HRE-REVIEWER PDF

Summary

This document details bituminous materials, commonly known as asphalt. It discusses different types of bituminous materials, bituminous binders, and qualities of asphalt road. It also mentions problems associated with bituminous binders and construction procedures to attain satisfactory asphalt pavements.

Full Transcript

😡 BITUMINOUS MATERIALS 😡 Film thickness impacts aging processes.
Dry mixtures are prone to cracking.
High asphalt content and low voids may
Bituminous materials, commonly known as lead to pavement instability.
asphalt, are viscous liquids used as binders for Improper construction, such as overheated
aggregates, can prematurely age asphalt.
aggregates in road construction. They can be
Extended storage and climatic conditions
either slightly thicker than water at normal affect binder behavior.
temperature or hard and brittle. When mixed with Variability in asphalt brands impacts
aggregates, bituminous materials are typically in performance consistency.
High viscosity temperature ratios can
liquid form. This state can be achieved by heating, cause brittleness at low temperatures.
dissolving in solvents, or emulsifying in water.
BITUMINOUS PAVEMENTS
Bituminous materials’ action depends on the type
of binder and the aggregate it is combined with, It is a combination of mineral aggregate and
resisting abrasive forces from heavy traffic. binders.

National Paving
TYPES OF BITUMINOUS MATERIALS: Asphalt Macadam
Asphalt Concrete
Heated Asphalt Mastic
Dissolved in Solvents Plant Mix
Emulsified Asphalt Asphalt Sheet
Road Mix
BITUMINOUS BINDERS Armor Coat
Oil Mat
Asphalt cement, a semi-solid hydrocarbon, is the QUALITIES OF ASPHALT ROAD
most used bituminous binder in high-quality
pavements. Cutback or liquid asphalt, which 1. The surface must be free from cracks or
includes asphalt cement with a liquid distillate, is traveling due to shrinkage and fatigue
less favored due to fuel usability and air pollution failure.
concerns. Emulsified asphalt, a mixture where 2. It must be withstanding weather condition,
asphalt disperses in water, serves as an alternative including the effect of surface water, heat,
to cutback asphalt, beneficial for environmental cold, and oxidation
and energy considerations. Modified bituminous 3. It must be resistant to internal moisture
binders like epoxy resin and bitumen-rubber such as water vapor.
mixtures enhance pavement stability and 4. It must possess a tight or porous
durability under specific conditions. impermeable surface as the case may be
suitable to underlying base on sub-base.
TYPES OF BITUMINOUS BINDERS: 5. It must be smooth riding and skid free
surface.
Cutback Asphalt
Emulsified Asphalt THE SUCCESS OF AN ASPHALT PAVEMENT
Modified Bituminous Binders LIES OR DEPENDS ON THE
CONSTRUCTION QUALITY OF THE
Problems Associated with Bituminous Binders:
SUBGRADE, AND THE BASE COURSE. ON
Several issues can affect bituminous binders'
THE CONTRARY, PAVEMENT FAILURE
performance:
WOULD BE CONSIDERED AS A FORE-GONE BITUMINOUS PAVEMENT FAILURE
CONCLUSION.
Bituminous pavement failures are caused by
Construction Procedures to Attain Satisfactory excessive load. Heavy load creates deflection on
Asphalt Pavement the road surface, with insufficient underlying
strength.
➔ Viscous asphalt binder is heated to a fluid
condition and mixed with heated Repetitious application of excessive load will
aggregates. The mixture is then laid and roughen and crack the road pavement that
compacted while still hot. ultimately results in complete failure of the
➔ Mixing liquid or emulsion asphalt with roadway.
aggregates at normal temperature is either
by plant or road mixing. The mixture is Deflection on the road surface may be the effect
laid compacted at normal temperature of elastic deformation from the solidation of the
before the solvent evaporates or the base and subsoil or from the combination of
emulsion breaks. elastic and plastic deformation.
➔ Spread and compact the clean crushed
Repeated heavy wheel load on highly resilient soil
stones, sprayed with heated or emulsified
causes deflection leading to fatigue failure of the
asphalt binder over it. Cover with sprayed
asphalt surface. Alligator or map cracking of the
pavement with fine aggregate. This is
surface will be substantially evident.
process referred to as the “penetration
method.” Elastic deformation in the subgrade penetrates to a
depth of 6.00 meters although mostly to a depth
ASPHALT CONCRETE PAVEMENTS
from the surface.
The term Asphalt Concrete refers to a dense
graded road surface made of hot mineral
aggregates, mixed with hot asphalt and laid at Bitumen is a thick, sticky, black material made
high temperatures of about 275 F to 300 F. from oil, used to hold rocks and sand together in
Asphalt concrete is the highest type of dense roads, making them strong and waterproof.
bituminous pavement suitable for the most heavily
traveled roads. Asphalt is a mix of bitumen and small rocks or
sand, used to make smooth, strong roads that can
A prime coat is applied over the untreated and handle heavy traffic and rain.
treated base before asphalt concrete is laid.

Purpose: To bind any loose particles of the base
and likewise act as a bond between the base and
the pavement to deter rising moisture from
penetrating the pavement.

