Highway and Railway Geometric Design PDF

Summary

This document provides a comprehensive look at the geometric design of highways and railways. Key elements including horizontal and vertical alignment, cross-section elements, and sight distance are discussed. The document also includes examples of problems related to simple curve calculations.

Full Transcript

MODULE 4

GEOMETRIC DESIGN
FOR HIGHWAYS
AND RAILWAYS
 Geometric Design of Highways

The geometric design of highways involves the physical
dimensions and layout of roadways, including alignment,
cross-sectional elements, and sight distance, to ensure
safety and efficiency.
 Geometric Design of Highways

The geometric design of highways involves the physical
dimensions and layout of roadways, including alignment,
cross-sectional elements, and sight distance, to ensure
safety and efficiency.
Key Elements of Highway Geometric Design

1.Horizontal Alignment

❑ Tangents (Straight Sections): Straight portions of the
roadway used to maintain high-speed travel.

❑ Curves: Used to change the direction of the road. Key
factors include curve radius, curve length,
superelevation (banking), and transition curves.
2. Vertical Alignment

❑Grades (Slopes): The slope of the road, crucial for
maintaining vehicle speed, especially on uphill or downhill
segments.

❑Vertical Curves: Provide smooth transitions between
different grades, enhancing safety and comfort. Crest
curves handle upward changes, while sag curves handle
downward changes.
3. Cross-Section Elements

❑Lanes: Define the space for vehicle movement,
typically 3.0 to 3.6 meters wide.

❑Shoulders: Provide recovery space for vehicles,
improve sight distance, and offer space for emergency
stops.

❑Medians: Separate opposing traffic flows, enhance
safety, and reduce headlight glare.

❑Side Slopes and Drainage Ditches: Ensure proper
drainage and prevent water accumulation on the
roadway.
4. Intersection and Interchanges

❑At-Grade Intersections: Points where roads cross at
the same level; design focuses on traffic control,
turning lanes, and visibility.

❑Grade-Separated Interchanges: Structures like
overpasses and underpasses used to separate
conflicting traffic flows, typically found on freeways.
5. Sight Distance

❑ Stopping Sight Distance (SSD): The distance
required for a driver to perceive a hazard and stop
the vehicle safely.

❑ Passing Sight Distance (PSD): Required distance
for a vehicle to safely overtake another vehicle on a
two-lane road.
6. Clear Zones and Roadside Design

❑ Clear Zones: Safe recovery areas free of fixed obstacles.

❑ Roadside Barriers: Protect vehicles from hazardous drop-
offs or obstacles.

7. Design Speed

❑ The speed selected as a basis for the geometric features of
the road, influencing lane width, curve radii, and sight
distances.
 Geometric Design of Railways

The geometric design of railways focuses on the layout and
dimensions of the track, ensuring smooth and safe operations of
trains. The design addresses horizontal and vertical alignment,
cross-section, and station design.
 Key Elements of Railway Geometric Design

1.Horizontal Alignment
❑ Tangents: Straight track segments that allow for maximum
train speeds.
❑ Curves: Required to change direction; designed with
appropriate radius, transition curves, and cant
(superelevation) to manage centrifugal forces.

2. Vertical Alignment
❑ Grades: Longitudinal slopes of the railway track, kept as
gentle as possible to minimize traction and braking
requirements.
❑ Vertical Curves: Smooth transitions between grades to
enhance passenger comfort and maintain train stability.
3. Track Cross-Section

❑ Rails: Steel tracks supported by sleepers, maintaining the
gauge.
❑ Ballast: Crushed stone that provides stability, drainage, and load
distribution.
❑ Subgrade: The foundational layer beneath the ballast that
supports the entire track structure.

4. Stations and Platforms

❑ Station Layout: Designed for efficient passenger movement,
train operations, and accessibility.
❑ Sleepers (Ties): Support the rails and maintain their position
and gauge.
❑ Platform Design: Includes height, length, and width to ensure
safe boarding and alighting from trains.
5. Turnouts and Crossings

❑ Crossings (Diamonds): Enable track intersections, allowing
two tracks to cross without the need for level separation.

