CVE 06 Highway And Railroad Engineering Module 11 PDF

Summary

This document provides an in-depth analysis of highway and railroad engineering, focusing on grade separations and interchanges. It covers various factors, warrants, and configurations related to these crucial elements of transportation infrastructure.

Full Transcript

Republic of the Philippines
SOUTHERN LUZON STATE UNIVERSITY
College of Engineering
Civil Engineering Department
Lucban, Quezon

CVE 06 HIGHWAY AND RAILROAD ENGINEERING
Module No. 11

GRADE SEPARATIONS AND INTERCHANGES

The ability to accommodate high volumes of traffic safely and efficiently through
intersections depends largely on the arrangements provided for handling
intersecting traffic. The greatest efficiency, safety, and capacity are attained when
the intersecting traveled ways are grade separated.

An interchange is a system of interconnecting roadways in conjunction with one or
more grade separations that provides for the movement of traffic between two or
more roadways or highways on different levels.

Factors in selecting appropriate type of grade separation and interchange
- highway classification
- character and composition of traffic
- design speed
- degree of access control
- economics
- terrain
- right-of-way

To avoid conflicts between vehicles, pedestrians, and/or bicycles within
interchanges, it is preferable to separate their movements. When separation cannot
be provided, each interchange site should be studied and alternate designs
considered to determine the most appropriate arrangement of structures and ramps
to accommodate bicycle and pedestrian traffic through the interchange area.

WARRANTS FOR INTERCHANGES AND GRADE SEPARATIONS

The following six conditions, or warrants, should be considered when determining if
an interchange is justified at a particular site:

1. Design designation. The determination to develop a highway with full control of
access between selected terminals becomes the warrant for providing highway
grade separations or interchanges for all intersecting roadways crossing the
highway.

2. Reduction of bottlenecks or spot congestion. Insufficient capacity at the
intersection of heavily traveled routes results in intolerable congestion on one or all
approaches. Inability to provide essential capacity with an at-grade facility provides
a warrant for an interchange where development and available right-of-way permit.

3. Safety improvement. Some at-grade intersections have a disproportionate rate
of serious crashes. If inexpensive methods of eliminating crashes are likely to be
ineffective or impractical, a highway grade separation or interchange may be
warranted.

CVE 06 HRE 11 118
JCSaliendra
4. Site topography. At some sites, grade-separation designs are the only type of
intersection that can be constructed economically. The topography at the site may
be such that, to satisfy appropriate design criteria, any other type of intersection is
physically impossible to develop or is equal to or greater than the cost of a grade-
separated design.

5. Road-user benefits. The road-user costs due to delays at congested at-grade
intersections are large. Road-user costs, such as fuel and oil usage, wear on tires,
repairs, delay to motorists, and crashes that result from speed changes, stops, and
waiting, are well in excess of those for intersections permitting uninterrupted or
continuous operation. In general, interchanges involve somewhat more total travel
distance than direct crossings at grade, but the added cost of the extra travel
distance is less than the cost savings resulting from the reduction in stopping and
delay. The relation of road-user benefits to the cost of improvement indicates an
economic warrant for that improvement.

6. Traffic volume warrant. Volumes in excess of the capacity of an at-grade
intersection would certainly be a warrant. Interchanges are desirable at cross
streets with heavy traffic volumes because the elimination of conflicts due to high
crossing volume greatly improves the movement of traffic.

Not all warrants for grade separations are included in the warrants for interchanges.
Additional warrants for grade separations include grade separations that would:
→ Serve local roads or streets that cannot practically be terminated outside
the right- of-way limits of freeways.
→ Provide access to areas not served by frontage roads or other means of
access.
→ Eliminate a railroad-highway grade crossing.
→ Serve unusual concentrations of pedestrian traffic (for instance, a city park
developed on both sides of a major arterial).
→ Serve bikeways and routine pedestrian crossings.
→ Provide access to mass transit stations within the confines of a major
arterial.
→ Assure free-flow operation of certain ramp configurations and serve as
part of an interchange.

Interchange Configurations

CVE 06 HRE 11 119
JCSaliendra
 Interchange Configurations

Typical Grade Separation Structures With Closed Abutments

CVE 06 HRE 11 120
JCSaliendra
 Typical Grade Separation Structure With Open-End Span

Two Variations Of Roadways Crossing At Three Or Four Levels

Overpass Roadways

Typical Overpass Structures
CVE 06 HRE 11 121
JCSaliendra
 Typical Overpass Structures

INTERCHANGES

Three-Leg Designs

An interchange with three intersecting legs consists of one or more highway grade
separations and one-way roadways for all traffic movements. When two of the three
intersection legs form a through road and the angle of intersection is not acute, the
term T interchange applies. When all three intersection legs have a through
character or the intersection angle with the third intersection leg is small, the
interchange may be considered a Y configuration. A clear distinction between the T
and Y configurations is not important. Regardless of the intersection angle and
through-road character, any basic interchange pattern may apply for a wide variety
of conditions. Three-leg interchanges should only be considered when future
expansion to the unused quadrant is either impossible or highly unlikely. This is due
in part to the fact that three-leg interchanges are very difficult to expand or modify in
the future.

