase in strength) in one track component may cause
an increased load on another. It is not uncommon for an improvement (or increase in strength) of one
track component to cause an increased load on another.
a. Computer Program Available. A computer program for basic track structure design, called TRACK, is
available through the PCASE Internet Site (http://pavement.wes.army.mil/pcase.html) or the Army
Transportation Systems Center (CENWO-ED-TX). Its use is recommended.
b. Manual Design Procedure. If computer programs are not accessible or if a computer is unavailable,
the design procedure in paragraph 7 may be used as an alternative. A disadvantage of this method,
however, is that very little data exists to correlate the value of track modulus with the properties of
individual rail support components: ties, ballast, and subgrade.
(1) The AREMA method leaves several choices and judgments open to designers, to be set
according to situation and policy. And like most AREMA criteria, the method is also oriented toward those
commercial lines that carry medium to heavy traffic volumes (more than 10 million gross tons per year)
and operate at medium or higher speeds (more than 40 mph).
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(2) The guidance below is based on recognizing that most military track operates at relatively low
traffic volumes (less than 5 million gross tons per year) and at relatively low speeds (less than 25 mph),
and uses jointed, rather than continuously welded, rail.
(3) For unusual cases where yearly traffic frequencies are expected to exceed 5 million gross tons,
designers may follow the method directly from chapter 16 of the AREMA Manual.
(1) The AREMA track design method is based on extensive field and laboratory testing conducted
between 1914 and 1940. The committee supervising the tests and evaluations was led by Professor
Arthur Talbot of the University of Illinois, whose name is often used when referring to the tests and
findings.
(2) One of the Talbot Committee’s findings was that, when subject to a large number of load
repetitions (“millions of groups of car wheels”), the greater the vertical rail deflection under those loads,
the faster the track condition deteriorated. From the data and observations collected, the AREMA then
developed a track design method based on limiting or controlling vertical rail deflection.
(3) Figure 6-12 illustrates the general relationship between track deflection and track performance
over long time periods. The design criteria in this section are based on limiting the deflection of main
running tracks to 0.3 in. and of auxiliary, storage, spur, and light use tracks to 0.4 in.
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(4) The AREMA track design method uses the beam-on-elastic-foundation model. In this model, the
track has two components: the beam, which is the rail, and the elastic foundation, which represents
everything below the rail combined. The basic expression in the model relates three main variables: the
load on the rail, the stiffness of the track system, and the amount of vertical rail deflection, as shown in
equation 6-4.
P
Y=
(64 EIu 3 )0.25 Eq 6-4
In this equation, EI represents the stiffness of the “beam” and u the stiffness of the “elastic foundation.”
(1) Select the design wheel load from table 2-2, based on the most common, heaviest car expected
to travel over the track.
(2) Figure 6-13 shows the two most common wheel configurations. Most cars have two-axle trucks
and the design wheel configuration is that in drawing (a), with an average 75-in. wheel spacing. The 140-
ton series flat cars (for carrying M-1 tanks and other heavy vehicles) and some 100-ton flat cars have 3-
axle trucks; their design wheel configuration is that in drawing (b), with 66-in. wheel spacing.
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(3) The track is evaluated assuming that a wheel is centered over a tie, with an adjacent wheel on
either side contributing to the loads, deflections, and stresses as occurs when two cars are coupled
together. Referring to figure 6-13(a), the maximum tie, ballast, and subgrade loads will occur under
wheels one and four (counting from the left), while the maximum rail bending stress will occur at wheels
two and three. For the wheel configuration in figure 6-13(b), the maximum tie, ballast, and subgrade
loads will occur under wheels two and five, while the maximum rail bending stress will occur at wheels
three and four.
(4) The effect of wheels farther than 100 in. from the design wheel is negligible.
d. Select Trial Track Modulus (u). The track modulus values listed in table 6-6 are suggested starting
points for design. In the table, track type “main” refers to main running tracks, while “auxiliary” includes
sidings, wyes, loading, spur, storage, interchange, and light use tracks.
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(2) Select a rail section from table 6-7 of equal or greater weight than calculated above.
(1) The moment and loading coefficients account for the affects of wheels adjacent to the design
wheel. Adjacent wheels reduce rail moment and increase tie, ballast, and subgrade load.
(2) Calculate X1 using equation 6-6. (X1 should normally range between 28 and 40):
I
x1 = 82 4
u Eq 6-6
X1 = Distance from design wheel load to point of zero bending moment (inches).
I= Vertical moment of inertia of rail section (in.4).
u= Stiffness of rail support, or track modulus (psi).
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(a) For most design situations, and for cars with either 2-axle or 3-axle trucks, the rail moment
coefficient (Cm) can be taken as 0.8.
X1 = 28 30 32 34 36 38 40
Design 66: 1.24 1.30 1.36 1.44 1.54 1.62 1.70
Wheel Spacing 75: 1.08 1.15 1.22 1.30 1.36 1.42 1.50
g. Check Rail Bending Stress. Use equation 6-7 to check that rail bending stress is less than 32,000:
(0.318 Pd Cm X1 )
fo = Eq 6-7
Zb
Cm = Moment coefficient.
(1) Choose a trial tie spacing and calculate the maximum rail seat load using equation 6-8:
0.39 Pd Cd S
qo =
X1 Eq 6-8
qo = Maximum rail seat load (lb).
(2) Select tie size, either 6-in. x 8-in. x 8.5 ft, or 7-in. x 9-in. x 8.5 ft.
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(3) Check tie bending stress using equation 6-9a or 6-9b, and ft = 1100 psi as a suggested limit:
qo
For 6 x 8 Ties : ft = Eq 6-9a
29
qo
For 7 x 9 Ties : ft = Eq 6-9b
52
ft = Flexural stress on underside of tie below rail seat (psi).
(4) If ft > 1100, choose a larger tie size or decrease tie spacing.
(1) Determine ballast surface stress from equation 6-10, with pm = 65 psi as a suggested limit:
qo
pm =
Ab Eq 6-10
pm = Ballast surface stress (psi).
(2) If pm exceeds 65 psi, choose a larger tie and/or decrease tie spacing.
(3) Select design subgrade bearing capacity (pc) according to results of soil tests or other data. (In
the absence of other guidance, the design bearing capacity for cohesive soils may be the same as the
unconfined compressive strength).
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8. SUBGRADE.
a. Subgrade Stability and Track Performance. The subgrade is the prepared earth on which the
railroad ballast section and track structure are built. If the subgrade does not have sufficient stability, it
will be impossible to maintain proper track alignment, profile (surface), and cross level.
b. Soil Investigation. Prior to initial design of the track structure, a geotechnical investigation should be
performed along the proposed alignment to determine soil type, strength, bearing capacity, location of
groundwater tables, natural water content, and compaction characteristics. Additional geotechnical
borings, laboratory testing, and engineering analysis will be required in areas where bridges or other
special structures are to be constructed. Chapter 1, part 1 of the AREMA Manual provides
recommendations for geotechnical investigations.
c. Design of Cuts and Fills and Subgrade Preparation. Chapter 1, part 2 of the AREMA Manual
provides recommendations for design of cuts and fills and subgrade preparation. Table 1.2.5 of the
AREMA Manual indicates soils types and their suitability as railroad subgrades.
d. Track Structure Design Bearing Capacity - Cohesive Soils. For cohesive soils, and for track
expected to carry the usual military traffic level of less than 5 million gross tons per year, design bearing
capacity for the track structure may be set at the soil’s unconfined compressive strength at its natural
water content. For unusual cases, where annual traffic volumes are projected at higher than 5 million
gross tons, 80 percent of the unconfined compressive strength may be used as the design bearing
capacity.
e. Soil Stabilization. Information on the use of soil stabilization and the design and construction of soil
stabilized subgrades is presented in TM 5-822-14/AFMAN 1019. Especially in frost areas, soil stabilizers
should be used with caution and only after intensive laboratory testing, including a frost susceptibility test
and a freeze-thaw durability test.
a. Frost Heave Conditions. Frost heaving is the rising of the soil due to the growth of ice lenses or ice
segregation during freezing. There are three basic conditions that must be present for ice segregation to
occur: a frost susceptible soil, a source of water, and freezing temperatures. A change in any of the three
conditions will affect the amount of heave.
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b. Identifying Frost Susceptible Soils. For design purposes, the potential for ice segregation is often
expressed as a function of grain (or particle) size. Most organic, non-uniform soils containing 3 percent or
more by weight of particles smaller than 0.02 mm are considered frost susceptible. Gravel, well graded
sands and silty sands (especially those approaching the theoretical maximum density curve) that contain
1.5 to 3 percent of particles smaller than 0.02 mm should be considered possibly frost susceptible and
subject to laboratory frost-susceptibility tests. Considerable ice segregation can be expected in uniform
sandy soils with greater than 10 percent smaller than 0.02 mm. Figure 6-14 illustrates a method for
determining the frost susceptibility of soils.
Figure 6-14. General Method for Determining the Frost Susceptibility of Soils
c. Water Source. Usually, the water source will be an underlying groundwater table, a perched aquifer,
or infiltration from the overlying layers.
d. Frost Depth. Future track maintenance costs are reduced if the design depth of frost below the top of
the ballast is at least 60 percent of the expected local frost depth. The expected frost depth should be
established using local records, experience or building practices. If these are unavailable, use the
procedures in TM5-852-6/AFP 88-19, chapter 6.
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(1) This procedure may only be used for fine grained soils of relatively uniform composition at
different depths.
(2) Determine the Air Freezing Index - the number of degree days (above and below 32 °F) between
the highest and lowest points on the cumulative degree day curve for a freezing season. For the design
air freezing index, use the 3 coldest years in the last 30 years of record, or use the average index and
multiply it by 1.75. (If fewer than 30 years of data are available, the air freezing index for the coldest year
in the last 10-year period may be used). If local records are unavailable, use the values directly from
either figure 6-15 or the PCASE WORLD INDEX program.
(3) Determine the frost depth using figure 6-16. The gravel thickness in this figure is the total depth
of ballast and sub-ballast. Multiply the frost penetration value by 0.6. If the resulting number is smaller
than the gravel thickness, then there is an adequate amount of ballast and sub-ballast in the cross
section. If it is larger, additional ballast and/or sub-ballast should be added and the thickness
recalculated.
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f. Alternate Design Procedure. An alternate method of designing for the effects of frost is to reduce the
effective strength of the soil to compensate for the thaw-weakening period (similar to a reduced-strength
pavement design).
(1) Additional Ballast/Sub-ballast. If more than 40 percent of the total frost depth is in the frost
susceptible subgrade, nonfrost susceptible material (clean ballast or sub-ballast) must be added to the
roadbed.
(2) Geotextiles. Geotextiles can be used to prevent particle migration at the subgrade/sub-ballast
interface during the spring thaw. Contamination of an otherwise clean ballast and sub-ballast by
subgrade soil can turn a nonfrost susceptible material into a frost susceptible material. The application of
geotextiles is covered in TM 5-818-8 and AFMAN 32-8011.
(3) Insulating Material. Frost heaving may be reduced or eliminated by the use of insulating
materials. This may be particularly useful in areas with deep seasonal frost that lack nonfrost susceptible
soils and in areas with varying subgrade soil conditions that may result in differential heaving. Expanded
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and extruded polystyrene foam boards are the two most commonly used synthetic insulations. Extruded
polystyrene is generally the most popular. In some instances, organic material such as peat, bark, wood
chips, or timbers and mineral materials such as slag or gravel have also been used. Placement of the
insulation can be between the ballast and sub-ballast, sub-ballast and the subgrade, or anywhere in
between. However, the insulation should be placed deep enough in the cross section to prevent damage
by maintenance equipment. In general, a minimum depth of 24 in. is recommended. Results of field and
laboratory tests have shown that extruded polystyrene retains its thermal properties and does not absorb
a significant amount of moisture if the board is protected from deformation. Therefore, the thickness of
the cover above the insulation is usually determined by the vertical stresses caused by the dead and live
loads and is limited to 1/5 of the compressive strength of the insulating material. Extruded polystyrene is
commercially available in compressive strengths of 40, 60 and 115 psi. Physical properties, available
thicknesses and sheet sizes are available from manufacturer’s specifications. TM 5-852-6/AFM 88-19,
chapter 6 provides calculations of frost depth where insulation is used.
h. Transition Zones. A gradual transition is required between areas with significantly different frost
heave behavior. The transition distributes differential heave over a distance and thus reduces its
detrimental affects. Transitions between cuts and fills and at culvert crossings and bridge approaches are
typically 75 to 100 ft long.
i. Construction Procedures. Subgrade will be excavated and scarified to a predetermined depth based
on field conditions, and then wind-rowed and bladed to achieve adequate blending. This helps to ensure
a high degree of uniformity of soil conditions and to eliminate any isolated pockets of soil with higher or
lower frost susceptibility. It may be necessary to remove isolated pockets of either low or high frost-
susceptible material. In these cases, the soil should be excavated to the full frost depth and replaced with
the surrounding soil. Stones (6-in. in diameter or larger) or large roots must be removed from any fill in
the full depth of the frost penetration. This includes any stones encountered during subgrade preparation.
Failure to remove these items can result in track roughness as the stones and roots are gradually heaved
upward. In rock excavations, positive drainage should be supplied so that no pockets of water are left in
the zone of freezing. The irregularity of the isolated pockets may lead to non-uniform heaving. At the
transition between cut and fill sections, transition sections should be used as previously discussed.
Frequently, rock joints and fractures are full of frost susceptible soil. Rock joints or fractures encountered
in the subgrade should be cleaned out to the full depth of frost penetration and these joints replaced with
nonfrost susceptible material.
10. DRAINAGE.
a. Importance. Although not a component of the track or roadbed, drainage (or lack of it) can have a
major impact on track strength and longevity. Without proper drainage, track will fail to perform as
designed or intended.
b. Design Guidance. TM 5-820-4/AFP 88-5, chapter 2 will be used for the design and construction of
drainage structures, except as modified by the following paragraphs.
c. Side Ditches.
(1) Most commonly, drainage is provided by open ditches running parallel to the track. In terminals
and in other level areas, subdrainage or other alternative drainage designs will be required.
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(2) To prevent a significant loss of strength in the subgrade, side ditches must provide ample
capacity and flow rate. The size of ditches will be based on the expected rainfall runoff and the
contribution from other drainage that may empty into the ditches. Guidance for estimating runoff and
ditch size may be found in TM 5-820-4.
(3) To provide adequate capacity, side ditches will be designed for a 10-year storm. To provide an
adequate flow rate, the minimum gradient for side ditches will be 0.30 percent.
(a) While not a desirable practice, there are some areas where the bottom of the ballast section
cannot be installed or raised above the surrounding ground level, and standard side ditches cannot be
dug (or would not provide sufficient flow). In these cases, subdrainage will be installed (figure 6-17).
Figure 6-17. Required Subdrainage where Open Side Ditches cannot be Installed
d. Culverts.
