Highway Development and Planning PDF

Summary

This presentation covers various aspects of highway development and planning, including classifications of roads, factors influencing highway alignment, and surveying methods. The presentation also discusses the advantages and disadvantages of different road patterns.

Full Transcript

HIGHWAY DEVELOPMENT
AND PLANNING
By Group 3
HIGHWAY PLANNING
Involves the planning, design, construction,
operation, and maintenance of roads, bridges, and
tunnels to ensure safe and effective transportation
of people and goods.
It is one of the most important things before
starting any project. It is the basic requirement for
the development and construction of highways.
HIGHWAY PLANNING
IMPORTANCE

Economic Growth and Development
Improved Mobility and Accessibility
Environmental Sustainability
Safety
DAVAO COASTAL ROAD

17.33-kilometer road
provides an alternative route
along the coastline
improve access between the
southern and northern parts of
Davao City
CLASSIFICATION OF ROADS
1. According to Traffic Volume
2. According to Transport Tonnage
3. According to Importance
4. According to Location and Function
5. According to Material Used
6. According to Rigidity
7. According to Topography
8. According to Speed and Accessibility
01
ACCORDING TO TRAFFIC VOLUME
Vehicle per
No. Types of Road
day

Very Heavy
1 Above 600
Traffic Road

Heavy Traffic
2 251 to 600
Road

Medium
3 70 to 250
Traffic Road

Light Traffic
4 Below 70
Road
02
ACCORDING TO TRANSPORT TONNAGE
Vehicle per
No. Types
day

1 Very Heavy Above 1524

2 Heavy Traffic 1017 to 1524

3 Medium 508 to 1017

4 Light Traffic Below 508
03

ACCORDING TO IMPORTANCE
Class I Roads - international and national roads /
expressways and national highways.
Class II Roads - region to region or neighboring
parts / major district roads.
Class III Roads - rural areas and barangays.
04
ACCORDING TO
LOCATION & FUNCTION
National Highways
State Highways
Major District Roads
Other District Roads
Village Roads
05
ACCORDING TO
MATERIAL USED
Earthen Roads
Gravel Roads
Murrum Roads
Kankar Roads
WBM Roads
Bituminous Road
Concrete Roads
05
ACCORDING TO MATERIAL USED

Earthen Roads Gravel Roads Murrum Roads Kankar Roads
05
ACCORDING TO MATERIAL USED

WBM Roads Bituminous Roads Concrete Roads
06
ACCORDING TO RIGIDITY
FLEXIBLE ROADS RIGID ROADS
07
ACCORDING TO TOPOGRAPHY
HILLY ROADS PLAIN AREA ROADS
08
ACCORDING TO SPEED &
ACCESSIBILITY
Freeways
Expressways
Highways
Arterials
Local Streets
Collector Roads
ROAD PATTERN
A road pattern is when the road is constructed
in patterns for the proper management of
traffic and to interconnect the branch roads
with main roads.
It is made to reduce the time and distance that
a vehicle takes to reach a destination.
It increases the response time of normal
vehicles as well as emergency vehicles to reach
their destination.
ROAD PATTERNS
1. RECTANGULAR OR BLOCK PATTERN
The whole area is divided into rectangular blocks.
Streets or branch roads intersect with each other at a right
angle.
The main roads always pass through the center and it
should be wide enough.
Branch roads may be more narrow compared to main roads.
The main roads should be provided with a direct approach
going outside the city.

ADVANTAGE:
1. The rectangular blocks can be further fractioned into smaller
blocks to accomodate more buildings.

DISADVANTAGE:
1. It is inconvenient since roads are perpendicular to each other
which increases accident rates due to poor visibility at a
perpendicular junction.
ROAD PATTERNS
2. RADIAL OR STAR & BLOCK PATTERN
It is a combination of star and block patterns.
The entire area is divided into a radial network of
roads radiating from the center outwardly with a
block pattern network of roads in between the radial
main streets.

ADVANTAGES:
1. Less risky compared to the rectangular pattern.
2. Reduces the level of congestion at the primary
bottleneck location.