6. Safety and Signaling Systems

❑ Turnouts (Switches): Allow trains to change tracks, critical in
junctions and yards.
❑ Geometric design integrates safety features and signaling
systems to manage train movements, ensuring smooth and
conflict-free operations.
 References
American Association of State Highway and Transportation Officials (AASHTO), A
Policy on Geometric Design of Highways and Streets, 7th Edition, 2018.

Highway Capacity Manual (HCM), 6th Edition, 2016. Transportation Research Board,
National Academies of Sciences, Engineering, and Medicine.

Manual on Uniform Traffic Control Devices (MUTCD), 2009 Edition. Federal Highway
Administration (FHWA).

AREMA Manual for Railway Engineering, 2021. American Railway Engineering and
Maintenance-of-Way Association.

Design of Highway and Railway Geometric Elements, Institute of Transportation
Engineers (ITE), 2020.

O’Flaherty, C. A., Highways: The Location, Design, Construction, and Maintenance of
Road Pavements, 2002.

Turner, D., and Ellis, M., "Railway Engineering: An Integral Approach", 2017.
 Assignment # 2

Expound and discuss the following questions for at least
200 words each. Write your answers using pen (black ink)
and paper (short bond paper).

1. What are the challenges in the utilization of highway
infrastructures in the Philippines a) by the governing bodies
b) passengers or commuters?

2. What are the challenges in the utilization of railroad
infrastructures in the Philippines a) by the governing bodies
b) passengers or commuters?
 FORMAT
__________________________________________________________________________

HIGHWAY AND RAILROAD ENGINEERING
TCIE 3-3 3-6pm Wed Room: 3105
ASSIGNMENT NO. 2

Dela Cruz, Juan P. Prof: Engr. Crispin S. Lictaoa
BSCE 22-1-1234 Date: August 28, 2024
__________________________________________________________________________

1. Write the question # 1 here.

Answers:

2. Write the question # 2 here.

Answers:
 MODULE 4A
HIGHWAY GEOMETRIC DESIGN
DESIGN OF HORIZONTAL ALIGNMENT
FIELD SURVEY INFORMATION AND INVESTIGATION

PRELIMINARY SURVEY
FIELD SURVEY INFORMATION AND INVESTIGATION
PRELIMINARY SURVEY
Objectives of preliminary survey are:
To survey the various alternative alignments proposed after
the reconnaissance and to collect all the necessary
physical information and detail of topography, drainage,
and soil.
To compare the different proposals in view of the
requirements of the good alignment.
To estimate quantity of earthwork materials and other
construction aspect and to workout the cost of the
alternate proposals.
FIELD SURVEY INFORMATION AND INVESTIGATION
PRELIMINARY SURVEY

Methods of preliminary survey are:
Conventional approach | survey party carries out surveys using
the required field equipment, taking measurement, collecting
topographical and other data and carrying out soil survey.
Modern rapid approach | by aerial survey taking the required
aerial photographs for obtaining the necessary topographic
and other maps including details of soil and geology.
Finalize the best alignment from all considerations by
comparative analysis of alternative routes.
FIELD SURVEY INFORMATION AND INVESTIGATION
PRELIMINARY SURVEY: HORIZONTAL ALIGNMENT
Horizontal alignment involves circular curves, transition curves,
and tangents.
It aims to ensure safe and uninterrupted travel at a consistent
speed for extended road segments.
Design considerations include safety, functional classification,
desired speed, topography, vertical alignment, construction
cost, cultural development, and aesthetics.
Properly balancing these factors results in an alignment that is
both safe and cost-effective, while also harmonizing with the
land's natural contour.
A. Circular Curves
❑ Simple Curve – a circular curve is an arc with a single constant radius
connecting two tangents. The most common type of curve used in a
horizontal alignment.
❑ Compound Curve - composed of two or more adjoining circular arcs of
different radii. The centers of the arcs of the compound curves are located
on the same side of the alignment.
❑ Broken-Back Curve - the combination of a short length of tangent between
two circular curves.
❑ Reverse Curve - consists of two adjoining circular arcs with the arc centers
located on opposite sides of the alignment.
❑ Note: Compound and reverse curves are generally used only in specific
design situations such as mountainous terrain.
 GEOMETRIC DESIGN OF ROADS

is the branch of highway engineering concerned with the positioning of the physical elements
of the roadway according to standards and constraints.