The thickness of compacted asphalt concrete
ranges from 2 inches for lightly traveled roads to 6
inches or more for roads where traffic is
considerably heavy.
ROAD MATERIALS develop on the asphalt and water penetrate the
surface until it reaches the aggregates.
Aggregates
Test for shape and texture - A relatively rounded
Aggregates intended for either Bituminous smooth aggregate particle like natural gravel is
(asphalt) or Portland cement concrete pavement, recommended for Portland cement concrete
should be of good quality in accordance with the pavement because the mixture is workable.
requirements of AASHTO standard or Item-703 of Meaning, easily managed and consolidated inside
the Department of Public Works and Highways the forms.
specifications which generally provides that:
Test for resistance to polishing - One good
"The aggregates shall consist of hard durable criterion for pavement design is the high
particles or fragments of crushed stone, crushed coefficient of friction between the tire and the
slag, or crushed rock or natural gravel." road surface. A good asphalt or concrete road
design is when "the rubber tire is in direct contact
Aggregates to be classified as good quality, must with the aggregate and not with the binder"
undergo various test enumerated as follows:
Degradation test - Some aggregates degrade in
Test for strength - Los Angeles Rattler Test the presence of water. This is measured through
(AASHTO T-96) mechanical agitation in water under designation
test T-210 of AASHTO
Test for soundness - Soundness refers to the
resistance of materials to deterioration from the PARTICLE SIZE
effect of action like freezing and thawing. The
common test for soundness is the application with 1. For dense graded pavement. - The
sodium or magnesium sulfate. (AASHTO T-104) particle size of aggregate ranges from
coarse to dust.
Test for affinity and swell - Strong and durable 2. For open graded pavement. - One or
pavement must have binder that adhere or stick more layers of coarse rock of uniform size
firmly to the aggregate particles. If the binder is used.
separates or strip's-off from the aggregate, the 3. For sheet asphalt. - The mineral aggregate
pavement will disintegrate under traffic. Another is a carefully graded sand and mineral
reaction of the pavement is to pit when aggregates dust.
are pulled-off caused by running wheels. In the
event that pavement mixture swells, the interlock AGGREGATE FOR BITUMINOUS
and friction between the particles are destroyed PAVEMENT
resulting in collapse of the pavement stability.
(AASHTO T-165) Bituminous, or asphalt, pavements rely heavily on
aggregates as a primary component, making up
Hydrophilic - is the term used when the aggregate 88% to 96% of the pavement by weight or over
has greater affinity for water than asphalt. 75% by volume.
Meaning, they like water than asphalt in contrast
to hydrophobic which means fear, or against 1. Coarse aggregate materials retained on
water. 2.00 mm No.lO sieve shall have a mass
percent of wear by the Los Angeles
Hydrophobic - the chemical bond between the Abrasion Test (AASHTO T-96) of not
aggregates and water is much stronger than those more than 45
between aggregates and asphalt. On the contrary, 2. When crushed aggregate is specified, not
if the aggregate is hydrophobic, pinholes will less than -50 mass percent of the particles
 retained on the 4.75 mm No. a) sieve shall a. Slow curing (SC) road soil
have at least one fractured face. b. Medium curing (MC) cutback
3. The fraction passing the 0.75 mm asphalt
(No.200) sieve should not be greater than c. Rapid Curing (RC) cutback asphalt
213 of the fraction passing the 0.425 mm
(No.40) sieve. Emulsified Asphalt
4. The fraction passing 0.425 mm (No.a0)
Emulsified asphalt is a kind of mixture wherein
sieve shall have a liquid limit not greater
the minute globules of asphalt disperse in water.
than 35 and a plasticity index. range of 4
Asphalt content ranges from 55o/o-70% by
to 9 when tested by AASF{TO 'I-89 and
weight. Emulsion could be applied or mixed at
T-90 respectively
normal temperature, because when the water
BITUMINOUS MATERIALS content evaporates, the asphalt remains. It has the
following characteristics.
Bituminous material or Asphalt in short, is a
viscous liquid used as binder for aggregates in 1. Emulsified asphalt is excellent with wet
road construction. At normal temperature, asphalt aggregate because the water medium
is either slightly thicker than water or hard but carries the asphalt into a superior contact
brittle material that breaks under a hammer blow with the particle surfaces.
when cold. 2. Emulsified asphalt is an alternate cutback
asphalt for energy and environmental
BITUMINOUS BINDERS objectives. It is an effective material in
coating electropositive aggregate such as
Asphalt cement is used as binder for almost all limestone but tends to strip from
high types of bituminous pavement. Asphalt aggregates with high content of silica for
cement is a semi solid hydrocarbon retained after having strong electronegative surface
fuel and lubricating oils are removed from charges.
petroleum. The softest grade used for pavement is 3. The Cationic Emulsion is very effective on
the 200-300 penetration. The 60-70 penetrations is high siliceous aggregates but may strip
the hardest type. from high alkaline that carry strong
positive surface changes.
Penetration refers to the consistencies of asphalt
4. Rejuvenating Agent is an emulsified
cement as described under AASHTO-T49. It is the
petroleum resin sprayed over the surface
distance that a standard needle penetrates a sample
of an old asphalt road that changes to
under known conditions of loading time and
asphaltenes causing the binder to harden
temperature. Recently, the procedure used in
and crack. The rejuvenating agent sprayed
grading asphalt cement is the Viscosity Test rather
over the pavement and softening the
than the Penetration Test.
binder. Too much application however,
Cutback or Liquid Asphalt produces a slick pavement surface.

