1. Design of Concrete Structure II
Sessional
(CE-3103)
A Presentation
on
Reinforced Slab Bridge Design(ASD)
Prepared by-
Shekh Muhsen Uddin Ahmed
3 ๐๐ ๐๐๐๐ 1 ๐ ๐ก ๐๐๐๐๐ ๐ก๐๐
Department of Civil Engineering
Submitted to-
Md. Rezaul Karim, Ph.D.
Associate Professor
&
Sukanta Kumar Shill
Assistant Professor
Dhaka University of Engineering & Technology
2. Contents
Introduction to Bridge Structures
Types of Reinforced Concrete Bridge
Loads that Concerned with Slab Bridges
Components of Slab Bridge
Design Steps for Slab and Edge Beam
3. A Short Introduction to Bridge Structures
The first Bridges were made by nature as simple log fallen across a
stream. The first bridge made by humans were probably spans of
wooden log on planks and eventually stones, using simple support
and cross beam arrangement.
Most of these early bridges could not carry heavy weights on
withstand strong current. It was these inadequacies which led to the
development of better bridges.
4. Types of Reinforced Concrete Bridge
Reinforced Slab Bridges
Beam and Slab Bridges
For short spans, a solid reinforced concrete
slab, generally cast in-situ rather than precast,
is the simplest designUp to about 25m span,
such voided slabs are more economical than
prestressed slabs.
Beam and slab bridges are the most common form
of concrete bridge in today. They have the virtue of
simplicity, economy, wide availability of the
standard sections, and speed of erection.
The precast beams are placed on the supporting
piers or abutments, usually on rubber bearings
which are maintenance free.
5. Types of Reinforced Concrete Bridge
Arch Bridges
Cable-Stayed Bridges
Arch bridges derive their strength from
the fact that vertical loads on the arch
generate compressive forces in the arch
ring, which is constructed of materials
well able to withstand these forces.
For really large spans, one solution is
the cable-stayed bridge. As typified by
the Dee Crossing where all elements
are concrete, the design consists of
supporting towers carrying cables
which support the bridge from both
sides of the tower.
6. Box Girder Bridges
Types of Reinforced Concrete Bridge
For spans greater than around 45 metres, prestressed concrete box girders are the most common method
of concrete bridge construction.
Incrementally launched
The incrementally launched technique
creates the bridge section by section,
pushing the structure outwards from
the abutment towards the pier. The
practical limit on span for the technique
is around 75m.
Span-by-span
The span-by-span method is used for
multi-span viaducts, where the
individual span can be up to 60m.
These bridges are usually
constructed in-situ
Balanced cantilever
In the early 1950's, the German
engineer Ulrich Finsterwalder developed
a way of erecting prestressed concrete
cantilevers segment by segment with
each additional unit being prestressed to
those already in position.
7. Integral Bridges
Types of Reinforced Concrete Bridge
One of the difficulties in designing any structure is deciding where
to put the joints. These are necessary to allow movement as the
structure expands under the heat of the summer sun and contracts
during the cold of winter.
Expansion joints in bridges are notoriously prone to leakage. Water
laden with road salts can then reach the tops of the piers and the
abutments, and this can result in corrosion of all reinforcement.
The expansive effects of rust can split concrete apart.
They are constructed with their decks connected directly to the
supporting piers and abutments and with no provision in the form
of bearings or expansion joints for thermal movement.
8. Suspension Bridges
Types of Reinforced Concrete Bridge
Concrete plays an important part in the
construction of a suspension bridge. There
will be massive foundations, usually
embedded in the ground, that support the
weight and cable anchorages. There will
also be the abutments, again probably in
mass concrete, providing the vital strength
and ability to resist the enormous forces,
and in addition, the slender
superstructures carrying the upper ends of
the supporting cables are also generally
made from reinforced concrete.
9. Live Loads
Loads that Concerned with Slab Bridges
Truck Loading
Other roadway
Loading
AASHTO specify two types of truck loadings(HS and H).
Highways which may carry heavy truck traffic the minimum live load
shall be HS15-44
Bridge may be required to carry electric railways, railroad freight cars,
military vehicles, or other extra ordinary vehicles.
Sidewalk
Loading
Sidewalk floors, stringers, and their immediate Supports are usually
designed for a live of at least 85 psf of sidewalk area.
11. Impact Load
Loads that Concerned with Slab Bridges
Live load stresses due to truck loading are increased by vibration and
sudden application of the load.
Impact Load= Live Load * Impact Fraction
Where Impact Fraction, I=
50
๐+125
โค 0.30
Here l = loaded length
12. Components of Slab Bridge
Sub-Structure Footing Distributes super structures load on soil.