The basic objectives in geometric design are to optimize efficiency and safety while minimizing
cost and environmental damage.

Geometric design also affects an emerging fifth objective called "livability," which is defined as
designing roads to foster broader community goals, including providing access to employment,
schools, businesses and residences, accommodate a range of travel modes such as walking,
bicycling, transit, and automobiles, and minimizing fuel use, emissions and environmental
damage.
 GEOMETRIC DESIGN OF ROADS

Geometric roadway design can be broken
into three main parts:
1. Alignment
2. Profile
3. Cross-section
 DESIGN OF HORIZONTAL ALIGMENT
Horizontal Curves-provides a transition between two tangent lengths of roadway.
 DESIGN OF HORIZONTAL ALIGMENT

Types of Curves:

1. Simple Curve
2. Compound Curve
3. Reverse Curve
4. Spiral Curve
 Simple Curve
❑ A simple curve is a circular arc,
extending from one tangent to the
next.

❑ The point where the curve leaves
the first tangent is called the "point
of curvature" (P.C.)

❑ The point where the curve joins the
second tangent is called the "point
of tangency" (P.T.). The P.C. and
P.T. are often called the tangent
points.
 Simple Curve
❑ If the tangent be produced, they will meet in a
point of intersection called the "vertex".

❑ The distance from the vertex to the P.C. or P.T.
is called the "tangent distance".

❑ The distance from the vertex to the curve is
called the "external distance" (measured
towards the center of curvature).

❑ While the line joining the middle of the curve
and the middle of the chord line joining the
P.C. and P.T. is called the "middle ordinate".
Simple Curve
 Sample Problem Simple Curve

A simple curve of the proposed extension of Aguinaldo
Highway have a direction of tangent AB which is due north
and tangent BC bearing N50°E. Point A is at the P.C. whose
stationing is 20+130.46. The degree of curve is 4°.

1. Compute the long chord of the curve.
2. Compute the stationing of point D on the curve along a
line joining the center of the curve which makes an
angle of 54° with the tangent line passing thru the P.C.
3. What is the length of the line from D to the intersection
of the tangent AB?
Sample Problem Simple Curve
 Sample Problem Simple Curve

A simple curve have tangents AB and BC
intersecting at a common point B. AB has an
azimuth of 180° and BC has an azimuth of 230°. The
stationing of the point of curvature at A is 10+140.26.
If the degree of the curve of the simple curve is 4°:

1. Compute the length of the long chord from A.
2. Compute the tangent distance AB of the curve.
3. Compute the stationing of a point “X” on the
curve on which a line passing through the center
of the curve makes an angle of 58° with the line
AB, intersects the curve at point “X”.
Sample Problem Simple Curve
 Sample Problem Simple Curve
A simple curve connects
two tangents AB and BC
with bearing N85°30’E and
S68°30E’ respectively. If the
stationing of the vertex is
4+360.20 and the
stationing of PC is
4+288.40. Determine the
following:

1. Radius of the curve
2. External Distance
3. Middle Distance
4. Chord Distance
5. Length of the curve
 Compound Curves

❑ Compound Curve consists of two or more consecutive simple curves having
different radius, but whose centers lie on the same side of the curve, likewise
any two consecutive curves must have a common tangent at their meeting
point.

❑ When two such curves lie upon opposite sides of the common tangent, the
two curves then turns a reversed curve.

❑ In a compound curve, the point of the common tangent where the two
curves join is called the point of compound curvature (P.C.C.)
Compound Curves
 Sample Problem Compound Curve

The long chord from the P.C. to the P.T. of a
compound curve is 300 meters long and the
angles it makes with the longer and shorter
tangents are 12° and 15° respectively. If the
common tangent is parallel to the long chord:

1. Find the radius of the first curve.
2. Find the radius of the 2nd curve.
3. If stationing of P.C. is 10+204.30, find the
stationing of P.T.
Sample Problem Compound Curve
Sample Problem Compound Curve
 Reversed Curves

❑ A reversed curve is formed by two circular simple curves having a common tangent but lies on opposite sides.