1. Liquid asphalt is a petroleum product Oxidized Asphalt and Road Tar
consisting of asphalt cement with a liquid
Oxidized asphalt is suitable only for roofing and
distillate (diesel, kerosene or gasoline).
similar applications. Highway use of oxidized
The less viscous asphalt contains diluents
asphalt is limited to waterproofing of structures
as little as l5%.
and filling joints of concrete pavement. Road tar is
2. The use of cutback is being frowned upon
a by-product of the distillation process of coal.
for two reasons: a. It is a usable fuel b. It is
Tars are produced from gashouse coal tar, cook
an air pollutant.
oven tars and water gas tar.
3. Cutback or liquid asphalt is classified into:
Bitumen – Rubber Mixture 4. Distillation test (AASHTO T -48)

The bitumen rubber mixture for road pavement 5. Thin film oven test (AASHTO T –
was experimented in Holland in the year 7929. It 179)
was adopted in the United States in 1947 and later,
in European countries' The assessments of the 6. Flashpoint (AASHTO T – 48%79)
road states that:
7. Test for homogeneity of petroleum
1. Very little improvement gained as far as asphalt (AASHTO 102)
coefficient of friction on newly laid
8. Special test for Emulsion asphalt
pavement but expect higher advantages
(AASHTO T-59)
after six months. The analysis of the
Bureau of Public Roads states that: PAVEMENT DESIGNS
"An appraisal of the real economic value of the Design of Flexible Pavements
addition of rubber to asphalt must wait on further
observation of the behavior of experimental Structural Components of a Flexible Pavement
pavements under the influence of age, weather
and traffic".

2. According to the report, powdered rubber
foams added to bitumen have improved
the stability of some but not all.

Epoxy as Bituminous Binders

1. Test of consistency is subdivided
into:
Subgrade (Prepared Road Bed)
a. Kinematics Viscosity test
The subgrade is usually the natural
(AASHTO T-202)
material located along the
b. Saybolt-Fural test horizontal alignment of the
(AASHTO T-72) pavement and serves as the
foundation of the pavement
c. Engler specific gravity test structure. It also may consist of a
(AASHTO T 54) layer of selected borrow materials

d. The float test (AASHTO T Subbase Course
– 50)
Located immediately above the
e. Penetration test (AASHTO subgrade, the sub base component
T – 49) consists of material of a superior
quality to that which is generally
f. Softening point test used for subgrade construction.
(AASHTO T – 53) The requirements for subbase
materials usually are given in terms
2. Test for durability (AASHTO T –
of the gradation, plastic
52)
characteristics, and strength
3. Test for solubility (AASHTO T –
Base Course
44)
 The base course lies immediately Portland cement is manufactured by crushing and
above the subbase. It is placed pulverizing a carefully prepared mix of limestone,
immediately above the subgrade if marl, and clay or shale and by burning the mixture
a subbase course is not used. This at a high temperature (about 2800°F) to form a
course usually consists of granular clinker. The clinker is then allowed to cool, a
materials such as crushed stone, small quantity of gypsum is added, and the
crushed or uncrushed slag, crushed mixture is then ground until more than 90 per cent
or uncrushed gravel, and sand. of the material passes the No. 200 sieve. The main
chemical constituents of the material are
Surface Course tricalcium silicate (C3S), dicalcium silicate (C2S),
and tetracalcium alumino ferrite (C4AF).
The surface course is the upper
course of the road pavement and is Coarse Aggregates
constructed immediately above the
base course. The surface course in The coarse aggregates used in Portland cement
flexible pavements usually consists concrete are inert materials that do not react with
of a mixture of mineral aggregates cement and usually are composed of crushed
and asphalt. It should be capable of gravel, stone, or blast furnace slag. The coarse
withstanding high tire pressures, aggregates may be any one of the three materials
resisting abrasive forces due to or else a combination of any two, or all three. One
traffic, providing a skid resistant of the major requirements for coarse aggregates
driving surface, and preventing the used in Portland cement concrete is the gradation
penetration of surface water into of the material. The material is well graded, with
the underlying layers. the maximum size specified.

Design of Rigid Pavements Fine Aggregates

Materials Used in Rigid Pavements Sand is mainly used as the fine aggregate in
Portland cement concrete. Specifications for this
Portland Cement material usually include grading requirements,
Coarse Aggregates soundness, and cleanliness. Standard
Fines Aggregates specifications for the fine aggregates for Portland
Water cement concrete (AASHTO Designation M6) give
Reinforcing Steel grading requirements normally adopted by state
Temperature Steel highway agencies
Dowel Bars
Tie Bars Water