DISADVANTAGE:
1. Lack of safety appurtenances like rail transitions,
crash attenuators and post support bases.
ROAD PATTERNS
3. RADIAL OR STAR & CIRCULAR PATTERN
The main roads (radial roads) radiate from the central
point and are connected with concentric roads (ring
roads) that are also radiating outwardly.

ADVANTAGE:
1. It is safer compared to previous patterns because
vehicles travel in the same direction which makes it
more efficient in improving traffic flow.

DISADVANTAGES:
1. Providing a good curve during the implementation of
this pattern is challenging.
2. It affects driving ability due to decrease in vision.
ROAD PATTERNS
4. RADIAL OR STAR & GRID PATTERN
A radial network of road radiates from the
center outwardly.
The main radial streets are interconnected by a
grid pattern.

ADVANTAGES:
1. It increases the effectiveness of land usage unit
density.
2. It improves traffic flow.

DISADVANTAGE:
1. High construction cost because of the need for extra
traffic signals, road marking, and lighting.
ROAD PATTERNS
5. HEXAGONAL PATTERN
The entire area is divided into hexagonal
patterns.
3 roads meet the boundary of the area formed
by the sides of the hexagon.
A hexagonal boundary is further split into
plots of the appropriate sizes.

ADVANTAGES:
1. Travel time and distance are cut down.
2. Reduced traffic congestion.

DISADVANTAGE:
1. High construction cost because of the need to
implement more traffic signs, pavement
markings, and illumination to minimize the risk
of accidents.
ROAD PATTERNS
6. MINIMUM TRAVEL PATTERN
The town is contented by sector centers,
suburban facilities, and neighborhood centers
by the highway -- all of which are connected to
the city center by a highway that can be
reached in the shortest amount of time.
The shortest roads interconnect the city center
with neighboring and suburban centers.
The alignment of the road is made straight to
shorten it.

ADVANTAGE:
1. Potentially dangerous collisions are almost
eliminated.

DISADVANTAGES:
1. The right amount of traffic signs, pavement
markings, and illumination should be in place
to alert vehicles to slow down.
2. For senior drivers, intersections may be
particularly difficult.
3.
ROAD PATTERNS
7. GRID PATTERN
A network of intersecting parallel lines, real or imaginary, is
referred to as a grid.
When seen from above, this pattern is made up of streets that
connect at right angles to form squares.

ADVANTAGES:
1. Grids benefit pedestrians since there are several routes from
point A to point B.
2. Grids benefit restaurants and retail establishments since they
provide several corner lots.
3. A grid's navigation is quite simple.

DISADVANTAGES:
1. Grids are dangerous for motorists and bicycles because they
contain numerous junctions and many potential conflict places.
2. Grids may encourage individuals to take shortcuts through
residential areas.
3. Grids don't work well in places with many hills since they result
in unnecessarily steep streets.
4. Traffic mayhem may readily occur on a grid that is uneven or
unfinished.
ROAD PATTERNS
8. LINEAR PATTERN
It comprises a road that expands linearly in one
direction, potentially due to certain natural resources
like the sea or ocean existing on one side of the city.

ADVANTAGE:
1. Potentially dangerous collisions are almost
eliminated.

DISADVANTAGE:
1. The right amount of traffic signs, pavement markings,
speed breakers, and illumination should be in place
to alert vehicles to slow down.
PLANNING SURVEY
Planning surveys involve several steps to ensure
that the survey meets its objectives and provides
accurate and reliable data.
The planning must have a forecast for the next
several years in order to plan fixed periods for
maintenance, renewal, and widening.
A highway should be planned according to the
volume of daily traffic flow from a particular path.
The highways developed must be efficient and safe
but at a minimum cost.
PLANNING SURVEY
ECONOMIC STUDIES

Involves understanding the following:

The various cost components of highway projects.
The economic feasibility of alternative highway
projects.
The decision on a scheme of investment on a
project at its various stages.
The funding source and policies for road projects.
PLANNING SURVEY
ECONOMIC STUDIES

The following data should be collected:

Details of the existing facilities and their utility
Distribution of the existing population in the area
Population growth trends
Existing products in the agricultural and industrial
sectors
Future trends of developments in the
abovementioned sectors
Existing communication and education facilities
Per capita income
PLANNING SURVEY
FINANCIAL STUDIES

Involves understanding the following:

The financial aspects and the manner in which
funds for the project may be mobilized.
It generally depends on the sources of income and
estimated revenue from taxation on road transport.
PLANNING SURVEY
FINANCIAL STUDIES

The following data should be collected:

Sources of funding
Estimated revenue from taxes on vehicles
Toll tax
Vehicles registration tax
Indirect benefits of raising living standards of the
people due to the proposed road network
PLANNING SURVEY
TRAFFIC OR ROAD USE STUDIES

Involves understanding the following:

Information collected during the planning and
design phases of a project
Impact of phased developments
The need for traffic signals
Accessibility of service and emergency vehicles on
site
PLANNING SURVEY
TRAFFIC OR ROAD USE STUDIES

The following data should be collected:

Details of existing road facilities
Traffic volume
Traffic flow patterns
Classes of traffic
Loads carried
Average speeds
Anticipated future trends of traffic growth
PLANNING SURVEY
ENGINEERING STUDIES

Involves understanding the following:

Activities involved in the planning and execution of
surveys for the location, design, construction,
operation, and maintenance of civil and other
engineered projects.
PLANNING SURVEY
ENGINEERING STUDIES

The following data should be collected:

Details of existing roads
Topographic survey
Soil survey
Road life
Drainage networks
HIGHWAY ALIGNMENT
-The path or route of a highway, including its
horizontal and vertical curves and grades.

IMPORTANCE OF PROPER ALIGNMENT
Safety: Reduces accidents by providing adequate
sight distances and curves that are easy to
navigate.
Efficiency: Minimizes travel time and fuel
consumption.
Environmental impact: Reduces noise pollution and
habitat disruption.
 HIGHWAY ALIGNMENT
FACTORS INFLUENCING HIGHWAY ALIGNMENT
Physical Factors:
Topography: Hills, valleys, mountains
Soil conditions: Stability, bearing capacity
Water bodies: Rivers, lakes
Land use: Residential, commercial, agricultural
Environmental Factors:
Wildlife habitats: Protected areas
Noise pollution: Impact on nearby communities
Air pollution: Emissions from vehicles
Economic Factors:
Cost of land acquisition: Price of land for the highway
Construction costs: Cost of building the highway, including
materials, labor, and equipment
Maintenance costs: Cost of maintaining the highway, including
repairs, cleaning, and landscaping
 HIGHWAY ALIGNMENT
DESIGN CONSIDERATIONS: CURVES

Horizontal Curves
Radius: Larger = faster speeds; smaller = slower speeds.
Degree of Curve: Smaller radius = sharper turn; larger = gentler
turn.
Central Angle: Bigger angle = longer curve.
Superelevation: Road tilt to prevent slipping.
Transition Curves: Smooth entry/exit to curves.

Vertical Curves
Radius: Larger = gentler slope; smaller = steeper slope.
Length: Longer curves improve visibility.
Grade Change: Steeper needs shorter curves; gentler allows
longer.
Sight Distance:
-Stopping: Distance to stop safely.
-Passing: Distance to pass safely.
 HIGHWAY ALIGNMENT
DESIGN CONSIDERATIONS: GRADES

Maximum Grades:
Uphill grades: The maximum hill steepness that a vehicle can
climb without stalling.
Downhill grades: The maximum steepness of a hill that a vehicle
can descend without losing control.
Design speed: The maximum safe speed for a vehicle to travel up
or down the grade.

Minimum Grades:
Drainage: The minimum slope required to allow water to drain
off the road.
Aesthetics: The minimum slope required to create a visually
pleasing appearance.
 HIGHWAY ALIGNMENT
DESIGN CONSIDERATIONS: SIGHT DISTANCES

Stopping Sight Distance:
Perception-reaction time: The time it takes for a driver to see a
hazard and react.
Braking distance: The distance it takes for a vehicle to stop after
the brakes are applied.