(1) Chapter 1, part 4 and chapter 8, parts 10 and 13 of the AREMA Manual provide design criteria
and specifications for railroad culverts. All culvert pipe will conform to current AREMA or ASTM
recommendations or specifications for culvert pipe under railroads.
(2) A minimum cover of 2.5 ft should be provided from the bottom of the tie to the top of the culvert.
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11. GEOTEXTILES.
a. Application under Track. Geotextiles are sometimes used under the track to provide for filtration
and/or separation of ballast and subgrade or ballast and sub-ballast, or drainage functions. Common
locations for the installation of a geotextile under track are:
(3) When rebuilding track with a history of excessive loss of profile (surface) and frequent track
maintenance requirements.
Recent industry studies have shown that geotextiles have not always been effective under track. Thus,
before deciding to install a geotextile, a thorough analysis of the site must be done to assure that a
geotextile will accomplish its intended purpose.
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b. Material and Installation Specifications. Geotextiles, and their installation, will conform with the
specifications in chapter 1, part 10 of the AREMA Manual.
c. Design Guidance. TM 5-818-8 will be used for the design of geotextile applications.
d. Drainage Applications. Lighter weight geotextiles are often useful for drainage applications outside of
the track structure, especially in subdrainage.
12. BALLAST.
b. Material Type.
(1) As ballast depends on high friction and interlock to be effective in restraining track and must also
withstand large loads, ballast must consist of a hard angular crushed rock or crushed slag.
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(2) Common rock materials suitable for ballast are granites, traprocks, quartzites, dolomites, and hard
limestones. As limestones degrade, they tend to produce fine particles that cement together, and are
thus not the best ballast choice if other hard rock material is economically available. Crushed slag can
also vary greatly in quality and suitability for good ballast.
c. Gradation.
(1) Table 6-8 gives recommended AREMA ballast gradations. For main running tracks, sizes 4A and
4 will be used. For loading tracks in terminal areas, size 5 may be used to facilitate easier walking along
the cars during loading and unloading operations, but a larger size is preferred for long-term track
maintenance. AREMA ballast gradation 4 is identical to ASTM C33 gradation 4. ASTM C33 gradation 56
is close to AREMA no. 5.
Table 6-8. Recommended Ballast Gradations
Nominal Size Amounts Finer Than Each Sieve (Square Opening)
Square Opening Percent by Weight
Size No. (in.) 2-1/2 in. 2 in. 1-1/2 in. 1 in. 3/4 in. 1/2 in. 3/8 in. No. 4
4A 2 to 3/4 100 90-100 60-90 10-35 0-10 0-3
4 1-1/2 to 3/4 100 90-100 20-55 0-15 0-5
5 1 to 3/8 100 90-100 40-75 15-35 0-15 0-5
(2) For smaller projects, where less than 200 tons of ballast is needed, and where the nearest
suppliers do not stock AREMA gradations, the following AASHTO (highway) gradations may be
substituted: CA5 for AREMA 4 or 4A, and CA7 for AREMA 5.
d. Depth.
(1) Appropriate ballast depth will be determined by structural analysis using the computer program
specified in paragraph 6. The manual method described in paragraph 7 may also be used, but is not
preferred.
(2) In all cases, the minimum depth of ballast from the bottom of the tie to the subgrade will be 8 in. In
most cases, however, main running tracks will require more.
e. Cross-Section. Figures 6-1 through 6-7 show standard ballast shoulder widths and side slopes. In
finished or resurfaced track, the top of ballast may be up to 1 in. below the top of the tie, but never above
the top.
13. SUB-BALLAST.
a. Purpose. Sub-ballast is a layer of material between the top ballast and subgrade with a gradation
finer than the top ballast and coarser than the subgrade. Sub-ballast is often cheaper than top ballast, so
it can be used to reduce total ballast cost or to provide a filter layer between the top ballast and a fine-
grained subgrade. Figures 6-2, 6-4, 6-5, and 6-7 show sub-ballast layer.
b. Application. A sub-ballast layer is recommended for most new construction. In addition to providing
a filter to keep subgrade particles from working up into and fouling the ballast, it provides a good mat to
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distribute loads from the ballast and prevents ballast particles from being pushed into the subgrade. A
sub-ballast layer is required whenever:
(1) The subgrade contains 85 percent or more (by weight) of silt and clay sized particles, or
(2) The subgrade material has a liquid limit greater than 50 and a plasticity index greater than 20.
d. Gradation.
(1) To function well as a filter layer, the sub-ballast particles should range in size from the smallest
ballast particles the largest subgrade particles.
(2) Over a clay or silty clay, with greater than 85 percent passing the no. 200 sieve, the following
gradation is recommended:
Sieve Size ½ in. 3/8 in. #4 #10 #20 #40 #100 #200
Percent Passing 100 90 80 70 50 40 20 10
This gradation can be approximated by specifying ASTM D1241 gradation C or the somewhat finer
gradation D.
(3) Over a subgrade with more than 15 percent larger than no. 200, either of the following should
suffice: a sub-ballast of AASHTO gradation C19, or ASTM D1241 gradation C.
e. Depth.
(1) During structural analysis, the sub-ballast layer is considered as part of the total ballast depth.
(2) A sub-ballast layer may comprise up to 40 percent of the total ballast depth on main running
tracks and up to 50 percent on auxiliary and terminal tracks.
(3) When used, the minimum sub-ballast thickness will be 4 in. with a minimum total ballast depth of
10 in.
a. Material.
(1) In most cases, wood is still the most cost-effective tie material. Wood ties will meet the
requirements in chapter 3, part 1 of the AREMA Manual. The recommended species of wood for cross
ties are:
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Hardwoods Softwoods
Ash Douglas Fir
Beech Pine
Hickory Spruce
Red Oak
White Oak
(2) Strictly defined, hardwood and softwood refer to a type of tree and not the hardness or density of
the wood. However, the hardwoods listed above are denser and generally more durable than the listed
softwoods and thus usually more desirable for ties. While softwoods are sometimes preferred on open
deck bridges to help absorb impact, they are not recommended for use in turnouts or in sharp curves
(over 8 degrees) where the better spike-holding ability of the denser woods is needed.
(3) Hardwood ties are often sold in species groups such as mixed hardwoods or oak. The mixed
hardwoods may comprise, for example, 40 percent oak and 60 percent assorted hardwoods, including
gum. Gum is not a preferred species, but is commonly used. The oak group is usually a mix of red and
white oak and typically costs more than the mixed hardwoods.
(4) For track with annual traffic volumes of 5 MGT or less, as is common at military installations,
wood ties are more likely to fail from decay rather than mechanical wear or loss of spike-holding ability. In
such cases, tie selection should lean toward available species that readily accept deeply penetrating
preservative treatment. Information from the engineering department of the serving commercial carrier,
from regional tie suppliers, and from local experience should help in selecting the most appropriate ties.
(1) The two common cross sectional sizes for wood track ties are 7 in. thick by 9 in. wide or 6 in. thick
by 8 in. wide.
(2) 7x9 ties are recommended for areas with higher traffic volumes and wheel loads as well as in
turnouts and in road crossings.
(3) Track ties are commonly produced in 8.5 or 9-ft lengths. The 8.5-ft length will be used when most
conveniently available.
(4) Ties for turnouts vary from 9 to 16 ft long and will be ordered as indicated in table 6-9.
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Note: Each tie set includes 2 - 15 ft ties for head blocks (which hold the switch stand).
c. Treatment.
(1) All wood ties will be pressure treated with preservative as specified below.
(2) The preferred preservative for ties is a creosote-coal tar solution (60/40) as specified in AWPA
standard P2.
(3) For ties used west of the Mississippi River, a creosote petroleum solution (50/50) as specified by
AWPA standard P3 may be used.
d. Anti-splitting Devices. To reduce the tendency of wood to split, anti-splitting devices are often
applied to the ends of ties. Anti-splitting devices are recommended for turnout ties but may be specified
for standard track ties. Of the two general types, as shown in figure 6-20, the nail plates are more
effective and thus preferred.
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e. Pre-boring. Once a common practice, the pre-boring of spike holes is no longer recommended.
f. Tie Spacing. The center-to-center distance between adjacent ties will usually range from 19.5 to 22
in., with a minimum allowable of 18 in. and a maximum of 24 in. For auxiliary and loading tracks, a 21 to
23-in. spacing will often suffice. Tie spacing will be specified after a structural analysis has been
performed.
(1) Concrete ties are used by some commercial railroads, particularly on lines with the heaviest traffic
volumes and in areas with numerous curves. Where used, concrete ties are in track with welded rail and
solidly supported with deep ballast sections. Concrete ties are usually not economical on lighter traffic
lines, and are usually not suitable for use with jointed rail or in track of lighter construction. Also, concrete
ties cannot be successfully mixed with wood ties. Thus, concrete ties are not recommended for general
use in military track.
(2) The use of concrete ties for certain special applications may be cost effective. The economic
benefit of these installations must be thoroughly investigated prior to the selection of concrete ties.
(3) Research and development continues on ties made with alternative materials and of hybrid
construction. None have yet proven economical for routine, general purpose use.
15. RAIL.
a. Section Designation. Rail is rolled into different sizes (dimensions) and shapes commonly referred to
as “weight” and “section.” The weight of a rail is based on how much a rail weighs in pounds per yard of
length. The section refers to the cross sectional shape of the rail.
b. Selection Criteria. Selection of a rail section will be done only after a structural analysis has been
performed. Designers will determine structural requirements as well as cost and availability of rail
sections before a final selection is made.
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(1) Weights and sections recommended for new rail purchases are: 115RE, 132RE, 133RE, and
136RE, with 115RE being the preferred. These are the standard sections recommended by the AREMA
and should be available for many years.
(2) Rail may be purchased in either 39- or 80-ft lengths. Rail 80 ft long has the advantage of
reducing the number of joints to half that for 39 ft rail. For small purchases where the rail may be
transported by truck, 39 ft lengths may be more cost effective.
(1) Secondhand rail that meets the specifications in table 6-10 either as is or after cropping off the
ends, may be used for rehabilitation or new construction. Before selecting relay rail, the cost, condition,
and availability of matching joint bars and tie plates must be investigated.
Table 6-10. Dimension and Surface Specifications for Relay (Secondhand) Rail
Length For Standard 39 ft lengths:
Not more than 10% of lot between 33 ft and 39 ft.
No rail shorter than 33 ft.
Vertical 90 lb or Larger: Average top wear 5/16 in. or less with maximum at any one location of 11/32
Wear in.
Less Than 90 lb: Average top wear 1/4 in. or less with maximum at anyone location of 9/32
in.
Side At least one side must meet the following:
Wear 90 lb or Larger - Maximum of 5/16 in
Less Than 90 lb - Maximum of 1/4 in.
Lip or Maximum of 1/16 in., either as is or obtained by grinding off excess.
Overflow
Engine Maximum of 1/2 in. diameter (or 1/4 in. wide by 1/2 in. long) and 1/32 in. deep.
Burns Maximum of four engine burns per rail.
Engine burns on no more than 8% of the lot.
End Batter Maximum of 1/8 in. when measured 1/2 in. from the rail end with an 18 in. straightedge.
And Chipping
Running Surface Maximum size of 1/4 in. wide by 1/2 in. long and 1/32 in. deep.
Damage Maximum of four damaged spots in any one rail.
Defects Not Bolt hole cracks or breaks, broken base, crushed head, detail or engine burn fractures, head-
Permitted web or web-base separations, piping, horizontal or vertical split head or web, torch cuts or
flame gouges, compound or transverse fissures, deep pitting from corrosion.
Condition and Rail must be: free from obvious defects; clean in appearance; straight in line and surface and
Appearance without kinks; and free from base defects such as plate wear and spike notches.
Internal Rail to be ultrasonically inspected before or after installation.
Inspection Defective sections to be rejected and replaced.
Note: See AREMA Manual chapter 4, part 3 for rail defect definitions and illustrations.
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(2) Recommended relay rail sections are: 100ARA-B, 112RE, 115RE, 130RE, 132RE, 133RE, and
136RE.
(3) Relay rail should be selected to limit the number of different rail weights and sections within the
track network. For a given weight, the section and joint drilling pattern (bolt-hole size and spacing) should
also be consistent.
(4) Due to the varying market for relay rail it may be beneficial to allow the contractor an option to
provide an acceptable rail section. Selection should be limited to those sections that are sufficiently
plentiful to supply future maintenance purchase requirements: rail, joint bars, frogs and other turnout
parts.
e. Lightweight Rail.
(1) Lightweight rail weighs less than 90 lb per yd. These weights are no longer manufactured and
are only available as secondhand.
(2) For main running tracks, rail weights less than 90 lb per yd will not be used. Rail weighing 75 lb
per yd to 85 lb per yd may be adequate for terminals and auxiliary tracks with light use, depending upon
support conditions. A structural evaluation is necessary to determine the adequacy of these rail weights.
Rail not adequate to support the desired wheel loads should be replaced.
(1) Continuous welded rail (CWR) is strings of standard rail welded together either in a rail plant or by
field welding after installation. CWR is commonly used on commercial railroads and is beneficial in
reducing maintenance costs due to rail joints.
(2) CWR is not recommended for general use on military track because it: (1) requires a larger ballast
section to provide sufficient track restraint, (2) needs more rail anchors to restrain longitudinal rail
expansion, (3) is more subject to buckling in hotter weather and pull-aparts during colder weather, and (4)
has a higher initial installation cost. If conveniently available, short strings (less than 200 ft) may be
appropriate for wide road crossings or track in paved areas. CWR may have good application on certain
lines that form a long connection to the serving commercial carrier.
g. Field Welds.
(1) It is recommended that rail through road crossings and for 20 ft on either side of crossings be
welded to eliminate joints in these areas. Likewise, field welding should be considered for rail placed in
confined loading areas, adjacent to warehouse loading docks, and in other areas where maintenance
access to rail joints would be difficult.
(2) Rail welding may only be accomplished with special thermite welding kits designed for this
purpose and by people with the necessary training and experience in welding rail. Where many welds
are to be done, some specialized contractors have truck-mounted electric welding units designed for this
purpose.
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h. Salvaging Rail. During track reconstruction, the existing rail and other track materials can often be
salvaged for use at other locations on the installation, stockpiled for future construction projects, or sold
on the open market as used material. Lightweight rail, defective rail, and other track materials not
suitable for use in track reconstruction on the installation or for resale on the open market should be
disposed of as scrap or reroll material.
a. Definition. Tie plates, joint bars, bolts, spikes and other miscellaneous hardware used in track
construction are commonly referred to as other track materials (OTM).
b. Tie Plates.
(1) Tie plates vary in length and width. Most sizes are suitable, as long as the spike hole punching
(or distance between the shoulders - for double shoulder plates) matches the width of the rail base. For
double shoulder tie plates, the distance between the shoulders will be at most 1/8 in. larger than the rail
base width. On single shoulder plates, the spike holes on the gage side (opposite the shoulder) must
keep the inside face of the spike within 1/8 in. of the rail base when the opposite edge of the base is
against the shoulder. (See figures 6-21 (a) and (b)).