❑ The method of laying out a reversed curve is just the same as the deflection angle method of laying out
simple curves.

❑ At the point where the curve reversed in its direction is called the Point of Reversed Curvature.

❑ After this point has been laid out from the P.C., the instrument is then transferred to this point (P.R.C.). With
the transit at P.R.C. and a reading equal to the. total deflection angle from the P.C. to the PRC., the P.C. is
backsighted.

❑ If the line of sight is rotated about the vertical axis until horizontal circle reading becomes zero, this line of
sight falls on the common tangent. The next simple curve could be laid out on the opposite side of this
tangent by deflection angle method.
Reversed Curves
Reversed Curves
Reversed Curves
Sample Problem No. 1 Reversed Curve
Sample Problem Reversed Curve
 Sample Problem No. 2 (Reversed Curve)

Two converging tangents have azimuth of 300° and 90° respectively,
while that of the common tangent is 320°. The distance from the point
intersection of the tangents of PI of the second curve is 100m while
the station of PI of the first curve is 10+432.24. If the radius of the first
curve is 285.40m, determine the following:

a. Radius of the second curve
b. Stationing of PRC
c. Stationing of PT
 Midterm Seatwork No. 1 (30 points)
Given the perpendicular distance between two
parallel tangents equal to 6m, the central angle
being equal to 7° and the radius of the curvature of
the first curve equal to 163.8 meters. Find the radius
of the second curve of the reversed curve. Illustrate
the R.C.
 MODULE 5

STRUCTURAL DESIGN
OF RAILWAYS AND
PAVEMENTS
The structural design of railways and pavements involves ensuring these
systems can withstand loads and environmental factors while providing safety
and durability.

Railway Structural Design

1.Track Structure:

❑ Rails: Typically made of steel, rails must be designed to handle
the dynamic loads from trains. They are laid on sleepers or ties.
❑ Sleepers/Ties: Wooden, concrete, or steel beams that support
and maintain the gauge of the rails.
❑ Ballast: Crushed stone or gravel placed under and around the
sleepers to support the load and facilitate drainage.
❑ Subgrade: The prepared ground or foundation that the track
structure rests upon. It must be stable and capable of supporting
the railway loads.
2. Track Geometry:

❑ Horizontal Alignment: Curves need to be designed to
accommodate the centrifugal forces and ensure safe train
operation.

❑ Vertical Alignment: Includes gradients and transitions that
must be managed to prevent excessive wear and ensure safe
acceleration and braking.
3. Load Considerations:

❑ Dynamic Loads: Trains exert dynamic loads that vary with
speed, load, and track conditions. This needs to be accounted
for in design.

❑ Static Loads: The static load from the weight of the rail and
sleepers also needs to be supported by the subgrade.
4. Maintenance:

❑ Regular maintenance is crucial to address issues such as
track deformation, ballast degradation, and rail wear.

5. Drainage:

❑ Proper drainage systems must be incorporated to prevent
water accumulation, which can weaken the track structure
and cause damage.
 Pavement Structural Design

1. Pavement Layers:

❑ Surface Course: This is the top layer and must provide a smooth, skid-
resistant surface. Materials include asphalt or concrete. The design
involves selecting the appropriate mix and thickness to handle traffic
loads and environmental conditions.
❑ Base Course: This layer distributes the loads from the surface course to
the subbase. It typically consists of crushed stone or gravel. The design
focuses on achieving the required strength and stability.
❑ Subbase: The subbase improves load distribution and provides
additional support. It is often composed of granular materials that
facilitate drainage.
❑ Subgrade: The natural soil or rock layer underneath the pavement. It
must be adequately prepared and stabilized to support the pavement
structure. Geotechnical analysis is used to assess the suitability of the
subgrade.
2. Load Distribution:

❑ Traffic Loads: Pavements must be designed to support
various vehicle loads, including heavy trucks and cars.
Design methods like those outlined in the AASHTO
(American Association of State Highway and Transportation
Officials) guide are used to determine the required
pavement thickness and materials.