Portland Cement The main water requirement stipulated is that the
water used also should be suitable for drinking.
The Portland cement concrete commonly used for This requires that the quantity of organic matter,
rigid pavements consists of Port land cement, oil, acids, and alkalis should not be greater than
coarse aggregate, fine aggregate, and water. Steel the allowable amount in drinking water.
reinforcing rods may or may not be used,
depending on the type of pavement being Reinforcing Steel
constructed.
Steel reinforcing may be used in concrete
Portland Cement pavements to reduce the amount of cracking that
occurs, as a load transfer mechanism at joints, or construction (for example, between the end of one
as a means of tying two slabs together. Steel day’s work and the beginning of the next). These
reinforcement used to control cracking is usually joints can be divided into four basic categories:
referred to as temperature steel, whereas steel rods
used as load transfer mechanisms are known as Expansion Joints
dowel bars, and those used to connect two slabs Contraction Joints
together are known as tie bars. Hinge Joints
Construction Joints
Temperature Steel
Expansion Joints
Temperature steel is provided in the form of a bar
mat or wire mesh consisting of longitudinal and are usually placed transversely, at regular
transverse steel wires welded at regular intervals. intervals, to provide adequate space for the slab to
The mesh usually is placed about 3 in. below the expand. These joints are placed across the full
slab surface. The cross-sectional area of the steel width of the slab and are 3⁄4 to 1 in. wide in the
provided per foot width of the slab depends on the longitudinal direction.
size and spacing of the steel wires forming the
Contraction Joints
mesh. The amount of steel required depends on
the length of the pavement between expansion are placed transversely at regular intervals across
joints, the maximum stress desired in the concrete the width of the pavement to release some of the
pavement, the thickness of the pavement, and the tensile stresses that are so induced
moduli of elasticity of the concrete and steel.
Hinge Joints
Dowel Bars
Hinge joints are used mainly to reduce cracking
Dowel bars are used mainly as load-transfer along the centerline of highway pavements.
mechanisms across joints. They provide flexural,
shearing, and bearing resistance. The dowel bars Construction Joints
must be of a much larger diameter than the wires
used in temperature steel. are placed transversely across the pavement width
to provide suitable transition between concrete
Tie Bars laid at different times.

Tie bars are used to tie two sections of the Type of Rigid Highway Pavements
pavement together, and therefore they should be
either deformed bars or should contain hooks to Jointed Plain Concrete Pavement (JPCP)
facilitate the bonding of the two sections of the Simply Reinforced Concrete Pavement
concrete pavement with the bar. These bars are Continuously Reinforced Concrete
usually much smaller in diameter than the dowel Pavement (CRCP)
bars and are spaced at larger centers. Typical
Jointed Plain Concrete Pavement (JPCP)
diameter and spacing for these bars are 3⁄4 in. and
3 ft, respectively Plain concrete pavements, which are made from a
simple mixture of cement, water, and aggregate
JOINTS IN CONCRETE PAVEMENTS
(without any reinforcing steel), are often used in
Different types of joints are placed in concrete specific situations where the traffic load and
pavements to limit the stresses induced by environmental conditions are less demanding.
temperature changes and to facilitate proper These pavements are typically chosen for
bonding of two adjacent sections of pavement low-volume highways or areas with light traffic,
when there is a time lapse between their
as well as where the subbase (the layer beneath condition, delaying repairs can lead to more
the concrete) is made of cement-stabilized soil. extensive damage and higher rehabilitation costs.
Pavement deterioration is typically caused by
Simply Reinforces Concrete Pavement factors such as climate, drainage issues, soil
conditions, and heavy truck traffic, rather than
have dowels for the transfer of traffic loads across
poor design or construction. Limited budgets force
joints, with these joints spaced at larger distances,
agencies to prioritize between preventive
ranging from 30 to 100 ft. Temperature steel is
maintenance, which is cost-effective but often
used throughout the slab, with the amount
neglected, and corrective actions for critical
dependent on the length of the slab. Tie bars also
defects.
are used commonly at longitudinal joints.
Approaches to Pavement Management
Continuously Reinforced Concrete Pavement
(CRCP) The term pavement management describes the
various strategies that can be used to decide on a
have no transverse joints, except construction
pavement restoration and rehabilitation policy.
joints or expansion joints when they are necessary
These strategies range from addressing issues as
at specific positions, such as at bridges. These
they arise (a "squeaky wheel" approach) to
pavements have a relatively high percentage of
maintaining all roads on a regular, unrestricted
steel, with the minimum usually at 0.6 percent of
budget. Practical pavement management plans set
the cross section of the slab. They also contain tie
minimum standards for road conditions, determine
bars across the longitudinal joints.
necessary treatments, and establish timelines,
Pumping of Rigid Pavements balancing factors like pavement condition, initial
costs, maintenance, user expenses, safety, and
Pumping is an important phenomenon associated environmental impacts.
with rigid pavements. Pumping is the discharge of
water and subgrade (or subbase) material through Life-cycle cost analysis is fundamental in
joints, cracks, and along the pavement edges. It pavement management, covering the total project
primarily is caused by the repeated deflection of cost from initial construction to major
the pavement slab in the presence of accumulated rehabilitation. Pavement management aims to
water beneath it. The mechanics of pumping can maintain, improve, and operate pavement assets
best be explained by considering the sequence of systematically and cost-effectively by integrating
events that lead to it. engineering principles with economic practices.