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(3) Within a given length of track, tie plates of different lengths and widths may be used, and single
shoulder plates may be mixed with double shoulder plates. However, plates with different cants (i.e.,
those with level rail seats and those with a 1:40 slope) will not be mixed. Tie plates with a 1:40 cant are
preferred.
(4) Secondhand plates that are not bent, have not lost much material due to corrosion, and otherwise
meet the above requirements, are acceptable.
c. Spikes. On tangent track and on curves up to 4 degrees, one spike on the gage and field side of
each rail will be used (a total of four spikes in each tie). On curves greater than 4 degrees, one spike on
the field side and two spikes on the gage side of each rail will be used (a total of six spikes in each tie).
(1) Either four-hole (24-in.) or six-hole (36-in.) joint bars may be used for rail joints.
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(2) Standard and compromise joint bars will be properly factory designed and constructed and will be
of the size, shape, and punching pattern to fit the rail being joined. New joint bars will meet
“Specifications for High Carbon Steel Joint Bars” or “Specifications for Quenched Carbon Steel Joint Bars
and Forged Compromise Joint Bars” in chapter 4, part 2 of the AREMA Manual and joint bar assemblies
in chapter 4, part 1 of the AREMA manual. Compromise joints will be specified as indicated in AREMA
Plan 700B.
(3) Secondhand joint bars may be used on secondhand rail if not bent, cracked, excessively
corroded, or otherwise defective. Secondhand joint bars will not be used on new rail.
(4) Insulated joints required to isolate signal currents for road crossing warning devices may be either
the field-applied type or prefabricated (glued) type. Special insulated tie plates are also required.
(5) It is recommended that rail joints be welded where located in road crossings, paved areas, or at
any location where access to the joint is restricted.
(1) Track bolts, nuts, and spring washers will conform to the specifications in chapter 4, parts 1 and 2,
of the AREMA Manual.
(2) Common bolt diameters for different rail weights are found in table 6-11.
Table 6-11. Common Joint Bolt Diameters
Bolt Diameter (in.) Rail Weights (lb / yd)
3/4 60 to 75
7/8 70 to 90
1 90 to 130
1-1/8 131 to 140
f. Rail Anchors.
(1) Rail anchors restrain longitudinal rail movement and should be used on main running tracks in the
quantity and arrangement diagrammed in figure 6-22, as a minimum. Additional anchors may be required
on track with grades steeper than 0.5 percent, and where combinations of traffic volume, speed, and
curvature indicate a need.
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(2) When anchors are used, each tie that is anchored will have four anchors applied (box anchored),
per tie as shown in figure 6-22.
(3) Either type of anchor, spring or drive-on (shown in figure 6-23), may be used. Drive-on anchors
have the advantage of being easier to apply and remove manually, and do not require a special anchor
wrench, as do spring anchors. It is possible, though, to over-drive a drive-on anchor, causing it to lose its
ability to tightly grip the rail base.
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(4) Rail anchors will not be used across open deck bridges. Instead, for two rail lengths off each end
of the bridge, every third tie should be box anchored. A similar arrangement should be used at rail
crossings, as shown in figure 6-24. Rail anchors should be applied at the normal designated pattern
across ballast deck bridges.
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Figure 6-24. Rail Anchor Applications at Open Deck Bridges and Rail Crossings
g. Gage Rods.
(1) Gage rods are sometimes specified for very sharp curves (over 8 degrees) where difficulty in
holding gage is anticipated. Where used on sharp curves, two to four rods should be installed per rail
length.
(2) The general use of gage rods is not encouraged and should be reserved for special or unusual
cases.
a. Description. Turnouts are designed to divert trains from one track to another. Two turnouts form a
crossover when used together to allow the passage of trains between parallel tracks. The general
arrangement of turnouts and crossovers is shown in figure 6-25. The main parts of a turnout are shown
in figure 6-26. For additional switch detail see AREMA Plans 190, 220, and 221.
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b. Size.
(1) Turnout size is designated by the size of the frog used in the turnout, as illustrated in figure 6-27.
The size of the frog determines the angle at which the turnout track diverges from the tangent track. Frog
size also influences the required degree of curvature within the turnout.
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(1) The main design decisions for turnouts are the direction in which the turnout will diverge (as
shown in figure 6-25), and the angle of the frog (or frog number), which determines how sharply the
turnout diverges (and also designates the size of the turnout). Recommended choices for different
turnout components are covered below, as is layout design for use where nonstandard configurations are
required.
(2) Once a standard turnout has been selected from table 6-12, or the geometry has been otherwise
determined, the designer will then specify the desired switch, frog, and guard rails if needed, from the
appropriate AREMA plans; the turnout (or crossover) tie set from table 6-9; and the amount of rail needed
to complete the turnout (connect the switch and frog) from AREMA Plan 910 or 911. Guidance on the
selection of these items and other turnout hardware is given below.
(3) All materials used within the limits of a turnout will be factory designed and constructed, of the
proper type and size, and not be flame cut or otherwise altered in the field.
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d. Switch Ties.
(1) A turnout is fastened to a special set of ties called a switch tie set. Generally, switch ties increase
in length from the switch point to just past the frog where the turnout ends. From that point, two standard
tracks continue. An exception is at the switch point where the switch stand requires two long ties called
head blocks to accommodate the stand and operating rods. The make-up of switch tie sets will be
determined from table 6-9.
(3) Switch ties will meet the material and treatment specifications for standard track ties covered in
chapter 6, paragraph 14.
(1) The standard switch for use on military track is the 16 ft, 6-in. switch with graduated risers, as
shown in AREMA Plan 112. The detailed specification for this switch is given in the notes in the upper
right corner of the plan. In most cases, the specification will be for a 112E or 112F (non-insulated hand
throw - rigid braces), or if adjustable braces are desired, specification 112A or 112B - omit insulation
(Note 2(e)), if the switch is not within a signal circuit (as near crossings with warning lights or gates).
Shorter or longer switches may be used, as needed, but switches shorter than 15 ft are not
recommended.
(2) In locations where traffic conditions may cause excessive wear on the tapered ends of the switch
point, the use of alloyed steel (or hardened) switch points is recommended (AREMA Plan 220).
(3) The use of spring switches is not recommended on Army and Air Force track.
f. Switch Clips. Either the adjustable side jaw clip or the adjustable transit clip, as shown at the top of
AREMA Plan 222, are suitable. The slanted row of holes in the clip provides adjustment in switch rod
length ranging from 1/8 in. to 1/2 in., effected by moving the bolt from one hole to another.
g. Rail Braces. The rail braces that support the outside of the stock rails may be either the rigid or
adjustable type. In most cases, rigid braces will suffice, but where movements in both directions through
the turnout may be frequent and under heavy loads, the adjustable braces are recommended.
h. Switch Stands and Lever Latches. Ground throw (low) switch stands are preferred, especially in
terminal areas. However, high stands may be preferred in more remote areas at the ends of passing
sidings or where routes diverge. Many variations of stands are available and most are suitable.
However, any stand selected should have a provision for the throw lever to lock or latch solidly in place.
For switches in more remote areas, a switch point lock and/or lever lock may be desirable.
(1) The solid manganese, self-guarded type frog, as shown in AREMA Plans 641 and 691 (section B-
B), is preferred for the slower speed operations most common at military installations. Self-guarded frogs
simplify turnout construction by not requiring separate guard rails opposite each side of the frog.
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(2) Rail bound manganese (RBM) frogs, as shown in AREMA Plan 600, may be used on heavy traffic
lines where the traffic is approximately equal on both sides of the frog. This type of frog is most desirable
for long turnouts (size 15 or above) since manganese steel is especially suited to the thin long points and
requires comparatively little maintenance.
(3) Bolted rigid frogs, as shown in AREMA Plan 320, can be used at any location on military
installations. However, when new frogs are required, the two choices above are preferred.
(4) Spring rail frogs will not be used on Army and Air Force installations.
(5) Frogs are secured to ties with a set of hook plates, as shown in AREMA Plan 241.
(6) When not using self guarded frogs, guard rails will be specified to match the frog size, as listed in
Note 2A of AREMA Plan 502. Guard rails of the type in AREMA Plans 504 or 510 may be used.
(1) Enough rail to make up the straight and curved stock rails and closure rails must be supplied, as
indicated in AREMA Plan 910 or 911. This amount will approximately equal twice the actual lead
(Column 4) plus the closure distances (Columns 5 and 6).
(2) All rail within the limits of a new or secondhand turnout will be of the same weight and section,
and should match the rails on the main and diverging tracks. Compromise joints are not permitted within
the limits of a turnout.
(3) Where new switch points are specified with relay closure rail, a check must be made to assure
that the top and gage side of the points and closure rails match at the heel joint.
(4) When turnouts will be rebuilt, and both new and relay rail will be available on the project, it is
recommended that new rail be used to reconstruct the turnouts; this will avoid the potential problem of rail
contour mismatch at the switch heel joints.
(1) In most cases, designers will use the dimensions and layout data for standard turnouts shown in
AREMA Plans 910 and 911, with turnout size selected from table 6-12 and component options as
discussed above. Turnouts may be laid out as left-hand, right-hand, or equilateral, as shown in figure 6-
25.
(2) On occasions when nonstandard layout is required, or where different point lengths are used,
turnout layout may be determined from figure 6-28 and equations 6-12 through 6-15.
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h −t
sin S = Eq 6-12
a
S = Switch angle (degrees).
h = heel spread (inches). (Standard dimension is 6.25 in.).
t = thickness of switch point (inches). (Standard dimension is 0.25 in.).
a = length of switch point (inches).
1
C =q Eq 6-13
(F + S )
sin
2
C = Long chord (feet).
q = g - e - h (feet), where g is track gage, e is frog toe spread from AREMA Plan 910, Column 21, and h is
the switch heel spread distance (which has a standard value of 0.52 ft).
F = Frog angle (degrees), from AREMA Plan 910, Column 17 (converted to degrees).
S = Switch angle (degrees).
C
R≈ Eq 6-14
2 sin 1/2(F − S)
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L ≈a +C + d Eq 6-15
L = Lead (feet).
a = Switch length (feet).
C = Long chord (feet).
d = Frog toe length, from AREMA Plan 910, Column 19 (feet).
l. Equilateral Turnouts. In an equilateral turnout, the diverging angle (frog angle) is divided equally on
both sides, thus the turnout has two curved stock rails and two curved closure rails that mirror each other.
Likewise, the degree of curve along each closure rail is half that of a standard left or right-hand turnout.
(1) When not required by space limitations or other local conditions, turnouts to the inside of a curve
will be avoided.
(2) Curvature through a turnout on the inside of a curve equals the degree of curvature for the curve
plus that for a standard turnout. Thus, a number 10 turnout off the inside of a 3 degree curve will have a
curvature of 3 + 7.4 = 10.4 degrees. The total curvature must not exceed design limits.
a. Diverging Routes.
(1) Figure 6-29 shows the layout for a typical diverging route connection. Note that the angle that the
route diverges is the same as the frog angle for the turnout. The distance from the intersection of track
center lines to the location of the frog point is given by equation 6-16.
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N = Frog number
(2) For layout of parallel siding connections, as shown in figure 6-30, the tangent distance Q should
be at least 50 ft.
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b. Crossovers. Crossovers are a combination of two turnouts used to join two adjacent tracks, as
shown in figure 6-25.
c. Ladder Tracks. Figure 6-31 illustrates a typical ladder track, shown between points A and H. This
arrangement is commonly used for parallel yard tracks or loading tracks. (Also see chapter 8 for layout of
yard and terminal tracks).
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a. Recommended Types. Bolted rail crossings, as described in items 1(a) and (b) on AREMA Plan
700A, are recommended for use on military track. Tie layouts and plates for various angle crossings are
given in AREMA Plans 700F through 700J.
b. Anchoring Approaches. Where rail anchors are used on the tracks approaching rail crossings, every
third tie should be box anchored (four anchors per tie) for at least two rail lengths in all directions from the
crossings.
c. Application. As rail crossings are expensive and require more maintenance than standard track,
track layouts should be designed without the need for tracks to cross unless this is clearly necessary.
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a. Derails.
(1) Application and Type. Derails are commonly used on spur tracks or sidings to prevent runaway
cars or unauthorized entry onto the main track. Derails are also used to protect standing equipment
stored on a track. Three different types are the switch point derail, permanent hinged or sliding derail,
and portable derail.
(2) Location. Derails should be located so that after running over the derail, a car would stop before
reaching the point requiring protection. This distance depends mainly on track length and gradient.
Figure 6-32 illustrates derail placement.
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(3) Size and Designation. Derails must be ordered for the size of rail on which they are to be
installed. The number of the derail usually indicates the distance (in inches) from the top of the rail to the
top of the tie (including tie plate thickness). Derails generally come in even 1-in. sizes and can be
shimmed up to a height of 0.5 in. (or the ties on which the derail is attached can be added up to 0.5 in.
deep) to accommodate height variations.
(4) Direction. Derails are designed as either left-hand or right-hand. The proper direction is
determined by looking in the direction that the rolling stock to be derailed would be moving. A right hand
derail is installed on the right hand rail and derails the cars off the right side of the track, while a left-hand
derail is installed on the left-hand rail and always derails to the left.
(1) Wherever cars carrying fuel, ammunition, or other flammable or explosive materials are unloaded,
or where track is located adjacent to electrical equipment, the rails (and related track materials capable of
conducting electrical current) must be bonded, grounded and insulated from the remaining track. This
bonding and grounding helps prevent the discharge of static electricity during the loading or unloading of
these hazardous materials. General requirements for bonding and grounding are given below; additional
details are found in chapter 33, part 7 of the AREMA Manual.
(2) When a side track, or section of running track, is to be bonded and grounded, an insulated joint
should be provided on each rail at the first rail joint beyond the turnout of the adjacent main track at either
end of the main track. The rails at all other joints in the track beyond or between the insulated joints will
be bonded together with bond wires and both rails of the bonded track will be connected by grounding
connectors to a single driven ground rod.
(3) An exothermic type rail bond (“cadweld bond”) is recommended for the application of rail bonds
on military track. Bond cables should be flexible bare copper stranded 1/0 AWG cables with preformed
ends and should conform to the applicable requirements.
(4) Grounding rods should be 0.75-in. diameter copper clad steel rods or 1-in. diameter zinc coded
steel rods. The minimum length of ground rods should be 8 ft. Ground rods should be driven vertically
for their full length, and the top of the ground rod should be located a minimum of 12 in. below the top of
the subgrade at the toe of the ballast slope. The maximum allowable resistance of grounded rail or
structures is 25 ohms.
(5) All electrical connecting hardware should be bronze pressure type materials and have no rotating
parts coming in direct contact with the conductors.
(6) Rail cross bonds are required to bond the two rails together and to connect the rails to the
grounding rods. Rail cross bonds should be installed using exothermic type bonds and 1/0 AWG flexible
bare copper stranded cable. The cross bond should be applied to the rail head or rail web and the cable
for the cross bonds installed a minimum of 12 in. below the bottom of the ties. One cross-bonded ground
rod should be installed at 100-ft intervals along tracks designated for the loading and unloading of fuel,
ammunition, and other volatile or hazardous materials.