❑ Environmental Loads: Pavements must withstand
environmental conditions such as temperature variations,
precipitation, and freeze-thaw cycles. The design includes
provisions for thermal expansion and contraction.
3. Design Considerations:

❑ Structural Capacity: The pavement must be designed to
distribute loads to the underlying layers without causing
excessive deformation. Structural capacity is determined
based on expected traffic loads and material properties.

❑ Durability: The materials used must be durable enough to
resist wear from traffic and environmental conditions. This
includes selecting appropriate mixes and construction
techniques.
4. Drainage:

❑ Pavement Drainage: Effective drainage systems are crucial to
prevent water infiltration that can weaken the pavement. This
includes designing appropriate cross-slopes and drainage
channels.

5. Maintenance:

❑ Pavement Maintenance: Regular maintenance activities include
crack sealing, pothole repair, and resurfacing to address wear
and extend the pavement's lifespan.
 References

“Introduction to Railway Engineering” by Joseph A. Dyer. This book provides
foundational knowledge on railway track design and maintenance.

AREMA Manual for Railway Engineering: A comprehensive guide that covers various
aspects of railway engineering, including track structure and geometry.

“The Track and Track Work” by the International Union of Railways (UIC). This
document offers detailed information on track design and construction standards.

“Principles of Pavement Design” by E. J. Yoder and M. W. Witczak. This book covers the
fundamental principles of pavement design and analysis.

AASHTO Guide for Design of Pavement Structures: Provides guidelines for the design of
pavement structures, including material selection and layer thicknesses.

“Asphalt Pavements: A Practical Guide to Design, Production, and Maintenance” by
Bob M. Green and R. L. Parsons. This guide offers practical insights into the design and
maintenance of asphalt pavements.
 MODULE 6
Failures,
Maintenance and
Rehabilitation of
Transportation
Structure
“Transportation infrastructure, including railways
and pavements, is subject to various types of
failures over time. Understanding these failures,
and implementing appropriate maintenance and
rehabilitation strategies, is crucial for ensuring
safety, reliability, and longevity.”
 Railway Infrastructure Failures:

❑ Track Failures: These can include rail defects (e.g., cracks or
breaks), misalignment, and excessive wear. Track failures can be
caused by dynamic loads, poor maintenance, or material fatigue.

❑ Sleeper/Tie Failures: Wooden sleepers may decay, while concrete
or steel sleepers can suffer from cracking or corrosion. Poor
drainage or overloading can exacerbate these issues.

❑ Ballast Failures: Ballast can become degraded over time due to
traffic loads, weather conditions, and poor drainage. This leads to
track instability and misalignment.

❑ Subgrade Failures: Weak or unstable subgrade can lead to track
settlement and deformation. This can be due to inadequate
compaction, water infiltration, or soil erosion.
 Pavement Failures:
❑ Cracking: Common types include transverse, longitudinal,
and alligator cracks. Cracking can result from thermal stress,
load-induced stress, or poor construction practices.

❑ Potholes: These are depressions or holes that form due to
the combined effects of traffic loads and moisture infiltration.
Freeze-thaw cycles often exacerbate pothole formation.

❑ Rutting: Permanent deformations in the wheel paths caused
by the accumulation of plastic deformations in the asphalt
layer. Rutting can be caused by heavy traffic loads and high
temperatures.

❑ Settlement: Uneven settling or subsidence can occur due to
inadequate compaction of the subgrade, changes in moisture
content, or soil erosion.
 MAINTENANCE

1. Railway Maintenance:

❑ Track Inspection and Repair: Regular inspections are
conducted to identify defects in rails, sleepers, and track
alignment. Maintenance tasks include rail grinding, replacing
defective components, and adjusting track alignment.
❑ Ballast Maintenance: Periodic renewal of ballast is necessary to
maintain track stability. This includes reballasting, tamping to
restore proper track geometry, and ensuring effective drainage.
❑ Subgrade Stabilization: Techniques such as soil stabilization,
drainage improvement, and reinforcing with geotextiles are used
to address subgrade issues and prevent further settlement.
2. Pavement Maintenance:

❑ Crack Sealing: Applying sealant to cracks helps prevent water
infiltration and further damage. This is a common preventive
maintenance measure.