Visual manifestations of pumping include: Key Steps in Pavement Management

Discharge of water from cracks and joints Step 1: Assess Present Pavement Condition
Spalling near the centerline of the
Step 2: Predict Future Condition
pavement and a transverse crack or joint
Mud boils at the edge of the pavement Step 3: Conduct Alternatives Analysis
Pavement surface discoloration (caused by
the subgrade soil) Step 4: Select Appropriate Rehabilitation Strategy
Breaking of pavement at the corners
Elements of the Pavement Management System
Problems of Highway Rehabilitation
Inventory and Condition Database
Highway and transportation agencies frequently Mathematical Models for Forecasting
struggle with insufficient funding, which limits Procedures for Alternative Analysis
their ability to repair all deteriorating roadways. Reporting and Visualization Tools
Although some roads remain usable despite poor
Methods for Determining Roadway Condition diesel engine’s high efficiency makes it suitable as
a locomotive prime mover, providing reliable
1. pavement roughness (rideability) power across variable operational needs.
2. pavement distress (surface condition)
3. pavement deflection (structural failure) Electric Transmission Equipment
4. skid resistance (safety).
In diesel-electric locomotives, a generator
Pavement Rehabilitation or alternator directly coupled to the engine
provides power, with its output controlled
A variety of methods can be used to rehabilitate by engine speed and field adjustments.
pavements or to correct deficiencies in a given
pavement section including using overlays, Electrical Controls
sealing cracks, using seal coats, and repairing
potholes. In conventional DC propulsion systems,
contactors control the connection between
Rehabilitation Techniques and Strategies traction motors and the main generator,
Rehabilitation techniques are classified as: with interlocks for safety and operation,
and a cam switch is used for reversing and
1. corrective, which involves the permanent dynamic braking.
or temporary repair of deficiencies on an
as-needed basis CABS
2. preventive, which involves surface
applications of either structural or The AAR sets uniform safety standards for
nonstructural improvements intended to locomotive cab features, including noise
keep the quality of the pavement above a and control systems, to ensure safe
predetermined level. operations.

Pavement rehabilitation strategies can be Batteries
categorized in a variety of ways.
Diesel locomotives commonly use
One approach is in terms of the problem lead-acid batteries, typically with 280 or
being solved, such as skid resistance, 420 ampere-hour capacity, to start the
surface drainage, unevenness, roughness, engine. Each unit has 32 cells, supplying
or cracking. 64 volts to the system, and the batteries are
Another approach is in terms of the type of recharged from a 74-volt power source.
treatment used, such as surface treatment,
AIR-BRAKES
overlay, or recycle.
A third approach is in terms of the type of The engineer controls locomotive braking
surface that will result from the process, with two brake valve handles: the
such as asphalt overlay, rock seal coat, or "independent" for the locomotive alone
liquid seal coat. and the "automatic" for the entire train.

Dynamic Braking
DIESEL – ELECTRIC LOCOMOTIVES Dynamic brakes convert locomotive
kinetic energy into heat, dissipated through
Diesel-electric and electric locomotives are
resistance grids cooled by motor-driven
classified by wheel arrangements using letters for
fans. This system, controlled by adjusting
driving axles in a truck (e.g., "B" for two axles
motor excitation and grid resistance,
and "C" for three), and numerals for idler axles,
with additional symbols for articulation. The
 supplements air brakes and reduces wear, Maximum Speed - Traction motors are also rated
especially on long grades in terms of their maximum safe speed in r/min,
which in turn limits locomotive speed.
PERFORMANCE
Locomotive Compatibility - The AAR has
Engine-Indicated Horsepower - the theoretical developed two standards in an effort to improve
power of a reciprocating engine if it is completely compatibility between locomotives of different
frictionless in converting the expanding gas model, manufacture, and ownership: a standard
energy 27-point control system and a standard control
stand.
Rail Horsepower - a measurement of how much
power an engine can produce after accounting for Energy Conservation - Efforts to improve
frictional losses efficiency and fuel economy have resulted in
major changes in the prime movers, including
Thermal Efficiency - The thermal efficiency of
more efficient turbocharging, fuel injection, and
the diesel engine at the crankshaft, or the ratio of
combustion.
bhp output to the rate at which energy of the fuel
is delivered to the engine, is about 33 percent. Emissions - The U.S. Environmental Protection
Thermal efficiency at the rail is about 26 percent. Agency has promulgated regulations aimed at
reducing diesel locomotive emissions, especially
Drawbar Horsepower - The drawbar horsepower
oxides of nitrogen (NOx). These standards also
represents power available at the rear of the
include emissions reductions for hydrocarbons
locomotive to move the cars.
(HC), carbon monoxide (CO), particulate matter
Speed-Tractive Effort - The tractive effort of a (PM), and smoke.
diesel-electric locomotive varies with speed,
ELECTRIC LOCOMOTIVES
following a nearly hyperbolic curve. At full
throttle, the locomotive provides full horsepower Electric locomotives in North America are mostly
across the speed range, but power decreases as the used for coal or mineral freight and in
speed approaches its limit, a process called high-density passenger service in the northeastern
"power matching." This enables multiple U.S. They draw power from overhead catenary or
locomotives with different power ratings to third-rail systems, with newer systems using
operate together at the same speed. 25,000 or 50,000 V at 60 Hz.
Adhesion - Adhesion, typically 25% of the Report on Passenger Rail Equipment Types
locomotive's weight on drivers, determines
tractive effort, but it can vary from 5% to 35% Over the past two decades, passenger rail services
depending on rail conditions. Lubricants reduce in North America, especially for long-distance
adhesion, but sand from the locomotive can routes, have largely been managed by government
improve it. AC traction motors can achieve higher agencies like “Amtrak” in the U.S. and “Via Rail”
adhesion levels, up to 45% at low speeds, with a in Canada. Passenger rail equipment for “urban
nominal value of 35%. transit” is divided into three main categories:
commuter rail, heavy rail rapid transit (HRT), and
Traction Motor Characteristics - Motor torque light rail transit (LRT). These categories depend
in traction motors depends on motor current, on the characteristics of the service, such as the
which determines tractive effort, with field type of infrastructure and traffic conditions.
shunting altering this relationship at certain levels.
Main-Line Passenger Equipment
Main-line passenger trains are used for long-haul These trains are built to handle sharp curves, high
services. There are four primary types of speeds (up to 75 mph), and frequent stops, with
main-line train sets: acceleration rates between 2.5 to 3.0 mph/sec.
They also have robust braking systems, including
Diesel Locomotive-Hauled Trains dynamic braking and electro-pneumatic friction
Diesel Multiple Units (DMU) brakes, to ensure fast and safe stops
Electric Locomotive-Hauled Trains
Electric Multiple Units (EMU) Light Rail Transit (LRT) Equipment