Abutment
Acts as a load bearing wall which transfer supper structure
load on footing.
Super
Structure
Slab
Support all kinds of live load and dead load and transfer them
on Abutment
Edge Beam Prevent cracking of slab edge and support stringer load
Slab
Bridge
14. Design Steps for Slab and Edge Beam
a) Slab Design
Span Length
Span Length , S= Centre to Centre Distance of the Supports
โค (Clear Distance between support+ Slab Thickness)
Bending
Moment i). Dead Load Moments(DDM)=
๐ท ๐๐ ๐ก๐๐๐๐ข๐ก๐๐ ๐ท๐๐๐ ๐ฟ๐๐๐ ๐๐๐ ๐ข๐๐๐ก ๐ฟ๐๐๐๐กโ โ(๐ ๐๐๐ ๐ฟ๐๐๐๐กโ)2
8
โฆ โฆ โฆ . (1)
15. ii). Live Load Moments(LLM)
(For main reinforcement parallel to the traffic)
When HS20 Loadings:
Spans up to and including 50ft ,LLM= 900S ft-lb โฆ โฆ โฆ โฆ โฆ . (2)
Spans 50ft to 100ft, LLM= 1000(1.30S-20.0)ft-lb โฆ โฆ โฆ โฆ โฆ . (3)
When HS15 Loadings:
LLM =
3
4
โ (๐ป๐20 ๐ฟ๐๐๐๐๐๐ ๐๐๐๐๐๐ก๐ )
iii). Impact Load Moments(ILM)
ILM= (Live load Moments * Impact Fraction) ft-lb โฆ โฆ โฆ โฆ โฆ . (5)
Design Steps for Slab and Edge Beam
a) Slab Design
16. Design Steps for Slab and Edge Beam
a) Slab Design
๐ ๐๐๐ก๐๐ = ๐ท๐ฟ๐ + ๐ฟ๐ฟ๐ + ๐ผ๐๐ โฆ โฆ โฆ โฆ โฆ . (6)
Effective
Depth, d
Minimum Permissible Effective depth of slab,
๐ = โ(
2๐ ๐๐๐ก๐๐
๐๐ ๐๐
) โฆ โฆ โฆ โฆ โฆ . (7)
Area of Main
Reinforcement,
๐ด ๐
Area of Main Reinforcement,
๐ด ๐ =
๐ ๐๐๐ก๐๐
๐๐ ๐๐
โฆ โฆ โฆ โฆ โฆ โฆ . (8)
17. Design Step for Slab and Edge Beam
a) Slab Design
Area of
Distributed
Reinforcement,
๐ด ๐ โฒ
Area of Distributed Reinforcement,
๐ด ๐ โฒ= ๐ด ๐ โ ๐ ๐๐๐๐๐๐๐๐๐๐๐๐ก ๐ท๐๐ ๐ก๐๐๐๐ข๐ก๐๐๐ ๐น๐๐๐ก๐๐ โฆ โฆ โฆ . (9)
Where
๐ ๐๐๐๐๐๐๐๐๐๐๐๐ก ๐ท๐๐ ๐ก๐๐๐๐ข๐ก๐๐๐ ๐น๐๐๐ก๐๐ =
2.2
โ๐
โค 0.67
18. Design Steps for Slab and Edge Beam
b) Edge Beam Design
Bending
Moment
i). Dead Load Moments(DDM)=
๐ท ๐๐ ๐ก๐๐๐๐ข๐ก๐๐ ๐ท๐๐๐ ๐ฟ๐๐๐ ๐๐๐ ๐ข๐๐๐ก ๐ฟ๐๐๐๐กโ โ(๐ ๐๐๐ ๐ฟ๐๐๐๐กโ)2
8
๐๐ก โ ๐๐ โฆ โฆ โฆ . (10)
ii). Specified Live Load Moments(LLM)
=0.10* ๐20 โ ๐ ๐๐ก โ ๐๐ โฆ โฆ โฆ . (11)
(Here we will be only consider Self weight and Stringer Weight)
๐ ๐๐๐ก๐๐ = ๐ธ๐๐ 10 + ๐ธ๐๐(11) โฆ โฆ โฆ โฆ . (12)
19. Design Step for Slab and Edge Beam
b) Edge Beam Design
Area of Tensile
Reinforcement,
๐ด ๐
Area of Tensile Reinforcement,
๐ด ๐ =
๐ ๐๐๐ก๐๐
๐๐ ๐๐
โฆ โฆ โฆ โฆ โฆ โฆ . (13)