❑ Pothole Repair: Potholes are typically repaired using cold mix or
hot mix asphalt. Proper preparation and compaction are essential
to ensure durability.

❑ Surface Sealing: Applying a surface sealant or overlay can extend
the life of the pavement by providing a new wearing surface and
protecting against moisture and UV damage.

❑ Rejuvenation: For asphalt pavements, rejuvenating agents can be
applied to restore the flexibility and reduce the effects of aging.
 REHABILITATION

1. Railway Rehabilitation:

❑ Track Renewal: Involves replacing old rails and sleepers,
and sometimes the ballast. This is often necessary when the
track has reached the end of its service life.

❑ Subgrade Reconstruction: If the subgrade has deteriorated
significantly, it may need to be reconstructed or reinforced to
restore its load-bearing capacity.

❑ Upgrading Track Structure: This may include improving
track geometry, adding additional support structures, or
modernizing signaling and control systems.
2. Pavement Rehabilitation:

❑ Overlay: Adding a new layer of asphalt or concrete over the existing
pavement can address surface distresses and improve the structural
capacity. This is known as a surface or structural overlay.

❑ Full-Depth Reclamation (FDR): This involves milling the entire
pavement layer, mixing it with stabilizing agents, and then re-laying it.
FDR is used when the existing pavement is severely damaged.

❑ Pavement Reconstruction: This is a more extensive process that
involves completely removing and rebuilding the pavement structure,
including the base and subbase layers.

❑ Milling and Resurfacing: Milling involves removing the top layer of
the pavement to a specified depth and then resurfacing it with new
material. This method is often used to correct surface distresses and
improve ride quality.
 References

“Introduction to Railway Engineering” by Joseph A. Dyer. This book provides an
overview of railway track design, maintenance, and rehabilitation.

AREMA Manual for Railway Engineering: This comprehensive guide covers track
structure, maintenance practices, and rehabilitation techniques.

“The Track and Track Work” by the International Union of Railways (UIC).
Detailed information on track maintenance and failure management.

“Principles of Pavement Design” by E. J. Yoder and M. W. Witczak. This book
covers the design, failure mechanisms, and rehabilitation strategies for pavements.

AASHTO Guide for Design of Pavement Structures: Offers guidelines on the
design, maintenance, and rehabilitation of pavement structures.

“Asphalt Pavements: A Practical Guide to Design, Production, and
Maintenance” by Bob M. Green and R. L. Parsons. This guide includes practical
insights on pavement maintenance and rehabilitation techniques.
 MODULE 6A

THEORIES AND PROCEDURES ON
VISUAL ROAD CONDITION
(ROCOND) ASSESSMENT
Road Condition (RoCond) Survey Objectives:
Record, describe and measure the condition of the
road at the time of rating

Provide a sequence of recorded condition that can be
analyzed to indicate performance trends

Provide condition data for analysis in the Pavement
Management System (PMS), Routine Maintenance
Management System (RMMS), and eventually for
budgeting in the Multi-Year Programming System
(MYPS).
 Procedures in RoCond Assessment

I. Survey Preparation
Survey schedule and form a survey team.
Survey instruments, survey forms, service vehicle, etc.
Prepare survey gadgets, food and water.
Survey Equipment: Measuring tools and Safety gears
Service Vehicle Measuring Wheel/Measuring Crack Width Scale
Tape

Straight Edge, 1.2m long &
Spray Paint (or other appropriate road
Measuring Wedge Field Worksheets/pen or
marking materials, e.g. Chalk, Charcoal)
pencil

Jackets/Long Sleeves Shirt
Hats/Caps
Rubber Shoes
Safety devices for Traffic guide:
Safety Vests Traffic Guidance Cones