(7) Defective bonds will be removed by shear cutting old cables immediately adjacent to the weld or
pin. Flames or torches will not be used to remove defective or out-of-service bonds.
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(8) Where overhead power lines in excess of 600 volts cross over the track, the rails will be made
electrically continuous and grounded for a distance of 150 ft on each side of the power lines.
c. Track Scales.
(1) When required, track scales will be designed and installed in accordance with the AAR Scale
Handbook, which appears as an appendix in the AREMA Manual.
(2) The design and construction of track scales is best performed by a commercial firm that
specializes in design, fabrication, and construction of railroad track scales.
(1) Bumping posts, wheel stops, or timber and earth mounds should be used at the open end of all
stub tracks to prevent cars from rolling off the end of the track.
(2) Where it is not critical that railroad cars be absolutely stopped at track ends to protect personnel,
facilities, or parked vehicles and equipment, and where no other hazards are present, consideration
should be given to using low earth mounds or some type of wheel stop at the end of the tracks rather than
coupler-height, solid bumping posts, or obstructions.
e. Roadway Fencing. The character of the land use of property adjacent to the railroad and security
requirements will govern the need for fencing along the right-of-way lines. The installation Physical
Security Officer should be consulted to ensure that security fencing requirements are covered in the
design.
f. Snow Fences. Chapter 1, part 6 of the AREMA Manual provides guidance on the application and
construction of snow fences and other measures to minimize snow drifting on the track.
g. Cattle Guards. In areas where livestock or other large animals could enter the railroad right-of-way at
road crossings, cattle guards may be necessary.
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CHAPTER 7
ROAD CROSSINGS AND BRIDGES
1. ROAD CROSSINGS.
(1) The need for a new crossing and its appropriate location will be checked with the installation
master plan. As road crossings increase maintenance costs and safety risk, their number should be held
to a minimum.
(2) A study should be conducted to assess traffic and site conditions for a newly planned crossing or
one intended for upgrading or rehabilitation. This study should include:
(c) Crossing angle and horizontal and vertical approaches of road and track.
(d) Available sight distances, from all directions, for vehicles approaching the track and from trains
approaching the crossing.
These findings will help establish crossing and protection design requirements.
b. Design Steps.
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c. Geometric Layout.
(1) The ideal crossing geometry is a 90-degree intersection of the track and road (for best sight
angles) with slight ascending grades on the road approaches. Drainage should be away from the track to
reduce the flow of surface water toward the crossing.
(3) Avoid locating crossings within either a road or railroad curve. These sites typically result in poor
sight warning distances and in conflicting super-elevations that often lead to long-term maintenance
problems and poor performance of the crossing.
(4) Where the road and railroad cannot cross at right angles, the angle should be kept to 60 degrees
or greater whenever practical. For angles less than 60 degrees additional warning or crossing protection
should be considered.
(1) Table 7-1 lists 10 standard crossing types. Figures 7-1 through 7-10 show cross sections and
design details, These designs are described below along with some recommendations for their
application and their limitations. It should be noted that, even for the most expensive crossing surfaces,
the cost of rebuilding the track (especially when new rail is installed) and the road approaches is usually
more than the purchase and installation cost of the crossing surface itself. Thus, especially where road
traffic volume is significant, where significant numbers of heavy trucks pass over the crossing, or where
vehicle speeds exceed 25 mph, the main cost variable will probably be the expected durability of the
crossing.
(2) Table 7-1. This table is a starting point for matching a crossing surface with traffic requirements.
The descriptions of the crossing surfaces below will help focus on the most appropriate choices. The
Road/Street classes (A through F) and Traffic Categories (I through VII) in table 7-1 are those from TM 5-
822-2/AFM 88-7, chapter 5. The entries in the table are the codes for the suggested crossing surfaces.
Table 7-1. Recommended Crossing Surfaces
Road/Street Class
Traffic
Category A B C D E F
I 4A, 4B, 5 4A, 4B, 5 2, 4A, 4B, 5 2, 3B, 3C, 3D 2, 3A, 3B, 3C, 3D 1, 2, 3A
II 4A, 4B, 5 4A, 4B, 5 4A, 4B, 5 2, 3B, 3C, 3D 2, 3B, 3C, 3D 1, 2, 3A
III 4A, 4B, 5 4A, 4B, 5 4A, 4B, 5 4A, 4B, 5 2, 3B, 3C, 3D 1, 2, 3A
IV 4A, 4B 4A, 4B 4A, 4B, 5 4A, 4B, 5 2, 3B, 3C, 3D 2, 3B, 3C, 3D
IV-A 4A, 4B, 4C 4A, 4B,4C 4A, 4B,4C 4A, 4B 4A, 4B 2, 3B, 3C, 3D
V 4A, 4B,4C
VI
VII
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(a) Crossing Types 2, 4B, 4C, and 5 may be categorized as prefabricated. These crossings are
generally ordered from a manufacturer and are assembled at the site from surface panels using special
panel attachment or track fastening hardware. Prefabricated crossings often require longer ties than
standard and must be ordered specifically for the size of rail and tie plates, and anchors (if used) at the
crossing; this ensures panel height will match rail height and that sufficient clear space is available under
the panels for the tie plates and rail fastenings. Prefabricated crossings must also be ordered to match
any track curvature and for crossing angles that vary significantly from 90 degrees. It is suggested that
prefabricated crossings be ordered to extend at least 2 ft on each side beyond the widest part of the road
through the crossing, allowing for crossing angle as needed.
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(b) Prefabricated crossings can typically be installed more quickly than constructed crossings and
are usable as soon as installation is complete. When considering prefabricated crossings, it is suggested
that drawings and instructions be obtained from a sampling of manufacturers to help determine an exact
list of materials and hardware required, as well as available options and track construction and
preparation requirements.
Figure 7-1. Typical Type 1 Gravel Crossing with Timber Flangeway Header
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Figure 7-4. Typical Type 3B Asphalt Crossing with Timber Flangeway Header
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(5) Flangeways.
(a) General. These are often the most maintenance-intensive parts of a crossing. In all crossings,
a clear flangeway space must be provided to allow unimpeded passage of the flange on railroad wheels.
(b) Open or Closed Flangeways. Depending on the location, opinion may vary on whether the
benefits of filling a flangeway exceed its costs and disadvantages. Open flangeways allow water to enter
the crossing and track below, that is usually considerable highly undesirable; however if the drainage is
good, the water may quickly run off and cause little harm. Over time, dirt and debris entering an open
flangeway may impede drainage. Filled flangeways are often subject to rapid build-up of dirt and debris
or snow and ice. If left uncleaned, these foreign materials are typically packed in by the passage of wheel
flanges and may build up to the point of blocking the flangeway and causing a derailment. Ice in a
flangeway has a high probability of causing a derailment. In summary, an open flangeway readily allows
water to enter the track structure, and a filled flangeway must typically be cleaned more frequently. In
areas with low annual rainfall, or where track and road gradients naturally direct water away from the
crossing, an open flangeway design may be preferred. In most other cases, a filled flangeway will
provide long term benefits by reducing the amount of water entering the track through the flangeway.
(c) Filler Material. The least desirable filler is asphalt. While inexpensive, it tends to break in a
short time, losing its ability to seal against water entry, and ultimately requiring time-consuming removal
and replacement. Preformed or pourable rubber products are available for some crossings. Rubber
crossings typically come with a flangeway filler molded in as part of the panel. Concrete panel crossings
are often supplied with rubber flangeway fillers, sometimes pre-attached to the panels. Rubber fillers may
have a high initial cost, but they offer a reasonably good seal against water entry, are generally long
lasting, and have a flexibility that reduces the tendency of a debris-packed flangeway to cause a
derailment. Rubber flangeway fillers are especially useful where: (1) crossing geometry and low relative
elevation naturally direct rainwater to the crossing flangeways, (2) where crossing drainage is naturally
difficult, or (3) where crossing heave from freeze-thaw cycles is a common problem from rainwater or
snowmelt entering unsealed flangeways. Rubber fillers are also an alternative where asphalt filler has not
held up well in the past. Figure 7-11 shows rubber flangeway fillers installed in a concrete panel crossing.
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(6) The following should be considered in selecting an appropriate road crossing surface:
(e) Accident history for existing crossings where the crossing surface may have contributed to the
accident.
(f) Cost initial construction cost, replacement cost, and maintenance cost.
(7) Type 1 Gravel Crossing with Timber Flangeway Header. These crossings are appropriate in
locations with very low traffic volumes and where a crossing is not often used by large trucks or tracked
vehicles.
(8) Type 2 Timber Crossing. These crossings generally have a medium life span of about 10 to 15
years. They are often chosen due to long familiarity and experience with their design. If removed for
track or road maintenance, however, the warping stresses that commonly build up in wood long exposed
to weathering elements can make replacement difficult and may result in a rougher riding surface.
Timber is subject to wear, that may gradually lead to exposure of fastenings to vehicle tires. Timber is
also subject to damage by plow blades during snow removal.
(9) Type 3A Asphalt Crossing. These are expediently and inexpensively constructed, but the
absence of a separate header to form a flangeway typically leads to difficulty in keeping the flangeway
clear and to pavement breaking adjacent to the rail.
(10) Type 3B Asphalt Crossing with Timber Flangeway Header. The presence of a separate
flangeway header, compared with Type 3A, typically results in reduced flangeway maintenance and less
pavement breakage near the flangeway. Expected life may average 8 to 10 years under moderate traffic
and where freeze-thaw cycles are common.
(11) Type 3C 4-Rail Asphalt Crossing. This design may be less subject to plow blade damage during
snow removal operations than a Type 3B crossing. It uses scrap rail turned on its side to form a solid
flangeway, that tends to reduce the amount of water entering the track and can also be cleaned without
damaging the flangeway.
(12) Type 3D 6-Rail Asphalt Crossing. The protective rails on each side of the running rails take
some of the lateral impacts from passing vehicles and thus reduce the tendency of the running rail to be
loosened over time by vehicle traffic. This design may be useful where heavy trucks or tracked vehicles
commonly cross the track. The design does require cutting many scrap tie plates to act as supports or
shims, but, as with Type 3C, material costs are typically inexpensive.
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(13) Type 4A Cast-in-Place Concrete Crossing. These may be best suited for track through paved
areas as for truck delivery areas along warehouses or through concrete material storage areas. This type
of crossing, though more durable than asphalt, is the most difficult of all types to remove if access to the
track is needed for maintenance.
(a) General Characteristics. These are now being produced by a number of manufacturers and are
being widely adopted due to their relative strength and expected durability, ease of installation and
removal for track maintenance, and moderate cost. These crossings are not subject to decay as are
standard timber crossings and are much less subject to damage from plow blades during snow removal
operations, compared to timber, rubber, or gravel crossings. In addition, they may be most suitable to
accommodate traffic from tracked vehicles. When either track or adjacent road maintenance is required,
these crossings can be removed relatively easily, in part or whole, and replaced without damage to the
crossing material or track, and without loss of original evenness of surface. Like other crossings, though,
these require solid support to prevent panel breakage or loss of crossing surface evenness. Due to the
stiffness of the panels, these crossings are not recommended for locations where there is a pronounced
vertical curve in the track.
(b) Specifications. Design of these crossings varies with manufacturer. It is suggested that a type
be chosen with a minimum concrete strength of 5,000 psi, with guaranteed panel thickness variation
within +/- 1/8 in., with a waterproof and chemical resistant seal on panels, and with the option of epoxy
coated rebar. A warranty of crossing performance should also be obtained.
(c) Installation Options. In a standard or lagged installation, the panels are “lagged” (attached) to
wood ties with lag bolts, with no fastening between adjacent panels - similar to the way a conventional
timber crossing is installed. With a lagless installation, the field panels and gage panels are fastened
lengthwise to form three monolithic panels for the length of the crossing, with no fastening into the ties.
Different methods are used for panel-to-panel fastening. End angles or other end restraint devices must
be used to secure the crossing longitudinally. Vertical and lateral movement is prevented by the weight of
the fastened panels combined with confinement between the adjacent roadway and the rail for field
panels, and confinement between the rails for gage panels. With a lagless installation, flangeway fillers
must be used to keep gage panels secured away from the running rails. For most military applications,
lagless installation is suggested. Figure 7-12 shows a lagless concrete panel crossing in which adjacent
panels are fastened by a series of short welds.
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(15) Type 4C Sectional Monolithic Concrete (No Ties). These crossings essentially form a concrete
roadbed and crossing surface all in one complete unit. The rails rest on rubber pads in precast concrete
sections that form a solid bed. The concrete bed rests on a layer of crushed rock over a prepared
subgrade. These crossings may be well suited for rail service through an active container handling area
or where the track would normally run through a concrete paved area. They may also be warranted
where there is frequent heavy truck traffic and other crossing types have not withstood the traffic and
loadings. With these crossings, the rail is accessible by unbolting and removing the upper gage panels;
however, since the bed is solid, the track cannot be surfaced (tamped or raised) by conventional
methods. Surface correction or track raise must be done by either completely removing the crossing
sections and altering the subgrade, or for small corrections, by pressure injection of grout beneath the
sections. A subgrade and base material with adequate strength and drainage are essential for good long-
term performance of these crossings. These are the most expensive of the 10 crossing types
generally about twice the cost of a concrete panel (Type 4B) crossing.
(16) Type 5 Full Depth Rubber Crossing. Like the concrete panel crossings, these are made of
separate panels that rest on the ties and fit around the rails. Flangeway fillers are built into the panels.
While most are fastened to the ties with lags, some designs are available for a lagless installation.
Rubber crossings provide a flexible surface, but that flexibility prevents spreading heavier wheel loads
over a larger area and may lead to rutting in the tire paths where traffic is heavy. Snow plowing
operations can often damage rubber surfaces. The most durable are made completely from what is
termed “virgin” rubber. The other option - recycled or reconstituted rubber, is less expensive, but is not
suitable for larger traffic volumes or for heavy truck traffic.
e. Drainage. All crossings, for all surface types, require a subdrainage system similar to that shown in
figures 7-13 and 7-14. Geotextile surrounding the pipe filter is optional, but recommended in fine-particle
soils where clogging of the filter may occur.
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f. Track Design.
(1) As with other crossing surfaces, prefabricated concrete crossings do not act alone - their
performance depends on adequate support from the ballast and subgrade. Unless recently done, the
track, ballast section, and drainage system must first be rebuilt on a well-prepared subgrade before
installing the crossing. The drainage system must effectively transmit water outside the crossing limits.
(2) When crossings are built or rebuilt, all the ties in the crossing itself and for at least 20 ft beyond
each end of the crossing should be replaced. It is recommended that wood ties used in road crossings
be 7 x 9-in. in cross section. When prefabricated road crossings are installed, tie length and spacing
should conform with the installation requirements provided by the crossing manufacturer.