Trains are equipped with advanced suspension Light rail transit (LRT) is a versatile and
systems to ensure a smooth ride, including: flexible rail system used in cities like San Diego,
Portland, and Calgary. LRT systems can run on a
Primary Suspension: Isolates the wheels from mix of surface streets, dedicated tracks, or even
the truck using coil springs, elliptical springs, or elevated lines. Key features of LRT equipment
elastomeric components. include:
Secondary Suspension: Isolates the truck from Light Rail Vehicles (LRVs): These cars
the car body using large coil rings or pneumatic are electrically powered, usually via
springs, with hydraulic dampers to improve ride overhead catenary wires. They range in
quality size from 60 to 90 feet and are often
articulated to carry more passengers while
Commuter Rail Passenger Equipment
being able to navigate tight curves.
Commuter rail operates in urban or suburban Braking Systems: LRTs use a
areas, providing services to and from city centers. combination of dynamic, friction, and
There are two types of commuter rail equipment: track brakes. The dynamic braking helps
slow down the train during regular
Locomotive-Hauled operation, while track brakes are used in
Self-Propelled Units (e.g., DMUs) emergencies.
Passenger Capacity: LRT cars typically
Commuter rail trains often use push-pull have 50 to 80 seats, but the total capacity
operations, where the locomotive can either push is much higher when factoring in standing
or pull the train. Some cars are equipped with cabs room.
at both ends, allowing the engineer to operate the
train from either direction. Automatic couplers are VEHICLE-TRACK INTERACTION AND
used to link cars together, with most commuter TRAIN RESISTANCE
rail cars using AAR-type couplers.
Types of Train Resistance
Heavy Rail Rapid Transit Equipment
Inherent Resistance includes rolling
Heavy rail rapid transit systems are found in resistance at low speeds and aerodynamic
major cities like New York, Chicago, and Boston, resistance at high speeds. At higher
and they operate on dedicated tracks (subways or speeds, aerodynamic resistance dominates,
elevated lines). These systems use: and it decreases with increased car weight.
Incidental Resistance arises from factors
- Electric Propulsion (usually from a third rail or like track grade, curvature, wind, and
pantographs). vehicle dynamics, all affecting the train’s
performance
- Bidirectional Operation with up to 12 connected
cars. Key Resistance Components
 Rolling Resistance: Significant at low Association of American Railroads (AAR) has
speeds, decreases with car weight. established design and maintenance criteria to
Aerodynamic Resistance: Dominates at assure the interchangeability of freight cars on all
higher speeds, independent of car weight, North American railroads
and increases with speed.
Wind Resistance: Affected by vehicle AAR - The AAR Manual of Standards and
design, open tops, protrusions, and vehicle Recommended Practices specifies dimensional
spacing. limits, weights, and other design criteria for cars
Curve Resistance: Increases with the that may be freely interchanged between North
degree of curvature. Rail lubrication and American railroads.
special truck designs can reduce friction
The AAR identifies most cars by nominal capacity
and resistance.
and type, and in some cases there are restrictions
Grade Resistance: Related to the incline or
as to type of load (i.e., food, automobile parts, coil
decline, calculated as 20 lb/ton per 1%
steel, etc.). Most modern cars have nominal
grade.
capacities of either 70 or 100 tons.
Acceleration Resistance: Force required to
accelerate the train, including both linear Boxcars
and rotational components.
1. Standard boxcars may have
Vehicle Suspension System either sliding or plug doors. Plug
doors provide a tight seal from
Designed to isolate track input forces from
weather and a smooth interior.
the car body and prevent instability such as
Unequipped box cars are usually of
harmonic roll, pitch, bounce, and yaw.
70-ton capacity. These cars have
Advances in suspension design reduce
tongue-and-groove or plywood
undesirable behaviors and enhance
lining on the interior sides and ends
performance.
with nailable floors (either wood or
Superelevation steel with special grooves for
locking nails).
Superelevation compensates for centrifugal force
during curve negotiation by raising the outside 2. Specially equipped boxcars
rail. The maximum allowable superelevation for usually have the same dimensions
freight trains is usually 6 inches, adjusted for train as standard cars but include special
speed and curve radius. interior devices to protect lading
from impacts and over-the-road
Longitudinal Train Action vibrations. Specially equipped cars
may have hydraulic-cushion units
Slack action refers to the dynamic forces between to dampen longitudinal shock at the
individual cars in a train, which can cause couplers.
instability or breakage under certain conditions.
Analysis of longitudinal forces and tractive effort 3. Insulated boxcars have plug
is essential to minimize these effects. doors and special insulation. These
cars can carry foodstuffs such as
FREIGHT CARS unpasteurized beer, produce, and
dairy products. These cars may be
Freight Car Types
precooled by the shipper and
Freight cars are designed and constructed for maintain a heat loss rate equivalent
either general service or specific ladings. The to 1F (0.55C) per day
 4. Refrigerated boxcars are used typical 100-ton coal hopper car will vary in
where transit times are longer. volume depending on the light weight of the car
These cars are equipped with and density of the coal to be hauled. Volumes
diesel-powered refrigeration units range from 3,900 to 4,800 ft3 (110 to 136 m3 ).
and are primarily used to carry
fresh produce and meat. They are High-side Gondola Cars
often 100-ton cars.
High-side gondola cars (Figure 23.14d) are
5. ‘‘All-door’’ boxcars have doors open-top cars typically used to haul coal or wood
that open the full length of the car chips. These cars are similar to open-top hopper
for loading package lumber cars in volume but require a rotary coupler on one
products such as plywood and end for rotary dumping to discharge lading since
gypsum board. they do not have bottom outlets. Rotary-dump
coal gondolas are usually used in dedicated,
6. High-cubic-capacity boxcars unit-train service between a coal mine and an
with an inside volume of 10,000 ft3 electric power plant. The length over coupler
(283 m3) have been designed for pulling faces is approximately 53 ft 1 in. (16.2 m)
light-density lading, such as some to suit the standard coal dumper.
automobile parts and low-density
paper products. Bulkhead Flat Cars