Passing Sight Distance:
Perception-reaction time: The time it takes for a driver to see a
hazard and react.
Braking distance: The distance it takes for a vehicle to stop after
the brakes are applied.
Passing distance: The distance required for a vehicle to safely
pass another vehicle.
HIGHWAY SURVEY
Highway survey is a professional way of land
survey which forms the basic phase in planning a
highway or a road project for transportation
purpose.
The objective of highway survey is to locate a
perfect alignment of roadways that serves as a
primary source of maximum transportation
facilities.
A proper highway survey provides an accurate
location and contour layout data of road, utilities,
drainages, overhead wires, near by structures,
buildings, and other features.
HIGHWAY SURVEY
MAP STUDY
Maps show the various topographical features like river,
hills, and valleys.
With the proper map study at the office, it is possible to
obtain the basic details to fix the alignment of roads.
Possible alignment can be fixed based on the following
details available on the map:
1. Alignment passing through valleys, lakes, and ponds
2. Location of bridges for crossing rivers
3. Availability of a mountain passing a mountain range
4. Joining of two stations at different elevation by taking a
suitable ruling gradient
5. Determination of length of the roadway using contour
interval and ruling gradient
HIGHWAY SURVEY
RECONNAISSANCE SURVEY
To collect the details of obstruction along the route which are
not available in the map.
To collect geological features of the field.
To collect information regarding the availability of local
construction material, water, and labor.
To determine the approximate values of a gradient, length of
gradients and radius of curves of alternate alignments.
To locate the obligatory points along the alternative routes.
To determine an approximate estimate of the total cost of
construction of the road along each route.
To determine two or three best possible routes.
HIGHWAY SURVEY
PRELIMINARY SURVEY
To survey along the various alignments found
after the reconnaissance and to collect all
necessary physical information and details of
topography, drainage, and soil.
To compare the different proposals in view of
the requirements of good road alignment.
To estimate the cost of constructing the road
including bridges and other construction aspects
along each alternative alignment of the road.
To finalize the best alignment from
construction, maintenance, and traffic operation
point of view.
HIGHWAY SURVEY
LOCATION SURVEY
The alignment finalized at the design office after the
preliminary survey is to be first located on the field
by establishing the centerline.
The detailed survey should be carried out for
collecting the information necessary for the
preparation of plans and construction details for the
highway project.
To determine the cost of the total road project.
HIGHWAY SURVEY
ENGINEERING SURVEYS
Traffic Survey - To design the road pavement, fixing the
number of traffic lanes, geometric design of roads and other
economical aspects.
Soil and Material Survey - Detailed information on various
classifications of soils is collected and various field tests and
laboratory test are being carried out for the purpose of their
suitability for embankments.
Drainage Survey - Required mainly for the purpose of design
of cross drainage structure and survey on drainage is quite
useful in fixing the gradient or grade lien of the road.
HIGHWAY SURVEY
TOPOGRAPHIC SURVEY
Topographic surveys consist of determining the
horizontal and vertical locations of objects on the
surface of the earth.
Topographic surveys show the nature of the
ground or profile of ground which is the most
essential part for proper road alignment.
 SURVEYING METHODS

TRADITIONAL & MODERN

are based on the use of instruments are based on the use of technologies
such as tape measures, levels, such as GPS, GNSS, LiDAR,
theodolites, and total stations to photogrammetry, and remote sensing to
measure distances, angles, and collect spatial data.
elevations.
 TRADITIONAL MODERN

Generally more cost-effective, Higher initial cost, but can
COST especially for small-scale be more efficient for large-
projects. scale projects.

SURVEYING extensive scope; captures
INFORMATION Manual data collection and
detailed, high-resolution
METHODS GATHERING less detailed information.
information

TRADITIONAL VS MODERN

Prone to human errors,
ACCURACY & Higher accuracy and
limited accuracy and
PRECISION precision.
precision.

Faster data collection and
Time-consuming, especially
SPEED processing, leading to
for large-scale projects.
shorter project timelines.