(3) For road crossings having heavy volumes of rail traffic and heavy vehicle traffic, it may be
desirable to install tie pads beneath the tie plates in the crossing area, as shown in figure 7-15. With
concrete panel crossings, full length pads should always be nailed to the ties with 1-in. roof nails to
properly support the panels; most manufacturers recommend this and supply the pads with the crossing
panels.
(4) In crossings on main running tracks, rail of 115 lb per yd or greater is preferred.
(5) As bolted rail joints in road crossings are often a maintenance problem, it is recommended that all
joints through the crossing and for 20 ft from either end of the crossing be welded. As an alternative, 80-ft
rails are readily available and may be used to eliminate joints in the crossing area.
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(6) If the track approaching the crossing is anchored, it is recommended that each tie in the crossing
be box anchored and that the normal anchoring pattern be maintained throughout the remainder of the
crossing area (20 ft off each end).
(7) Once a conventional crossing surface is in place, the track will be covered, making maintenance
difficult and costly, thus the track geometry (gage, surface and alignment) should be nearly perfect before
placing the crossing surface. The ballast in and around all the ties should be well compacted to prevent
settlement and movement of the crossing.
(8) Crossing flangeways should have a minimum width of 2.5 in. with a maximum width of 3 in. and
be at least 2 in. deep.
g. Road Approaches.
(1) To reduce the amount of runoff water directed toward the crossing, road approaches are best
sloped away from the crossing.
(2) To achieve smooth riding characteristics, road approach slopes are best kept within the limits
shown in figure 7-3, however, the difference in elevation between the railroad and the adjacent roadway
may require steeper approaches. Ascending road approaches must not be so steep that long flatbed
truck trailers, for example, with low ground clearance might contact the crossing. On descending road
approaches, gradients must not excessively lengthen stopping distances for vehicles approaching the
crossing including an allowance for wet or icy pavement.
(1) Specifications and Minimum Requirements. Specifications for the basic design and appearance
of crossing warning signs, pavement markings, and warning signals is given in Part 8 of the Manual of
Uniform Traffic Control Devices (USDOT-FHWA). All road crossings will have, at minimum, the standard
warning signs shown in the MUTCD. The need for additional signs, flashing lights, or gates, depends on
crossing visibility, traffic character and volume, crossing geometry, and accident and incident history, as
described below. Further guidance on providing crossing warnings and protection can be found in the
FHWA Railroad-Highway Grade Crossing Handbook.
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(2) Visibility. Clear visibility criteria for approaching and stopped vehicles is shown in figures 7-17
and 7-18, with distances A and B determined from table 7-2. A crossing is considered visually
unobstructed if the triangular area defined by distances A and B is sufficiently clear that a motorist can
see approaching trains anywhere within that field of view. Crossings that do not meet this clear visibility
criteria may require additional protection.
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(3) Traffic Character and Volume. Additional protection may be desirable at crossings that
experience two or more train movements per day and the product of train movements and average daily
vehicle traffic exceeds 3,000. This traffic threshold drops to 1,000 for crossings that are considered
visually obstructed, as defined above. Flashing lights (or even gates) should be considered for crossings
that experience several daily train movements, have heavy truck traffic or frequent hazardous material
traffic, and where clear visibility criteria are not met.
(4) Crossing Geometry. Crossings with a road to track angle of less than 45 degrees, or where the
road approaches the track at a steep grade, may call for additional protection.
(5) Accident and Incident History. Crossings that have experienced at least one serious accident,
some close-call incidents, and/or where incidents of motorists not obeying existing warnings are common,
should at least receive consideration for flashing lights, or gates if flashing lights are already present.
i. Whistle Posts.
(1) General. Whistle posts are signs located adjacent to the track to indicate that a road crossing is
ahead. They mark the point at which the standard horn signal for crossing approach must begin. Whistle
posts commonly show just a large letter “W” on their face, but various designs have been used. The
installation’s operating rules may designate the type of sign required.
(2) Location. Whistle posts are usually located on the right side of the track (when viewed facing the
crossing) at a distance that allows sufficient time to warn motorists that an engine, train, or track machine
is approaching the crossing. Designers should consult the state Department of Transportation and the
installation for requirements on whistle post location. The appropriate location will depend on factors that
include the speed of railroad traffic, speed of vehicle traffic, and the visibility at the crossing. A commonly
used guideline is that the crossing warning signal must begin sounding at least 20 seconds before an
engine, car, or track machine reaches the nearest end of the crossing.
2. BRIDGES.
a. Types. Railroad bridges may be classified by deck type: open deck or ballast deck. In a typical open
deck bridge, every fourth tie is bolted directly to the structure; thus in effect, the track becomes part of the
bridge. In a ballast deck bridge, a standard track and ballast section are supported on a solid floor. The
ballast deck has the advantage of allowing the track across the bridge to be lined and surfaced in the
same fashion as standard track.
b. Design Procedures. When a bridge is required, the bridge structure will be designed by a practicing
railroad bridge engineer in accordance with the AREMA Manual: chapter 7 for timber structures, chapter
8 for concrete structures, or chapter 15 for steel structures. Part 9 of AREMA chapter 15 provides
background and commentary on railroad bridge design practices.
c. Basis for Design. The design of railroad bridges is based on two main factors: the magnitude of
loads applied to the bridge and the expected level of traffic (or number of stress cycles) over the design
life of the bridge. One stress (or load) cycle is defined by one application and release of loading on a
bridge member.
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(1) The design live load is expressed using the Cooper E series loading configuration adopted by the
AREMA about 1905. Figure 7-19 illustrates a unit E1 axle loading. Higher loadings are obtained by
multiplying each load by the same constant; wheel spacings do not change. Thus, an E60 loading would
show the largest axle loads as 60,000 lb.
(2) To allow an easy comparison of permissible in-service loading (or rating) over the life of a bridge
with the loads used in their original design, and to compare the effect of different engine and car loads for
either design or rating, the railroad industry kept the basic Cooper load configuration and used it to
represent all bridge loadings and bridge capacity ratings.
(1) In use, the loading from a train of typical (or heaviest common) cars (the design train) is converted
to the Cooper E loading that would have the same effect on the bridge.
(2) For a given design train, the equivalent Cooper loading (E value) will vary with train operating
speed, bridge span length, and bridge design.
(3) As the actual load distribution from current trains will differ from the Cooper configuration, the
equivalent Cooper loading will not be a constant for all bridge components. Figure 7-20 shows the
relationship between equivalent Cooper loading (at 60 mph) and span length for one type of steel bridge
and for the loading shown in figure 7-21. As an example, figure 7-20 indicates that, for a 60-ft span, the
train in figure 7-21 produces an effect equivalent to a Cooper E48 load with respect to floor beam
reaction, an E57 load with respect to end shear, and an E60 load with respect to bending moment.
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f. AREMA Standard Fatigue Stress Cycles. For fatigue, the standard AREMA design assumes stress
cycles from 100 trains per day, with 150 cars each (loaded up to 315,000 lb gross weight), traveling at
speeds up to 60 mph, every day for 80 years.
(1) As the standard AREMA fatigue loading is exceptionally high for most military railroad lines,
designers should use the design live loading in table 7-3, which is based on the recommendations in
chapter 15, part 9 of the AREMA Manual. This loading is a general recommendation for span lengths up
to about 75 ft. Actual design live loading may be adjusted to accommodate span length, structure design
characteristics, and other variables.
(2) Traffic over most military railroad bridges does not exceed 5 MGT per year, thus the 0-5 MGT
category of table 6-8 usually applies. To exceed this lower level, a bridge would have to experience an
average annual passage of 38,000 loaded 100-ton cars (104 per day) or 26,500 loaded 140-ton cars (73
per day) throughout the life of the bridge.
h. Walkways. When bridges are located in areas where switching movements are made and at other
locations where it is either useful or necessary for people to walk alongside a train (or cut of cars),
walkways must be provided on at least one side of a bridge. Where people must have access to both
sides of the track when a bridge is occupied, walkways must be provided on both sides. (Workers must
never be expected to cross the track by going under cars, crossing over couplers, or climbing over cars).
i. Tie Pads. On open deck bridges, installation of rubber tie pads between the tie and tie plate is
recommended.
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CHAPTER 8
TERMINALS
1. INTRODUCTION.
a. This chapter addresses the design of railroad terminal and support facilities that are primarily
intended to support unit mobilization. (Design and planning information for terminals at supply depots or
ammunition plants should be obtained from the Construction Branch of the Army Materiel Command).
(1) Loading and unloading: tracked and wheeled vehicles, containers, equipment, ammunition, fuel,
and general supplies.
(2) Holding: empty cars waiting to be loaded or loaded cars waiting to be unloaded, or cars that
require repair or adjustment of the load or tie-downs.
(3) Switching: maneuvering cars around the terminal, re-ordering or turning a line of cars, or allowing
an engine to get on either side of a cut of cars.
(4) Interchange: holding loaded or empty cars waiting to be picked up by the connecting commercial
carrier, or cars delivered to the installation by the commercial carrier.
a. In the siting and layout of terminals, the designer must consider space requirements, logistics,
security, safety, the presence and use of existing facilities, character of the terrain and natural drainage,
as well as mission requirements. When locating a terminal area, a site must be selected that has the
correct size, shape, and orientation so that it provides convenient access for both vehicles and railroad
service.
b. Where space is very limited, two or more separate terminals may be considered to provide sufficient
capacity. This option may result in better traffic flow and less congestion than might occur at a single site,
but might also complicate command and control of loading operations and security arrangements.
3. TRACK DESIGN.
(1) For through running tracks in terminal areas, use table 2-2, “10 MPH or Less.”
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(2) For tracks where cars are simply placed and removed (as distinguished from those where general
running or back and forth switching movements frequently occur) such as warehouse sidings and spur
tracks (dead end tracks), including loading and storage tracks, use table 2-2, “Light Use.”
(3) For run-around tracks, passing sidings, yard tracks, wyes, balloon tracks, or other tracks where
switching movements commonly occur, use table 2-2, “10 MPH or Less.”
b. Gradients.
(1) Gradients on running tracks through a terminal should not exceed 1.0 percent.
(2) On auxiliary tracks where cars may be temporarily left standing during switching, gradients should
generally not exceed 0.3 percent.
(3) Gradients on tracks where cars will be left standing for 1 or more days, such as loading, yard, and
storage tracks, should generally not exceed 0.2 percent, with a maximum allowable of 0.3 percent. It is
desirable to have these tracks slope away from the main track (or connecting track). Thus, if hand brakes
do not properly hold on cars, they would not roll toward the main track.
(4) Yards are best graded as shown figure 8-1, with tracks sloping toward the center, where storm
drainage is provided. This grading arrangement will prevent cars from accidentally rolling toward either
ladder track and will also facilitate drainage by collecting runoff at the center of the yard.
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c. Vertical Curves.
(1) Maximum vertical curvature in a summit should normally be 0.4 percent change in grade in 100 ft,
but may be as high as 2.0 percent change entering (or exiting) loading, storage, or other spur (dead end)
tracks. Corresponding values for sags are 0.2 and 1.2, respectively. Where track space is available and
no interference occurs, use the lower values. The higher values are sometimes needed to avoid putting
vertical curvature through a turnout, road crossing, or alongside a loading dock.
(2) It is best to avoid locating turnouts in vertical curves as sometimes problems with point fit or
operation result.
d. Horizontal Curves. Track curvature should not exceed 12 degrees in terminal areas. Where number
9 or 10 turnouts are the smallest recommended size, curvature elsewhere on the track should not exceed
10 degrees.
e. Track Layout. Design guidance for the layout of turnouts, curves, ladder tracks, and track
connections is covered in chapter 6.
a. As terminal track is typically closely spaced near loading docks, buildings, access roads, parking and
staging areas, parallel tracks, etc., awareness of clearance requirements is especially important.
Clearance requirements are covered in paragraph 6-4.
b. The maximum usable track length for positioning cars extends from the end of track (for spur tracks)
to the clearance point, or (for sidings) between two clearance points, as indicated in figure 6-9.
5. VEHICLE TERMINALS.
a. Purpose and Facility Requirements. A vehicle loading terminal is generally designed for transferring
tracked or wheeled vehicles on or off flatcars, or in the case of smaller wheeled vehicles, auto racks
(trilevel cars). A vehicle terminal will contain: loading tracks to position the flatcars; a nearby staging area
to hold the vehicles; end ramps or multilevel ramps for transferring the vehicles to and from the railroad
cars; a crew and communications facility; and a storage building for blocking and bracing material.
b. Track Spacing. When the loading tracks in a vehicle terminal are laid out parallel to each other (as
is often the case), the tracks should be spaced far enough apart to accommodate one-way vehicle traffic,
as shown in figure 8-2. If cranes are required between the loading tracks, every other track should be
spaced at 50 ft.
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(1) For vehicle loading, strings of between 10 and 20 cars are most effectively handled at a time: the
lower limit of 10 to minimize switching requirements and the upper limit of 20 for efficient loading. Thus,
each loading track should have a tangent length extending from 10 to 20 car lengths from the loading
ramp, as shown in figure 8-3.
Figure 8-3. Track and Approach Road Lengths for Vehicle Loading
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(2) The number of tracks required can be determined from the traffic and mission information covered
in chapter 2, the space available in the terminal area, and the criteria for track length above.
d. Staging Area
(1) The size and location of a staging area depend on terrain characteristics and availability of space.
It is recommended that a staging area be located as close to the loading area as possible to facilitate
better command and control. The staging area should be large enough to stage one full loading cycle of
vehicular cargo, thus a loading terminal with a capacity of 50 flatcars would require a staging area with a
capacity of 50 carloads of vehicles.
(2) The staging area must include an access road (or approach) leading up to the loading ramp,
which is straight and in line with the ramp for at least the full length of the longest vehicle to be loaded. If
practical, this in-line approach should be twice the length of the longest vehicle to ensure that a vehicle
can always be positioned ready to load as the first vehicle is driven up the ramp. It is also preferable that
this road not be directly adjacent to any track to avoid a dust cloud from the approaching vehicles
reducing the view of loading operations.
(3) For operation after dark, staging areas need to be lighted with “parking lot” type lighting. Fencing
may also be required if the cargo is security sensitive. (see paragraph 13).
(1) Rapid loading of larger vehicles onto flatcars is best accomplished with permanent end ramps
constructed at the end of the loading tracks. While end ramps may be constructed with concrete, wood,
steel or earth, they must be capable of supporting the largest and heaviest vehicles being mobilized
(typically, a main battle tank).
(2) A general reinforced concrete ramp design is shown in figure 8-4. More detailed guidance should
be obtained from the Army Transportation Systems Center (CENWO-ED-TX, or at website:
http://pavement.wes.army.mil/pcase.html/standard.html).
(a) Allow an M-1 Abrams tank to be driven onto a flatcar having the lowest platform height used in
commercial railroad service. (Note: It is safer and easier to drive a vehicle from a lower ramp level to a
higher flatcar level than vice-versa).
(b) Provide ample width to enable guides to walk on both sides of an M-1 tank.