Appropriate Advance Warning Signs (Flags, Tarpaulin, etc…)
Straight Edge and Measuring Wedge
 Procedures in RoCond Assessment
II. RoCond Survey Activities
a) Ensure the observance of proper road safety precaution,
before and during the survey.
 Procedures in RoCond Assessment
II. RoCond Survey Activities
b) Establish RATING SEGMENTS along the entire road sections.
c) Establish the GAUGING LENGTH for every rating segment created and
mark every 100m distance thereafter within the segment.
d) Mark the measured distances with paint along the edge of the
pavement or other adjacent permanent references in increasing direction.
These markings will be the basis of the conduct of surveys for the
succeeding years to avoid re-measurement of distances and shorten the
duration of survey.
e) Start assessing, measuring and recording the distresses found along each
segment in accordance with RoCond Procedures and Guidelines.
Road Condition Survey Lane Designation:

GENERAL RULE: Negative
Direction

Asphalt Surface
Positive
Direction

If there are road
Negative
Direction

widening in both
outer lane. The
designation of Positive
Direction

Lane number will
change.
 Elements of RoCond Assessment
✓ RATING SEGMENT

✓ GAUGING LENGTH

✓ ROAD DISTRESSES/DEFECTS
I. RATING SEGMENTS
Segmenting Procedure
RATING
GENERAL RULE: SEGMENT

Assessment of segments designated as between consecutive
kilometer posts of homogenous surface types but should not
exceed 1300-meters.
Segment 1

Concrete Surface

L ≤ 1300m
 Segmenting Procedure: RATING SEGMENT

a.) If the distance between two (2) consecutive kilometer posts
exceeds 1300m of homogenous surface type, adopt the 1000
meter rating segment and the remaining length should be
considered as another segment.
 Segmenting Procedure: RATING SEGMENT

b.) Change in Surface Type
 Segmenting Procedure:
c.) Change in No. of Lanes
 Segmenting Procedure:
d.) Distinct change in the condition of pavement
 Segmenting Procedure:
e.) Segments of asphalt and concrete with length less than 50m are
considered not assessable except for gravel/earth which are
assessed (regardless of length).
Segment 1 Segment 2 Segment 3 Segment 4
(not assessable) (assessable)

Asphalt Concrete Earth Concrete
Surface Surface Surface Surface

L1 L2 200mm Width = 220mm
Length = 13m

Width = 210mm
Length = 1m
 EDGE BREAK

Edge Break:
75 < 200mm Width = 150mm
Length = 1m
FLEXIBLE PAVEMENT
(ASPHALT)
EDGE BREAK
FLEXIBLE PAVEMENT
DES FORM: (ASPHALT)

15
L
 FLEXIBLE PAVEMENT
PATCHES (ASPHALT)

Defined as a successfully executed
permanent repair with a surface
condition similar to the
surrounding pavement
Assessed over the total area of
segment
Defective patches are not rated as
patches but the defects within the
patch are rated under the
applicable defects (ex. Cracks,
potholes/base failure)
The length of patches is recorded
per width category
PATCHES

FLEXIBLE PAVEMENT
(ASPHALT)
PATCHES
FLEXIBLE PAVEMENT
DES FORM: (ASPHALT)

10
 FLEXIBLE PAVEMENT
POTHOLES/BASE FAILURE (ASPHALT)

❑ Defined as the holes of various shapes and
sizes in the pavement surface reaching the
base coarse/unbound layer.
❑ For rating purposes, severe cracking with
base failure/settlement/ depression shall also
be considered as potholes.

Potholes/Base failures are recorded as
the number of potholes equivalent to
0.25 m2 per pothole. The total area of
potholes for the first 100m multiply
by 4 to get the no. of potholes.
Assessed over the total area of segment.
 POTHOLES/BASE FAILURE
FLEXIBLE PAVEMENT
No. of Potholes = (ASPHALT)
Area*4

Width 1.0m
 POTHOLES/BASE FAILURE
No. of Potholes = FLEXIBLE PAVEMENT
Area*4 (ASPHALT)

Width 1.5m
 POTHOLES/BASE FAILURE
Split or Cut the rating segment to separate the portion with base
failure (at least 50m length)

FLEXIBLE
PAVEMENT
(ASPHALT)
 POTHOLES/BASE FAILURE
FLEXIBLE PAVEMENT
DES FORM: (ASPHALT)
SURFACE FAILURE

Defined as loss of the wearing course
layer. These failures can be caused by
surface delamination or mechanical
damage.
Assessed over the total area of segment
Surface Failures are recorded as the
number of surface failures equivalent to
0.25 m2 per surface failures. The total
area of surface failures multiply by 4 to
get the no. of surface failures.