Three-Leg Interchages With Single Structures

CVE 06 HRE 11 122
JCSaliendra
 Three-Leg Interchages With Multiple Structures

Three-Leg Interchange (T-Type Or Trumpet)

CVE 06 HRE 11 123
JCSaliendra
 Three-Leg Interchange Semidirectional Design

Directional Three-Leg Interchange Of a River Crossing

Trumpet Freeway-To-Freeway Interchange

CVE 06 HRE 11 124
JCSaliendra
Four-Leg Designs

Interchanges with four intersection legs may be grouped under five general
configurations: (1) ramps in one quadrant, (2) diamond interchanges, (3) single-
point urban interchanges (SPUIs), (4) full or partial cloverleafs (including ramps in
two or three quadrants), and (5) interchanges with direct and semidirect
connections.

1. Ramps in One Quadrant
Interchanges with ramps in only one quadrant have application for an intersection of
roadways with low traffic volumes.

Four-Leg Interchanges, Ramps In One Quadrant

CVE 06 HRE 11 125
JCSaliendra
2. Diamond Interchanges
The simplest and perhaps most common interchange configuration is the diamond.
A full diamond interchange is formed when a one-way diagonal ramp is provided in
each quadrant. The ramps are aligned with free-flow terminals on the major
highway, and the left turns at grade are confined to the crossroad. The diamond
interchange has several advantages over a comparable partial cloverleaf: all traffic
can enter and leave the major road at relatively high speeds, leftturning maneuvers
entail little extra travel, and a relatively narrow band of right-of-way is needed,
sometimes no more than that needed for the highway alone.

Diamond Interchanges, Conventional Arrangements

CVE 06 HRE 11 126
JCSaliendra
 Diamond Interchange Arrangements To Reduce Traffic Conflicts

Freeway With A Three-Level Diamond Interchange

CVE 06 HRE 11 127
JCSaliendra
 Diamond Interchanges With Additional Structures

Existing Four-Leg Interchange With Diamond Stage Construction
CVE 06 HRE 11 128
JCSaliendra
3. Single-Point Urban Interchanges

The single-point urban interchange (SPUI) is a relatively recent development in
interchange design with the first SPUIs being constructed in the early 1970s. The
SPUI is also known as an urban interchange or a single-point diamond interchange.
The primary features of a SPUI are that all four turning moves are controlled by a
single traffic signal and opposing left turns operate to the left of each other.

Underpass Single Point Urban Interchange

An SPUI Underpass in Restricted Right-of-Way
CVE 06 HRE 11 129
JCSaliendra
 Overpass Layout With a Frontage Road And a Separate u-Turn Movement

CVE 06 HRE 11 130
JCSaliendra
 Underpass SPUI

Overpass SPUI

4. Cloverleafs
Cloverleafs are four-leg interchanges that employ loop ramps to accommodate left-
turning movements. Interchanges with loops in all four quadrants are referred to as
“full cloverleafs” and all others are referred to as “partial cloverleafs.”

Four-Leg Interchange, Full Cloverleaf With Collector-Distributor Rods

CVE 06 HRE 11 131
JCSaliendra
 Cloverleaf Interchange With Collector-Distributor Roads

Schematic Of Partial Cloverleaf Ramp Arrangements, Exit And Entrance Turns

Four-Leg Interchange (Partial Or Two-Quadrant Cloverleaf With Ramps Before Main
Structure)

CVE 06 HRE 11 132
JCSaliendra
 Four-Leg Interchange (Partial Or Two-Quadrant Cloverleaf With Ramps Beyond Main
Structure)

5. Directional and Semidirectional Interchanges

Direct or semidirect connections are used for important turning movements to reduce
travel distance, increase speed and capacity, eliminate weaving, and avoid the need for
out-of-direction travel in driving on a loop. Higher levels of service can be realized on
direct connections and, in some instances, on semidirect ramps because of relatively
high speeds and the likelihood of better terminal design. Often a direct connection is
designed with two lanes. In such cases, the ramp capacity may approach the capacity
of an equivalent number of lanes on the through highway.

Semidirect Interchange With Weaving

CVE 06 HRE 11 133
JCSaliendra
 Semi Direct Interchange With No Weaving

Semidirectional And Directional Interchange - Multilevel Structures
CVE 06 HRE 11 134
JCSaliendra
 Directional Interchange, Two Semidirect Connections

Four-Level Directional Interchange

Four-Level Directional Interchange
CVE 06 HRE 11 135
JCSaliendra
 Semidirectional Interchange With Loops

OTHER INTERCHANGE CONFIGURATION

Offset Interchange Via Ramp Highway

Four-Leg Interchange, Diamond With A Semidirect Connection
CVE 06 HRE 11 136
JCSaliendra
 Four-Leg Interchange, Cloverleaf With A Semidirect Connection

Complex Interchange Arrangement

Freeway With A Three-Level Cloverleaf Interchange

Reference:
American Association Of State Highway And Transportation Officials (AASHTO), A
Policy Of Geometric Design Of Highways And Streets
CVE 06 HRE 11 137
JCSaliendra