(c) Provide sufficient level platform length to allow a tank to be in a completely horizontal position
prior to proceeding onto the railcar.
(d) Have the proper transition between the incline and the level platform so that a tank will not “high
center” itself while negotiating the ramp.
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(4) To make vehicle loading easy, it is desirable to have the end of the car very close to the ramp
platform. It is also necessary to protect both the car and the ramp from impact damage when cars are
being positioned at the ramp. As car designs vary (draft gear length, amount of end overhang, position of
uncoupling lever, etc.), this protection cannot be reliably provided by fastening wheel stops to the track.
(5) The design in figure 8-4 incorporates a cut-out at the front of the ramp at the height of the car
coupler. Behind the cut-out is a concrete block separated from the remaining ramp structure with
cushioning (expansion joint) material. This concrete bumper block reduces the likelihood of impact
damage to the ramp.
(6) Other shock absorbing designs and devices can be used as well, including commercial railcar
buffers. The designer should select the method best suited for the particular application. While the
concrete bumper block could easily be incorporated into new construction, it might prove impractical
during rehabilitation if the existing ramp platform will not be extensively modified.
(7) To permit wheeled vehicles to cross the gap between the ramp and the flatcar, spanner boards
may be necessary; tracked vehicles do not require spanner boards. Thus, if fixed spanners are used,
they should be detachable so that they will not interfere with the loading and unloading of tracked
vehicles.
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(1) If an installation has a requirement to mobilize large quantities of small wheeled vehicles, it is
recommended that multilevel ramps be used to load bi-level and tri-level railcars. These ramps are
portable pieces of equipment that can either be purchased and maintained by the installation or leased
from a commercial railroad when needed. Like end ramps, multilevel ramps are positioned at the end of
a track spur. A typical multilevel ramp is shown in figure 8-5.
(2) It is important that the ground underneath a multilevel ramp be level and capable of bearing the
weight of the ramp plus the heaviest vehicle being loaded. A Portland cement concrete pad is
recommended to ensure good ramp stability.
a. Permanent side ramps, parallel to the track, are recommended for loading break bulk cargo into
boxcars. For staging cargo, large open areas are needed surrounding the ramps. Thus, where several
parallel tracks run through a terminal, the ramps should be constructed along the outermost tracks.
(1) The ramp must be capable of supporting the weight of a fully loaded 4,000-lb forklift.
(2) The ramp platform must allow sufficient area for a forklift to maneuver.
(3) The ramp platform must be at a height convenient for a forklift to drive into a boxcar on the
adjacent track as well as into a truck docked at the ramp.
(4) The ramp incline angle must be small enough for a forklift to easily negotiate it.
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7. CONTAINER TERMINALS.
a. A container loading area includes at least one track spur with sufficient space on one or both sides of
the track for a container handler to operate. The required size of a container terminal is related primarily
to the largest volume of cargo that must be handled in the shortest time period. General plans and
additional design guidance for container terminals can be found in the AREMA manual.
(1) Include at least one straight spur track long enough to hold a minimum of five flatcars.
(2) Have one entrance and one exit to the yard area located to establish a one-way circular traffic
flow.
(3) Have sufficient open area for a Rough Terrain Container Handler (RTCH) to efficiently operate.
(4) Have a surface that will support the weight of a RTCH carrying a loaded 40-ft container.
(5) For night operations, have “Parking Lot” type lighting positioned so that the light poles will not
interfere with the operation of the RTCH or truck-trailers operating inside the yard.
(6) If a secured area is required, have a perimeter fence with a sally port across each track entry and
exit. (See paragraph 13, chapter 8.)
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8. AMMUNITION TERMINALS.
a. An ammunition terminal should be designed to meet the required shipping volume at the installation.
The terminal may be set up as either a break bulk terminal (paragraph 6) or a container terminal
(paragraph 7).
b. In addition to the usual terminal requirements, the following safety standards must be incorporated
into the design:
(1) Generally, yards will be laid out on a unit car-group basis with each car-group separated by the
applicable above-ground magazine distance.
(2) If the yard is formed by two parallel ladder tracks connected by diagonal spurs, the parallel tracks
and the diagonal spurs will be separated by the applicable above-ground magazine distance for the unit-
group quantities of high explosive.
(3) If the yard is a tree arrangement, consisting of a center ladder track with diagonal dead-end spurs
projecting from each side at alternate intervals, the spurs shall be separated by the applicable above-
ground distance for the net quantity of high explosives in the cars on the spurs.
(4) Railroad yards will be separated from other facilities by the applicable Quantity-Distance
standards.
(1) If loaded ammunition cars will stay in a terminal area for sufficient time, the areas should be
completely fenced, with sally ports across all tracks entering the area, and have locking pedestrian and
vehicular gates. (See paragraph 13.)
(2) The area should be lighted with “parking lot” type lighting.
(3) If guard towers are required, they should be positioned to allow observation of the entire
ammunition loading area.
9. POL TERMINALS.
a. The design of POL handling and storage areas is regulated by Federal, State, and local
environmental protection agencies as well as State and local fire marshal’s. These agencies should be
contacted when designing POL facilities so that the appropriate standards can be incorporated into the
design.
b. POL handling and storage areas should be completely fenced, with sally ports across all tracks
entering the area, and have locking pedestrian and vehicular gates (see paragraph 13). These areas
should also be lighted with “parking lot” type lighting.
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a. Purpose. The interchange area (or yard) consists of one or more tracks used for the transfer of cars
between the installation’s railroad and the connecting commercial carrier. These tracks are usually
located at or near the junction of the two railroads.
b. Arrangement. Figure 8-7 shows an example car interchange yard. In this arrangement, one (or
both) of the outer two tracks would normally be designated as a running track and left clear of cars. The
other tracks would be of sufficient combined length to handle the largest expected number of cars to
come in or go out at any one time.
c. Running Track.
(1) An open running track through the interchange yard will allow the installation’s or commercial
railroad’s engine access to either end of each interchange track, and otherwise leaves an unblocked
connection between the two railroads. The running track can also be used temporarily for switching. This
would make it easier to rearrange the cars, if needed, or to pull out selected cars from any track.
(2) At installations with frequent grade crossings or where at least one heavily traveled road crosses
the tracks at grade (especially if the crossing angle is less than 45 degrees), access to either end of a cut
of cars is usually required. This will permit the engine to always be at the front of a train (pulling the cars
rather than pushing), in either direction of travel providing much better visibility and safety at road
crossings.
d. Set-Out Track. It is sometimes useful to allow an additional track (or perhaps a short spur) at an
interchange yard for special over-size loads and for cars needing repair, which should be placed only at
the end of a train, or for other special movements that need separate handling.
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e. Derails.
(1) In addition to being good practice, the connecting carrier will usually require that a derail be
placed on the track leading to its line, along with a sufficient safe length of track between the derail and
the junction. The derail is intended to prevent cars from accidentally rolling onto (or blocking) the carrier’s
track. As an option, derails may be desirable at the installation end of the interchange tracks.
(2) While derails themselves are not a design issue, their location is. Without a sufficient length of
track between a derail and the clearance point of the track being protected, a derail will be nearly useless.
The designer must allow for this safe track length as an addition to the length of track required for car
holding and switching space.
(3) The safe track length needed past a derail will vary with the grade of the yard tracks and the
configuration of the junction area. The designer should consult the connecting commercial carrier’s
engineering department for guidance on placing a derail to protect their track.
f. Security. If the interchange yard is outside the main installation area or otherwise not located within
constant view, it is recommended that the area be completely enclosed with a security fence, including
lockable sally ports across the tracks (see paragraph 13). Lighting and guard towers may also be
required if security-sensitive cargo is regularly handled.
a. Purpose.
(1) Yard and storage tracks are intended for, respectively, the short and long term holding of cars.
Yard capacity is needed at least equal to the maximum number of cars that the installation is expected to
handle at one time. Storage capacity must at least accommodate the number of cars to be kept at the
installation over a longer term. Loading tracks are not considered available for storage, unless cars are
pre-positioned on them for loading.
(2) Auxiliary tracks include sidings, wyes, balloon tracks, crossovers, tail tracks, and other tracks
used for switching and maneuvering cars, allowing engines and cars to clear the main track for other
movements (as in a second engine switching or delivering cars), or to allow an engine to get around the
other side of a string of cars.
b. Yard Tracks.
(1) Especially where the interchange with the commercial carrier is several miles from the loading
sites, or where loading sites are within a separate a secure area, a yard may be required. A yard is
typically several parallel tracks, as in figure 8-1, which serve as a holding area for cars waiting to be
loaded or delivered to the interchange area.
(2) An example is used here of an installation with a mobilization plan calling for 60 loaded cars to be
picked up each day (and 60 empties to be delivered) by the commercial carrier, and with loading sites (12
miles from the interchange point) that can accommodate 30 cars at one time. This installation will likely
need a yard that will hold at least the second 30 cars waiting to be loaded, and subsequently, the first 30
after they are loaded — to make room for the second 30 at the loading sites.
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c. Storage Tracks. Storage tracks or a storage yard may appear as shown in figure 8-1, but are often
designed as spur (dead end) tracks off a single ladder, as indicated in the lower left corner of figure 8-8.
(It is usually not essential to have access to either end of cars in storage, thus saving the cost and
maintenance of turnouts at one end of storage tracks).
d. Auxiliary Tracks.
(1) Figure 8-8 shows common auxiliary tracks. Their application is explained below.
(2) Sidings are used for temporarily holding extra cars, or holding part of a string of cars while the rest
are being switched, or to allow an engine to get around to the other end of a string of cars.
(3) Crossovers can be used as a shortcut between routes or to allow an engine to get around a string
of cars. In figure 8-8, the crossover, for example, allows trains from the interchange yard access to the
siding without having to go south to the warehouse track and then back north again, thus the crossover
allows the siding to be conveniently used from either track. In addition, when handling a string of cars
longer than will fit on the siding, the cars may be left south of the crossover on either track, with the
engine then using the crossover to get to the other track and then around to the opposite end of the cars.
(4) At least one wye or balloon track is almost always needed at military installations. These tracks
allow engines and cars to be turned around. This capability is required for most effective use of vehicle
terminals. If cars are delivered to the installation such that the vehicles on them would be facing away
(backward) from the loading ramps, the cars need to be turned so the vehicles can be driven in a forward
direction off the cars. Of the two types of turning tracks, wyes are most common, as they require far less
space than balloon tracks. Balloon tracks are typically used if space allows them to conveniently encircle
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other facilities, thus not requiring a large land area just for the balloon track. Balloon tracks have the
advantages over wyes of requiring only one turnout and a single movement to accomplish the turn. Wyes
require a backward movement to complete a turn, as well as throwing more switches. Wyes are often
created by installing the third leg where a junction already exists (or is required). In figure 8-8, for
example, the wye also allows convenient access to the warehouse track from either north or south
directions.
(5) When a yard or siding is located near the end of a route, a tail track is often added to allow
switching from the far end of the yard or siding. A tail track is most useful if it is at least three car lengths
longer than the siding or the longest track in the yard. Figure 8-8 shows a tail track north of the container
terminal.
a. Purpose. In each terminal area buildings may be needed for storage, shelter, and for other
purposes. At vehicle terminals, buildings will be needed for a crew and communications facility and for
blocking and bracing storage.
b. Crew and Communications Facility. The following should be considered when designing a crew and
communications facility:
(1) The building should be located as close to the loading area as possible without interfering with the
flow of vehicles between the staging areas and the loading ramps.
(2) The building should be large enough to accommodate the billeting of a rail loading crew.
(3) A telephone and a public address system would facilitate better command and control.
c. Blocking and Bracing Storage Facility. The following should be considered when designing a
blocking and bracing storage facility:
(1) The building should be located as close to the loading tracks as possible. Co-location with the
crew and communications facility may be desirable.
(2) The building needs to be large enough to hold the blocking and bracing material required for one
cycle of rail loading, that is, enough material for the maximum car capacity of the terminal.
a. Requirement. Security fencing may be required to surround facilities within a terminal, or even a
complete terminal area. These fences are typically standard chain-link construction (i.e., 6-ft FE-5),
however a more secure fence (FE-6 or FE-7) may be needed. The installation Physical Security Officer
should be consulted to ensure that proper security requirements are considered in the design. All gates
and sally ports should be equipped with locking hardware.
b. Sally Ports. When designing a sally port, the following should be considered:
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(1) The sally port must prevent unauthorized entry by both pedestrians and vehicles.
(2) The sally port must open to a minimum width of 17 ft to allow cars to pass through.
(3) Culverts draining the track through a sally port should have security bars in them.
(4) It is recommended that a drainage ditch security barrier be constructed using concrete. This will
provide both a headwall for the culvert and a foundation to mount rollers for the sliding gate.
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CHAPTER 9
CONSTRUCTION
1. CONSTRUCTION SURVEY.
a. The purpose of the construction survey is to mark the route to guide construction. It may be done in
two stages, especially in areas where significant amounts of earthwork and grading are needed. In the
first stage, enough marks are placed to define the basic track grade and drainage ditches. During this
stage, culvert locations should be checked to ensure that final track elevation will allow room for sufficient
cover over the culverts.
b. In the second stage, stakes are set for final grading and construction, including spiral and curve
locations, grade and side slope markers, bridge abutments, culvert centerlines, and frog and switch point
locations for turnouts. It is best to set stakes only a short time before they will be needed, to minimize the
chances of them being disturbed. Guidance on stake setting is given in table 9-1.
2. INSPECTING MATERIALS.
a. Inspect Before Installation. It is recommended that all materials (new or secondhand) be inspected
before work begins. If there are questions concerning the materials, it is much better to handle them
before the material has been installed.
b. Ties. Although inspection of the ties at the plant is preferred, this is not always possible. However,
upon delivery to the project site, all ties will be inspected to ensure compliance with the project
specifications. Ties not meeting the specifications will be rejected. The inspector should receive a copy
of the treatment report from the treatment plant and check that a date and manufacturer’s brand are
present on the ties.
c. Relay Rail. When relay rail is bought for the project, it will be inspected for wear and external defects
(end batter, engine burns, etc.), per project specifications. Standard gages are available to check wear.
a. When removing rail and other track material (OTM) for stockpile at an installation or transfer to
another installation, rail of like weight and section (and OTM of like size and design) should be stacked
neatly together. Normally, spikes will not be salvaged.
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b. Care should be taken when removing rail and OTM to prevent damage to usable materials. A torch
should never be used to cut rail, joint bars, or other salvageable materials during removal.
(1) The maximum time for exposure of geotextiles to sunlight, from removal of the protective shipping
cover to final placement, should be no more than 7 days.
(2) Equipment should not be allowed to operate over an area covered with geotextile unless there is
at least a 6-in. cover of sub-ballast or ballast.
(3) Surface drainage should be directed away from geotextile material to help prevent contamination.
(4) The minimum overlap distance in the longitudinal and transverse directions should be 3 ft.
c. Drainage.