Boxcars Bulkhead flat cars are used for hauling such
commodities as packaged finished lumber, pipe,
Boxcar door widths vary from 6 to 10 ft for or, with special inward canted floors, pulpwood.
single-door cars and 16 to 20 ft (4.9 to 6.1 m) for Both 70- and 100- ton bulkhead flats are used.
double-door cars. All-door cars have clear Typical deck heights are approximately 50 in.
doorway openings in excess of 25 ft (7.6 m). The (1,270 mm).
floor height above rail for an empty uninsulated
boxcar is approximately 44 in. (1,120 mm) and for Tank Cars
an empty insulated boxcar approximately 48 in.
Tank cars are used for liquids, compressed gases,
(1,220 mm). The floor height of a loaded car can
and other ladings, such as sulfur, that can be
be as much as 3 in. (76 mm) lower than the empty
loaded and unloaded in a molten state.
car
Nonhazardous liquids such as corn syrup, crude
Covered Hopper Cars oil, and mineral spring water are carried in
nonpressure cars. Cars used to haul hazardous
Covered hopper cars are used to haul bulk substances such as liquefied petroleum gas (LPG),
commodities that must be protected from the vinyl chloride, and anhydrous ammonia are
environment. Modern covered hopper cars are regulated by the U.S. Department of
typically 100-ton cars with roof hatches for Transportation
loading and from two to six bottom outlets for
discharge. Cars used for dense commodities, such Intermodal Cars
as fertilizer or cement, have two bottom outlets,
Boxcar door widths vary from 6 to 10 ft for
round roof hatches, and volumes of 3,000 to 4,000
single-door cars and 16 to 20 ft (4.9 to 6.1 m) for
ft3 (84.9 to 113.2 m3 ).
double-door cars. All-door cars have clear
Open-top Hopper Cars doorway openings in excess of 25 ft (7.6 m). The
floor height above rail for an empty uninsulated
Open-top hopper cars are used for hauling bulk boxcar is approximately 44 in. (1,120 mm) and for
commodities such as coal, ore, or wood chips. A an empty insulated boxcar approximately 48 in.
(1,220 mm). The floor height of a loaded car can Lading Restraint Systems: From tie-downs
be as much as 3 in. (76 mm) lower than the empty for vehicles to bulkheads for pulpwood,
car these features secure cargo effectively.
Intermodal Adaptations: Well cars enable
Design Standards and Safety double-stacked containers, significantly
increasing freight capacity.
Weight and Dimensions: For example,
modern cars handle up to 100 tons, with RAILWAY TRACK DESIGN
axle journals designed for high durability.
Structural Integrity: Freight cars must Track Components
withstand extreme loads, such as coupling
impacts reaching 1.25 million pounds. Superstructure:
Safety Features: These include compliance
Rails: Guide wheels, transfer loads, resist
with the Safety Appliances Act and Power
temperature-induced stresses.
Brake Law, ensuring brake efficiency and
Fastening Systems: Secure rails to ties,
prevention of derailments.
provide stability.
Suspension Systems Crossties: Distribute loads, maintain rail
alignment.
Side Frames and Bolsters: These
components provide structural support Substructure:
while allowing flexibility.
Ballast: Provides drainage, stability, and
Spring Damping: Springs with friction
adjusts track geometry.
wedges or hydraulic dampers enhance ride
Subballast: Separates ballast from
quality and minimize wear.
subgrade, improves resilience.
Steering Features: Some advanced trucks
Subgrade: Foundation layer that provides
improve lateral stability and reduce
overall stability
curving resistance, contributing to
smoother operations. Track Forces
Braking Systems Vertical Forces:
Air Brakes: Standard in North America, Generated by train weight; impact rail and
these use a brake pipe to control the air ballast integrity.
pressure and apply force to brake shoes,
ensuring consistent braking across the Lateral Forces:
train.
Dynamic Brakes: Locomotives equipped Due to curves and temperature changes;
with these brakes use traction motors as can lead to rail buckling.
generators to control speed.
Longitudinal Forces:
Advanced Cushioning: Hydraulic systems
reduce coupling forces and prevent Caused by train acceleration, braking, and
damage to cargo during impacts. thermal expansion/contraction.
Special Features Track Design Considerations
Coupler Cushioning: This reduces impact Vertical Track Stiffness:
forces during yard operations, protecting
cargo. Ensures adequate load distribution across
components.
 Lateral Stability: 3. Transfer wheel loads to spaced ties without
large deflection.
Prevents buckling through proper ballast 4. Resist tension failure from longitudinal
compaction and geometry. tensile force caused by rail temperature
reduction.
Drainage Systems:
5. Help resist buckling from longitudinal
Removes water to maintain track integrity compression force caused by rail temperature
and prevent fouling. increase.
6. Resist fatigue cracking from repeated wheel
loads.
7. Provide strong bolted or welded joints.
8. Limit rail impact by maintaining track
geometry and truing wheels to limit ‘‘false
flange’’wear on wheel and rail and reduce
wheel defects such as engine burns,
corrugations, and flat spots.
9. Permit tracks to cross over each other and
permit trains to switch from one track to
another.