FLEXIBLE PAVEMENT
(ASPHALT)
 FLEXIBLE PAVEMENT
SURFACE FAILURE (ASPHALT)

No. of Surface Failure = Area*4

Width Width 1m
0.5m

Length 1m
SURFACE FAILURE

DES FORM:

FLEXIBLE PAVEMENT
(ASPHALT)
 WEARING SURFACE

This rating includes both Raveling and Bleeding
Raveling is the loss or disintegration of stones, typically occurring in the
wheel path
Bleeding/Flushing is the occurrence of excessive bitumen on the surface of
the pavement
Assessed over the total area of segment
FLEXIBLE PAVEMENT
(ASPHALT)
 FLEXIBLE PAVEMENT
WEARING SURFACE (ASPHALT)

Raveling
Bleeding/Flushing

Minor Wearing
 FLEXIBLE PAVEMENT
WEARING SURFACE (ASPHALT)

SEVERITY:
Minor 'M' = Surface still relatively smooth with only some loss of fine
aggregate or in the case of bleeding there are some signs of excess binder.

Severe 'S' = Surface rough or pitted with both fine and coarse
aggregate lost or in the case of bleeding the surface is covered with excess
binder with skid resistance poor.
WEARING SURFACE
FLEXIBLE PAVEMENT
DES FORM: (ASPHALT)
 PAVEMENT CRACKING

Assessed over the total area of segment
Rated according to the type of cracking, i.e. Longitudinal, Crocodile, or
Transverse Crackings
Severity:
Wide Cracks (>3mm)
Narrow Cracks (3mm) or Narrow
Cracks (99mm
2 - Depth of gravel 50mm - 99mm
3 - Depth of gravel 25mm - 49mm
4 - Depth of gravel 0mm - 24mm
 UNPAVED ROAD
B. Material Quality
⮚ The Material Quality of the imported material or exposed sub-grade is
rated for Gravel roads.
⮚ The in-situ Material Quality is rated for Earth Roads.

⮚ Local knowledge of the roads must be used, if the surveyors know the
road is problematic after rains, then this must be considered when
rating the condition.

CONDITION SCORE:
1 – GOOD MATERIAL QUALITY
2 – FAIR MATERIAL QUALITY
3 – POOR MATERIAL QUALITY
4 – BAD MATERIAL QUALITY
 UNPAVED ROAD

B. Material Quality

Even size distribution
with sufficient plasticity to
bind the material – no
significant oversize
material (not bigger than
2 inches in diameter). Material Quality - Good (1)
 UNPAVED ROAD

B. Material Quality

Material Quality - Fair (2)

Loose material or
stones clearly visible
 UNPAVED ROAD

B. Material Quality

Poor particle size distribution Material Quality - Poor (3)
with excessive oversize
material. Plasticity is high
enough to cause slipperiness
or low enough to cause
excessive loose material
resulting in loss of traction
 UNPAVED ROAD

B. Material Quality

Poorly distributed range
of particle sizes, zero or
excessive plasticity,
excessive oversize
material
Material Quality - Bad (4)
 UNPAVED ROAD

C. Crown Shape

⮚ Crown Shape is determined to be the height of the center of
the road above the edge of the road
⮚ This determines the ability of the road to shed water from it
surface

CONDITION SCORE:
1 – GOOD MATERIAL QUALITY
2 – FAIR MATERIAL QUALITY
3 – POOR MATERIAL QUALITY
4 – BAD MATERIAL QUALITY
 UNPAVED ROAD

C. Crown Shape

Crown Shape - Good (1)

>2% crossfall –
no significant
ponding
 UNPAVED ROAD

C. Crown Shape

Crown Shape - Fair (2)

Crossfall mostly