(1) Drainage and other earthwork near the track should be completed before final subgrade
preparation begins; this minimizes the likelihood of disturbing the final subgrade surface or getting soil in
the ballast, and also provides a properly draining work site.
(2) Subdrainage installations should be checked before being covered and ditch elevations and
sections checked before track work begins.
5. TRACK CONSTRUCTION.
a. Sub-ballast Placement.
(1) On new construction, the subgrade surface should be inspected before geotextile or sub-ballast is
placed.
(2) Sub-ballast is placed on the prepared subgrade and compacted to provide a working surface for
track construction. Sub-ballast should be placed to the lines of grade shown on the project plans and
compacted to 95 percent of ASTM D 1557 laboratory maximum dry density.
(3) Place the line rail on the tie plates and spike in place.
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(5) Install the opposite rail by first checking the gage and spiking every fourth tie and then spiking the
remaining ties.
(6) Install rail anchors at this stage, or after final surface (but before dressing ballast).
(8) Lift and tamp track to about 1 in. below final elevation, in 3 to 4-in. lifts, adding ballast as needed
after each lift. The tamping machine will also align the track and place the proper superelevation in the
curves during this operation.
(10) If practical, run over track with at least 10 passes of an engine (or engine with heaviest loaded
cars) before the final surface.
c. Ballast Unloading.
(1) Large amounts of ballast (several hundred tons or more) are most efficiently unloaded using
railroad hoppers. For installations having a locomotive, the provision of a government locomotive and
crew to move the ballast cars for the contractor may result in a lower unit cost for ballast distribution.
Appropriate arrangements should be provided in the contract documents and during the pre-construction
meetings to ensure effective use of government locomotive to assist the contractor in placing the ballast.
(2) When trucks or other automotive equipment are used to place ballast, care should be taken to
prevent rutting that would impair drainage of the sub-ballast or subgrade. Any ruts that are formed should
be leveled and graded to drain prior to the continuation of ballast placement.
d. Rail Installation.
(1) Rails should be laid one at a time with allowance for expansion provided between the rail ends in
accordance with table 9-2.
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(2) Gaps between rail ends and insulated joints should only be sufficient to permit insertion of
standard end posts.
(3) During rail laying, a standard rail thermometers should be used to determine the rail temperature.
The thermometer should be laid close to the web on the side of the rail base that is shaded from the sun,
in advance of the laying operation and left there long enough to accurately record the temperature.
(1) When relay rail is used, care should be exercised in matching adjacent rails to minimize joint
mismatch. Any mismatch at the rail ends must be ground or welded to provide proper match. Building up
a worn end by welding may only be done by people with the proper training, experience, and equipment
to perform this operation.
(2) Relay rail will be laid with the previous gage side facing out (old field side becoming the new gage
side) unless required to match existing wear patterns. Where either overflow or a nearly square edge is
left on the new gage side, this edge must be ground to a rounded profile - similar to that found on new
rail.
(1) During the surfacing operation, every tie should receive two full insertions of the tamping heads at
each lift. The joint ties, on the joint side only, should get an additional insertion.
(2) If raising the track creates voids under the tie centers, the void space should be filled lightly but
not tamped.
(3) Worn tamping feet on a tamping machine will not properly compact ballast under the ties.
(4) Ties that pull loose during surfacing should be lifted and plugged, or replaced, spiked, and re-
tamped.
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(5) Track at the ends of open deck bridges should be maintained at the same grade as the track on
the bridge for at least 25 ft beyond bridge abutments and then transitioned smoothly to meet established
track grades.
(6) Track should not be tamped in frozen ballast conditions or if snow cover is present.
g. Switch Stand Installation. The switch stand is normally installed so that when the switch is lined for
the normal (main) route, the connecting rod keeps the point closed with a pulling (rather than a pushing)
force. In most cases, this will mean installing the stand on the diverging side of the turnout. When a
ground throw stand is used, the handle should point toward the frog when the switch is lined for the
normal route.
a. Many installations and offices do not have inspectors who are knowledgeable and experienced in
railroad work. In these cases it is strongly recommended that inspection services be obtained from an
engineering firm that specializes in railroad design and construction.
b. As initial work is often covered over in final stages, it is strongly recommended that railroad work be
inspected throughout the process.
c. All relay rail should be ultrasonically tested after installation. Scheduling with a contractor specialized
in this operation should be done well in advance to assure availability at the least cost.
7. AS-BUILT AND FINAL DRAWINGS. Upon completion of construction, a set of red-line drawings
should be given to the installation engineer. Final as-built drawings will be produced showing the actual
track locations, grades, curvatures and complete curve data, rail weight and section, grade crossing
locations and types, crossing signal circuitry and layout, drainage structures, and other aspects of track
construction. These drawings will be given to the installation engineer within 6 months after construction
has been completed.
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APPENDIX A
REFERENCES
Government Publications
Army:
Army/Air Force:
Non-government Publications
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Manual for Railway Engineering, Volumes I and II, Published Annually, Washington, DC
Annual Book of ASTM Standards, Volume 04.08 “Soil and Rock, Building Stones, Geotextiles,”
Hay, William W. 1982. Railroad Engineering. John Wiley & Sons, New York, NY
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APPENDIX B
RULING GRADE - EXAMPLE PROBLEM
This example of determining a trial ruling grade for a new railroad line follows the material presented in
A railroad line is to be built from the terminal serving the new training area at Fort Example to the nearest
commercial railroad, about 15 miles away. The most critical traffic, and heaviest loads, will be M-1 tanks
on flatcars. (Each car is 70 feet long and has a maximum loaded weight of 187 tons riding on 6 axles).
To handle movements during larger training exercises and mobilization, the installation wants to use an
engine from the connecting railroad which will be capable of hauling 25 loaded flats over the line at 15
MPH minimum speed. The connecting railroad expects to have a 3,000 HP, 170 ton (340,000 pound)
locomotive available when needed. (Tractive effort curves are not available for either locomotive. For
The designer must now determine the maximum effective gradient (and grade length) on the new line to
accommodate these train movements. The first step is to determine how much traction force is available
(using chapter 3, paragraph 5c). Available traction force will be the lesser of locomotive tractive effort or
traction at the wheel-rail adhesion limit, for the commercial locomotive:
TE =60,000 lbs
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NCar = 25
= 0.47%
Thus, grades of 1820 feet or longer would have to be limited to an effective gradient of 0.47%.From a
brief review of contour maps of the area through which the route would run, the designer believes the
route may require grades much steeper than 0.47% to keep construction costs at an acceptable level.
One way to accommodate the desire to move single trains of 25 loaded flats at a minimum speed of 15
MPH and allow for a steeper ruling grade is to use the installation's engine and commercial engine
together and drop the travel speed up the ruling grade to 10 mph, which should further increase the
tractive effort available. To offset the loss in speed up the ruling grade, other portions of the route might
be constructed to accommodate higher speeds - perhaps 25 to 30 mph. A check of this possibility shows
the following:
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NCar = 25
= 1.16%
Thus, if this revised arrangement is acceptable, grades of 1890 feet or longer could have an effective
gradient as high as 1.16%. Table B-1 shows the curve compensation for curves on this grade.
From the table, if a 5 degree curve was located within the ruling grade, the constructed (actual)
gradient through that curve must be limited to 0.96% to keep the effective gradient within 1.16%.
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APPENDIX C
This sample report illustrates the type of information and level of detail suggested for an analysis of a
military railroad network in preparation for rehabilitation work. The material that explains how the work is
normally conducted is included for the benefit of the reader and would not be necessary in an actual
rehabilitation plan.
2) A problem/defect analysis.
The material in appendix C covers the structural evaluation that is normally required in a rehabilitation
plan. The operational evaluation (not detailed here) should follow the guidance in chapter 5, paragraph 5.
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SUMMARY
Examination of the railroad network at Fort Example showed the following major deficiencies:
3) Turnout defects.
The work plan was divided into 2 phases, with a total project cost of approximately $970,000.
Phase 1 (to be accomplished first) covers the rehabilitation of the primary route and sidings extending
from the connection with the commercial carrier to the end of the East Line. This work is estimated to
Phase 2 covers rehabilitation of most of the remainder of the track network: the south half of the Main
Line, the West Line, and the North Line. This work is estimated to cost approximately $420,000.
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The remedial work described in this report would restore the railroad network to a fully functional level, in
a cost-effective manner. Remedial work has been specified only for those sections of track where the
work is most needed. Tracks with no current use are not included in the plan.
The work plan has been designed so that when completed, the railroad network would require only
normal routine maintenance to keep it fully functional for the foreseeable future.
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CONTENTS
SUMMARY C-2
1 INTRODUCTION C-7
Background C-7
Objectives C-7
Approach C-8
Scope C-8
Rail C-11
Plates/Fastenings C-12
Ties C-12
Ballast C-13
Drainage/Subgrade C-13
Vegetation C-14
Turnouts C-14
Bridges C-16
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General C-22
Phase 1 C-23
Phase 2 C-23
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Figures
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1 INTRODUCTION
Background
This rehabilitation plan was prompted by reports that portions of the Fort Example railroad network were
in a general deteriorated condition and that results of the structural evaluation program indicated
structural deficiencies in several stretches of track. These conditions were confirmed by the team
Objectives
1) Document the track and roadway deficiencies found during the recent field inspection, both by type
and extent.
The corrective work included in the plan is intended to restore the railroad network in a cost-effective
manner. Thus, not all sections of track in the network are included in the plan, and each type of remedial
work is specified only for those sections most in need. Further, corrective work is specified only to the
extent that will restore the long term function of the track. Tie replacement estimates are based on
improving tie condition to the point where installation trackage can function well for 5 years before the
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Approach
A three-person team visited the installation to examine the railroad network. During this visit, all track
(except the short piece leading to the old coal/gravel chute) was examined by walking inspection, and all
primary routes were traveled with the installation’s 120-ton locomotive. In addition, those who were
familiar with the track were interviewed about deficiencies they had observed and about track work
Scope
This report is intended to assist in the preparation of contract specifications for remedial track work.
Neither the field investigation nor this report is intended to cover every detail required for proper
restoration of the railroad network, nor is this report intended to be a substitute for a complete statement
of work and specifications. There are, in fact, several items noted that will require additional examination
and decisions before a complete and final remedial work plan can be established.
Accompanying this report are both general and detailed track maps and photographs (with notes)
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2 OPERATIONAL EVALUATION
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The railroad network connects with the _______________ Railway about 10 miles east of (City), (State).
Of the 19.95 miles of track, 9.62 miles are primary routes, 3.43 miles are in the classification yard, and
6.90 miles are loading and storage sidings and auxiliary tracks. A track diagram is shown in figure D-1,
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Incoming cars are generally brought to the classification yard by the commercial carrier. There, one of
the two installation locomotives will pick up the cars and deliver them to the appropriate area for loading
or unloading. These cars are then brought back to the yard to be picked up by the commercial carrier.
Below is a description of the railroad network, by component, reflecting conditions found during the
investigation.
Rail
a. Description: 80 percent of the rail is 90 lb (weight per yard of length) and manufactured between l909
and l924. The remaining 20 percent is 85 lb. The 85 lb. rail is primarily in Tracks 4 through 14 of the
classification yard, the end of the North Line, and on Track A5 in the Administration Area (leading to the
engine house). All rail was manufactured before the control cooling process was in use. (The control
cooling process, now standard practice, greatly reduces the formation of internal defects).
b. General Condition: The rail is generally in good condition, neither excessively or unevenly worn. Very
few pieces show serious end batter or surface bending. Likewise, obvious external defects, serious
corrosion (except, perhaps in crossings - where the whole rail is not visible), and breaks are rare.
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Plates/Fastenings
a. Plates: Almost all track has single shoulder tie plates. These are in adequate condition, with relatively
b. Joints: Joint bars are in good condition, with few excessively worn, cracked, or broken. However,
many bolts are missing, loose, or not fully tightened. Of those that are not fully tightened, many appear to
c. Spikes: Spikes are in good condition, however some are not fully driven or have worked their way up
in the last few years. Also, spikes have been frequently driven through angle bar base slots, which is no
d. Anchors: A portion of the primary routes have rail anchors. However, most of the anchors are far
enough from the ties that they can provide no benefit in restraining longitudinal rail movement.
Ties
a. Description: Most older ties are 6 x 8-in. in cross section. Most of the ties installed during the tie
b. General Condition: Tie condition is generally fair to good. Areas that did not receive ties during the
On the Main Line, approximately between stations 200+00 and 250+00, there are many skewed,
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Ballast
a. Description: Most track in the primary routes has ballast composed of a low density, finely crushed
volcanic material or slag, or cinders mixed with earth. Some stretches of track appear to have no real
ballast section, leaving the track essentially sitting directly on the subgrade.
During recent track work, some new ballast was applied. This ballast is crushed rock of about AREMA 3
or 4 gradation and appears to be good, hard material. However, in most cases, this ballast is only a
surface treatment, helping to fill in cribs (the spaces between the ties) and fill out the shoulders (at the
b. General Condition: The cinder/volcanic/earth material seems to drain adequately, but apparently
provides insufficient lateral or longitudinal stability to the track. (See Track Geometry section below).
Additionally, this material is not sufficiently dense and stable to resist washout from heavy rains. (See
Drainage/Subgrade
a. Description: While the rainfall in this area of the country is not high, much of the rain comes in short,
heavy periods, resulting in flash floods and washouts. Culverts at the installation are generally large (as
big as 72 in.) and often of double pipe arrangement, not only to accommodate sudden heavy flows, but
The track is built on a sandy subgrade, and is generally elevated above surrounding ground level. There
The large, flat areas containing tracks in the classification yard and in the Administration Area do not have
a subdrainage system.
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b. General Condition: Drainage is generally good, both from the track and through culverts. However,
there are a few problem areas. After a heavy rain, water commonly stands in the Administration Area and
in some loading sidings for quite some time. Also, due to the large amount of debris present in the storm
Heavy rains have also caused several small washouts on the Main Line, especially along a roughly 800-ft
stretch between stations 162+00 and 170+00 and at the south end of the line.
In some places, shallow clay seams block vertical drainage, but water can usually escape adequately in
lateral directions. And despite the numerous loose joint bars, the number of low joints is quite small,
Vegetation
a. Description: Thick brush and low vegetation grow close to the track in many stretches of track,
especially in loading sidings and near the ends of the primary routes.
b. General Condition: Some vegetation is very tough, and where dense growth occurs, it scrapes the
sides of trains. Because of this growth, it is difficult for a person to walk next to the track in several
Turnouts
a. Description: Turnouts are either 85 or 90 lb, matching the rail in the adjacent track. All but a few are
number 8 (in size) and have bolted frogs and either 11-ft or 16 ft, 6-in. switch points.
b. General Condition: Overall, turnout condition, line, and surface are adequate. However, many
switches are difficult to operate and badly need cleaning, lubrication, and adjustment. Also at many
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switches, the heel bolts are loose and the nuts and bolts often appear solidly rusted together, which
would prevent re-tightening. Some switch points are also badly chipped or broken, and other
About half the turnouts had most or all of their ties replaced during the last tie replacement program. A
few turnouts that did not get new ties do need some new ones.