Fastening Systems

1. Restrain the rail in the vertical, longitudinal,
and transverse directions.
2. Resist overturning of rail from lateral wheel
force.
3. Connect sections of rail to permit safe and
smooth train operation.
4. Create a canted (inclined) surface to provide
proper wheel/ rail contact—wood ties.
5. Spread the rail seat force over a larger part of
the tie surface to reduce the damage—wood ties.
6. Provide resiliency under the vertical wheel
Railway Track Design load—concrete ties.
7. Reduce tie abrasion trail seat—concrete ties.

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consists of superstructure and substructure. The 8. Provide damping of the high frequency
superstructure is composed of steel rails fastened to wheel-induced vibrations—concrete ties.
crossties. The rails are designed to support and guide
Crossties
flanged steel wheels through their prescribed position
in space. 1. Transfer the vertical wheel load from the rail
through the rail seat to the bottom of the ties to
FUNCTIONS OF TRACK COMPONENTS
provide an acceptable level or stress for the ties
and ballast.
Rails
2. Hold the fastening system so that it can
1. Guide the flanged wheels in the vertical, restrain the rails at the proper vertical, lateral,
letter l, and longitudinal directions. and longitudinal position and maintain the
2. Provide a smooth running surface. required gage.
 3. Provide a canted (inclined) surface for proper Drainage
wheel / rail contact—concrete ties.
Drainage is the single most important factor
Ballast governing the performance of track
substructure. A properly functioning drainage
1. Restrain the ties against vertical, lateral, and system provides the following:
longitudinal forces from the rails.
2. Reduce the pressure from the tie-bearing area 1. Intersects the water seeping up from the
to a level that is acceptable for the under- lying subgrade
materials. 2. Diverts the surface water flowing toward the
3. Provide the ability to adjust track geometry track
by rearranging the ballast particles by tamping 3. Removes water falling onto the track
and lining. 4. Carry off stone dust, sand, and other debris that
4. Assist in drainage of water from the track. otherwise could foul the track.
5. Provide sufficient voids between particles to
allow an efficient migration of unwanted fine Track Forces
particles from the ballast section. The forces applied to the track are vertical, lateral
6. Provide some resiliency to the track to decrease (parallel to the ties), and longitudinal (parallel to
rail, rail component, and wheel wear. the rails). These forces are affected by train travel
speed.
Subballast
1. Maintain separation between the ballast and Vertical
subgrade particles. The main vertical force is the repetitive downward
2. Prevent attrition of the hard subgrade surface by action of the wheel load. In addition, this wheel/
the ballast. rail interaction produces a corresponding lift-up
force on the ties away from the wheel load points.
3. Reduce pressure from the ballast to values
that can be sustained by the subgrade without The major factors affecting the magnitude of the
adverse effects. dynamic vertical forces are:
4. Intercept water from the ballast and direct it to
Nominal wheel load
the track drainage system.
Train speed
5. Provide drainage of water flowing upward from
Wheel diameter
the subgrade.
Vehicle unsprung mass
6. Provide some insulation to the subgrade to Smoothness of the rail and wheel surfaces
prevent freezing. Track geometry
7. Provide some resiliency to the track. Track modulus or vertical track stiffness

Subgrade Lateral

1. Provide a stable platform on which to construct One type of lateral force applied to the rail is the
the track. wheel force transmitted through friction
2. Limit progressive settlement from repeated between the wheel and top of the rail and by the
traffic loading. wheel flange acting against the inside face of the
3. Prevent massive slope failure. rail head, particularly on curves. Another lateral
force is the rail buckling resistance force.
4. Restrict swelling or shrinking from water
content change. The design lateral wheel force depends upon a
number of factors, including:
 Vehicle speed
Track geometry
Elevation difference between the two rails at the
same cross section
Transverse hunting movement due to the
train-track dynamics

Longitudinal
Sources of longitudinal rail forces are:

Speed
Locomotive traction
Locomotive and car braking
Expansion and contraction of the rails from
temperature change
Track grade
Special track, i.e., turnouts, at grade crossings,
rail crossings, dragging equipment, hot bearing
detectors

The ratio of lateral to vertical force (L / V) is also
important because it can cause loss of alignment
and even track buckling.

Track Systems Characteristics

Track system performance is a function of the
composite response of the track components
under the action of the train loads. Two
response characteristics are important to
consider in track design: vertical track stiffness
and lateral track stability.

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