Road Crossings
a. Description: Most crossings are all asphalt, with a few gravel/dirt type. There are two rubber
crossings through the Main Highway near the connection with the commercial carrier.
b. General Condition: About 25 percent of the asphalt crossings are in fair to poor condition. Likewise,
the track in those crossings appears to be in fair to poor condition, typically showing loose joints and wide
gage. Through a few crossings, only the slow and careful operation by the installation train crews has
Track Geometry
a. Description: Track geometry describes the relative position of the two rails and track in the vertical and
3) Gage - the spacing between the two rails. (Standard Gage is 56-1/2 in.).
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b. General Condition:
2) Surface/Crosslevel: Track surface is generally adequate, although poor in places on the east half of the
East Line, west half of the West Line, and spots on the Main Line. Track surface is also poor in some
1) Gage: Track gage is generally good, with the exception of some of the road crossings, where
wide gage is common, and spots where skewed ties have caused tight gage.
Bridges
b. General Condition: These bridges were thoroughly inspected about 2 years previously, and found to be
in good condition. During this visit, the bridges were given a brief inspection, and no obvious defects
were apparent.
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4 STRUCTURAL ANALYSIS
Explain any computer program or structural evaluations here.
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Below is a description of the major track deficiencies, along with contributing factors, where appropriate.
In addition, these deficiencies are referenced to the remedial actions (as described in chapter 4) that are
The track at the installation has, at best, a surface layer of crushed rock ballast. Most stretches have a
low density mix of fine crushed volcanic material and earth filling in the spaces between and around the
ties. This material does not provide adequate lateral or longitudinal track support. And as a result, track
alignment is generally fair or poor, and many ties have shifted position and become skewed (not
To both restore and keep proper track line and surface and maintain proper tie position, a sufficient
amount of good quality ballast material must be added to the track. In addition, anchors must be correctly
re-applied and added where needed. Remedial Actions 2,6,8,9,12, and 13 (as listed on page 16) are
About 25 percent of the asphalt crossings are in poor condition, and likewise, so is the track in them; ties
have deteriorated, track support is mushy, and joints have loosened - in some cases allowing track gage
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Turnout Defects
The portion of the track covered by this rehabilitation plan includes 48 turnouts. Many of these are
difficult to operate, out of adjustment, and have loose or defective parts. Remedial Action 9 (Restore
Heavy rain runoff occasionally washes out ballast and subgrade beneath the track in three areas along
the Main Line. Nine small washes have occurred in the last 3 years in the Main Line between Sta.
162+80 and 169+70. One small washout occurred near Sta. 253+40, and a deeper washout just past
that point. This is one area in which further study will be required to determine the most cost effective
way to either eliminate the probability of future washouts, or at least minimize possible track damage.
Remedial Action 2 includes a general plan for correcting drainage problems at these washout areas.
Skewed Ties
Some areas of the Main Line (mostly between stations 200+00 and 250+00) have skewed (crooked),
2) Cribs (space between the ties) not fully filled with ballast, further reducing resistance to tie
movement.
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3) Anchors not replaced after tie installation, or applied to only one rail (one side of the tie).
4) Track on grades. Portions of the track are on grades steep enough to encourage longitudinal rail
5) Spikes driven in the slots in angle bar type joint bars. This is no longer considered good practice.
As joints are usually staggered, rarely does a tie ever have a joint on both rails. Driving spikes
into the joint bar base slots will then have the same effect as anchoring only one side of a tie.
6) Ties with incorrect spiking pattern, present in some of the older ties. (While this incorrect pattern
Remedial Action 7 provides for repositioning skewed and misspaced ties, and Remedial Action 10 will
Numerous rail joints have loose or missing bolts, and several joints (at least 12 noted during the
inspection) have both bolts in one rail missing. Remedial Action 8 calls for tightening all joints and
Scattered locations along primary routes and loading sidings have thick brush growing close to the track,
and in some cases, in the ballast section. This vegetation must be removed before any track work can be
performed.
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In addition, sufficient herbicide needs to be applied soon after completion of track work to prevent future
brush growth.
Remedial Actions 1 and 13 cover the removal and future prevention of brush growth.
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General
This section presents a general plan for correcting the majority of track deficiencies. The plan is
organized as a list of 14 remedial actions, numbered in general work sequence order. The cost estimates
for each remedial action are broken down between Phase 1 (to be done this year) and Phase 2 (to be
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NOTES
PHASE 1 covers the primary route from connection with the commercial carrier to the end
of the East Line, Admin. Area, and Tracks 2-5 of the Classification Yard.
PHASE 2 covers the remainder of the Main Line (East Jct. to End), West Line, and North
Line.
Phase 1
Main Line from connection with the commercial carrier (Sta. 0+00) to East Junction (Sta. 119+81).
- East Line and sidings from Origin (Sta. 0+00) to End (Sta. 120+56).
Phase 2
- Main Line and sidings from East Junction (Sta. 119+81) to End (Sta. 263+97), and track Y2.
- West Line and sidings from Origin (Sta. 0+00) to End (Sta. 75+06).
- North Line and sidings from Origin (Sta. 0+00) to End (Sta. 47+96).
The work plan and estimates are for restoration of the majority of the railroad network. However, not all
remedial actions are intended to be carried out on all trackage. Within the description of each remedial
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Generally not included in the work plan are Classification Yard tracks 6-14 (the far west tracks), tracks X1
through X5, Administration Area track A9 (to the old coal/gravel chute), and track P5 (at the end of the
West Line). These tracks, while required for mobilization, are not in regular use.
Remedial Actions
1) Remove Vegetation
This should be the first step, to ensure that the track is fully accessible for other track work and that large
amounts of vegetation will not be buried in the track during ballast unloading.
Vegetation removal can be accomplished with the plow and brooms of a ballast regulator, supplemented
2) Restore Drainage
It is essential that proper drainage be provided and maintained to prevent roadbed deterioration and track
washouts. While drainage of the track network is mostly satisfactory, some general maintenance is
This section provides a rough allowance for the following drainage work:
1) Excavator, dump trucks, backhoe, and laborers reshaping ditches and cleaning culverts.
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2) Grading in the Administration Area to keep water from standing within the roadbed.
3) Installation of culverts and related earthwork in washout areas on the Main Line.
Due to the nature of the drainage in the Administration Area and in the washout areas, it may not be
practical to implement a solution that will entirely correct the problems. A plan that will greatly improve
Especially after heavy rains (such as were experienced last summer), water stands in the track in the
Administration Area. Apparently, a drainage system was never installed here, and providing one now
It is recommended that consideration be given to at least providing some grading so that water will tend
to flow away from the track into adjacent lowered areas. While this solution will not eliminate the standing
water in this area, it could at least prevent it from standing in the track, where it would do the most
damage.
In selected areas along the Main Line (especially between Sta. 162+80 and 169+70) ballast and
subgrade have been washed out from beneath the track on several occasions. These areas are located
in the natural drainage path of heavy rain runoff. While preventing all runoff from reaching the track may
not be affordable, it is recommended that remedial work be considered that will at least prevent the water
that does reach the track from causing any roadbed damage. Such work might include:
1) Install a culvert (perhaps double pipe) beneath the track, at the center of the washout area.
Grade adjacent area to channel water through the culvert. Place large rock near the culvert
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2) Construct an interceptor berm, or other obstacle, in the drainage path to break the force of a
heavy runoff.
3) Increase the ballast shoulder in the washout areas to 12 in. This may provide additional
Any drainage work that may directly disturb the track should be accomplished before track work begins.
Phase $ Estimate
1 15,000
2 35,000
Total $ 50,000
Since no record of internal rail defect inspection exists, and all rail was manufactured before the use of
controlled cooling (1933), an inspection for the presence of internal rail defects should be made over the
Note: Rail defect testing is priced per day plus travel costs, rather than by mileage. Phase 1 includes
inspection of all track in the rehabilitation plan. In addition to cost effectiveness, inspection of all
rail as soon as practical will permit an accurate determination of the quantity of rail that requires
replacement.
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This estimate is an allowance for replacing the defective rails that may be found during an internal defect
inspection.
In road crossings that require replacement, the track often needs to be completely rebuilt. In addition,
conventional rail joints are often replaced with welded joints to eliminate the need for future joint
maintenance (which usually requires tearing out at least part of the crossing surface). Welding joints in a
crossing is especially recommended in areas with heavy truck traffic and in crossings in main running
tracks. The rebuilding of crossings can start any time before the ballast and surfacing operations.
These estimates cover crossing replacements, as listed in table D-3. Three types are specified: complete
track rebuild with timber/asphalt surface, timber/asphalt surface replacement, and timber/gravel surface
replacement.
Table C-3. Road Crossing Repair/Rebuilding
Centerline Crossing Rebuild
Phase Line Location Length (ft) Type
1 Main 24+53 24 CA
77+55 42 CA
113+65 87 CA
East 10+94 33 A
46+46 31 A
65+81 30 CA
2 Main 173+20 25 A
193+31 22 A
204+20 15 G
258+09 30 A
West 4+45 18 G
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6) Tie Replacement
This estimate provides for ties primarily in the areas that were not covered in the previous tie replacement
program. Generally, the limits are the same as specified for ballast and surfacing. The number of ties
estimated is intended to allow the installation track to maintain sufficient tie condition for 5 more years
before another tie program is required. (Although during the next 5 years, some spot tie replacement will
probably be needed).
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Included in the estimate for each phase is an allowance for 400 ties in the loading tracks (and the
containerization terminal on the East Line to be done in Phase 1) and for 100 ties that drop during
Exact tie counts should be made when preparing the final plans.
2) The tie spacing at the installation averages 20 in., which equals 3,168 ties/mi.
7) Respace Ties
During this remedial action, the many skewed and misspaced ties will be properly repositioned. This work
also includes raising ties that dropped during the track raise and replacing occasional defective ties that
cannot be re-spiked.
This estimate covers labor and machine costs for tie respacing.
2) For Phase 2, tie respacing not required on Main Line from Sta. 154+00 to Sta. 200+00. This work is
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Due to numerous loose rail joints, a bolt tightening machine should tighten all track bolts. During this
Along with bolt tightening, all high spikes should be driven down and all defective spikes replaced. This
will minimize the number of ties that drop down when the track is raised during surfacing.
However, it is not recommended to either pull any spikes driven in the slots of angle bar type joint bars, or
pull or add any spikes in ties with an incorrect spiking pattern. The combination of tie
straightening/respacing, additional ballast, and application of rail anchors included in this rehabilitation
plan should be sufficient to prevent any future tie movement due to incorrect spiking. Further, there
would be significant potential for long term tie damage due to pulling spikes (even if old holes are
plugged).
Both operations (for bolts and spikes) should be performed prior to any ballast unloading or surfacing.
9) Restore Turnouts
This work includes: surfacing turnouts; replacing defective parts; grinding switch points and frogs as
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Table D-4 provides a detailed listing of turnouts included in Phases 1 and 2, along with a rough
approximation of switch tie requirements and switch point replacements. (Exact requirements should be
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Switch Tie
Phase Line I.D. Number Location Direction Requirement (1) Point Replacement
NORTH NO1 8+78 RIGHT 12 –
NO4 23+03 LEFT 22 L
NO5 25+80 RIGHT 11 L
NO6 (2) 32+47 LEFT 9 –
NO7 (3) 32+87 RIGHT 14 –
126 6
Notes:
L = Left Point, R = Right Point
One switch rod missing
Cracked frog
After new ties have been installed and skewed and misspaced ties properly repositioned, rail anchors
should be applied.
This estimate calls for every fifth tie to be box anchored (have four anchors applied), with anchoring of
primary routes only (no sidings). See Notes 2 and 3 below for intended anchoring limits.
2) For Phase 1, anchors are to be applied along the Main Line from Railroad connection (Sta. 0+00) to
East Junction (Sta. 119+81); East Line from Origin (Sta. 0+00) to End (Sta. 120+56); and along Y1.
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3) For Phase 2, anchors are to be applied along the Main Line from East Junction (Sta. 119+81) through
Sta. 194+00; West Line from Origin (Sta. 0+00) through Sta. 70+89; and North Line from Origin (Sta.
4) Anchoring near the two open deck bridges (M 19+13 and W 40+00) should be done as follows: no
anchors on track on the bridge; box anchor every third tie for two rail lengths (about 66 ft) off either end of
the bridge.
Once the track is clear of excess vegetation, all bolts in place and tight, high spikes driven, and track in
crossings rebuilt, the track is ready for new ballast to be applied. Ballast and surfacing locations are
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Location Footage
119+81 (East Junction) to 194+01 7,420
257+79 to 263+97 (End) 618
8,038
West
0+00 to 75+06 (End) 7,506
North
0+00 to 48+73 4,873
Tracks SA-SE 2,237
7,110
Total Phase 2 Footage (4.29mi.) 22,654
This estimate is for sufficient ballast to give the track a 3-in. raise, fill in shoulders and cribs, and pull up
any track sags. It includes the costs of purchasing the ballast material, delivery to the work site, and
The mileages indicated correspond to the surfacing footages, as shown in table D-5.
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During the final design process the sidings serving the loading docks and magazine standards should be
checked to ensure that there is proper horizontal and vertical clearance between the track and the loading
platform. Any corrections that are required should be done during track surfacing.
2) For Phase 1, estimate assumes no track raise through the track scale, and also assumes that track
will be raised to level of existing crossings in the sidings along the East Line (Buildings A - F).
3) For Phase 2, a 12-in. shoulder should be provided in the track washout areas along the Main Line.
Once the track work is complete, all track should be sprayed to prevent the growth of weeds in the ballast
section.
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While vegetation spraying should be done at least once per year, this estimate is for one initial heavy
application over a 16-ft wide path (8 ft from the center line of track on both sides).
Although listed last, quality control inspection is an essential element for a successful track rehabilitation.
It is an effective means of assuring that all work reflects good workmanship and is performed according to
Phase $ Estimate
1 1,200
2 12,000
Total $ 24,000
Note: Inspection cost estimate based on
$35/Hour basic labor and overhead charge,
or $280/Day, and $100/Day subsistence
expenses. Total = $380/Day.
2) Allowance for travel to and from site of one round trip/week = $500.
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Proper track restoration will involve remedial work that requires special attention. It is essential that this
As indicated in the report, there are still some areas that need further examination before detailed
contract specifications can be made, particularly in the improvement of drainage in areas where track
washouts have occurred. These additional determinations should be included as part of the final design
process.
design/inspection package be considered. Having the track work designed and inspected by the same
organization has great potential for improved quality control and accountability throughout the project.
To further clarify the work plan and contract specifications, the work requirements (by type and location)
should be marked in the field, whenever practical. This might include: marking with paint those switch
ties that need replacement, setting flags or stakes to indicate the limits where extra shoulder ballast is
required, painting a code at each road crossing to indicate which type of reconstruction is to be done, and
noting any other indicators that may help guide the field work.
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