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1.2 Advantages and Types of Prestressing
This section covers the following topics.
Definitions
Advantages of Prestressing
Limitations of Prestressing
Types of Prestressing
1.2.1 Definitions
The terms commonly used in prestressed concrete are explained. The terms are placed
in groups as per usage.
Forms of Prestressing Steel
Wires
Prestressing wire is a single unit made of steel.
Strands
Two, three or seven wires are wound to form a prestressing strand.
Tendon
A group of strands or wires are wound to form a prestressing tendon.
Cable
A group of tendons form a prestressing cable.
Bars
A tendon can be made up of a single steel bar. The diameter of a bar is much
larger than that of a wire.
The different types of prestressing steel are further explained in Section 1.7,
Prestressing Steel.
Nature of Concr ete-Steel Interface
Bonded tendon
When there is adequate bond between the prestressing tendon and concrete, it is called
a bonded tendon. Pre-tensioned and grouted post-tensioned tendons are bonded
tendons.
Unbonded tendon
When there is no bond between the prestressing tendon and concrete, it is called
unbonded tendon. When grout is not applied after post-tensioning, the tendon is an
unbonded tendon.
Stages of Loading
The analysis of prestressed members can be different for the different stages of loading.
The stages of loading are as follows.
1) Initial : It can be subdivided into two stages.a) During tensioning of steel
b) At transfer of prestress to concrete.
2) Intermediate : This includes the loads during transportation of the
prestressed members.
3) Final : It can be subdivided into two stages.
a) At service, during operation.
b) At ultimate, during extreme events.
1.2.2 Advantages of Prestressing
The prestressing of concrete has several advantages as compared to traditional
reinforced concrete (RC) without prestressing. A fully prestressed concrete member is
usually subjected to compression during service life. This rectifies several deficiencies
of concrete.
The following text broadly mentions the advantages of a prestressed concrete member
with an equivalent RC member. For each effect, the benefits are listed.
1) Section remains uncracked under service loads
Reduction of steel corrosion
Increase in durability.
Full section is utilised Higher moment of inertia (higher stiffness)
Less deformations (improved serviceability).
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Increase in shear capacity.
Suitable for use in pressure vessels, liquid retaining structures.
Improved performance (resilience) under dynamic and fatigue loading.
2) High span-to-depth ratios
Larger spans possible with prestressing (bridges, buildings with large column-free
spaces)
Typical values of span-to-depth ratios in slabs are given below.
Non-prestressed slab 28:1
Prestressed slab 45:1
For the same span, less depth compared to RC member.
Reduction in self weight
More aesthetic appeal due to slender sections
More economical sections.
3) Suitable for precast constr uction
The advantages of precast construction are as follows. Rapid construction
Better quality control
Reduced maintenance
Suitable for repetitive construction
Multiple use of formwork
Reduction of formwork
Availability of standard shapes.
The following figure shows the common types of precast sections.
Double T-sectionT-section
Hollow core Piles
Double T-sectionDouble T-sectionT-sectionT-section
Hollow core Piles
L-section Inverted T-section I-girdersL-section Inverted T-section
I-girders
Figure 1-2.1 Typical precast members
1.2.3 Limitations of Prestressing
Although prestressing has advantages, some aspects need to be carefully addressed.
Prestressing needs skilled technology. Hence, it is not as common as reinforced
concrete.
The use of high strength materials is costly.
There is additional cost in auxiliary equipments.
There is need for quality control and inspection.
1.2.4 Types of Prestressing
Prestressing of concrete can be classified in several ways. The following classifications
are discussed.
Source of prestressing force
This classification is based on the method by which the prestressing force is generated.
There are four sources of prestressing force: Mechanical, hydraulic, electrical and
chemical.
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External or internal prestressing
This classification is based on the location of the prestressing tendon with respect to the
concrete section.
Pre-tensioning or post-tensioning
This is the most important classification and is based on the sequence of casting the
concrete and applying tension to the tendons.
Linear or circular prestressing
This classification is based on the shape of the member prestressed.
Full, limited or partial prestressing
Based on the amount of prestressing force, three types of prestressing are defined.
Uniaxial, biaxial or multi-axial prestressing
As the names suggest, the classification is based on the directions of prestressing a
member.
The individual types of prestressing are explained next.
Source of Prestressing Force
Hydraulic Prestressing
This is the simplest type of prestressing, producing large prestressing forces. The
hydraulic jack used for the tensioning of tendons, comprises of calibrated pressure
gauges which directly indicate the magnitude of force developed during the tensioning.
Mechanical Prestressing
In this type of prestressing, the devices includes weights with or without lever
transmission, geared transmission in conjunction with pulley blocks, screw jacks with or
without gear drives and wire-winding machines. This type of prestressing is adopted for
mass scale production.
Electrical Prestressing
In this type of prestressing, the steel wires are electrically heated and anchored before
placing concrete in the moulds. This type of prestressing is also known as thermo-
electric prestressing.
External or Internal Prestressing
External Prestressing
When the prestressing is achieved by elements located outside the concrete, it is called
external prestressing. The tendons can lie outside the member (for example in I-girders
or walls) or inside the hollow space of a box girder. This technique is adopted inbridges and strengthening of buildings. In the following figure, the box girder of a bridge
is prestressed with tendons that lie outside the concrete.
Figure 1-2.2 External prestressing of a box girder
(Reference: VSL International Ltd.)
Internal Prestressing
When the prestressing is achieved by elements located inside the concrete member
(commonly, by embedded tendons), it is called internal prestressing. Most of the
applications of prestressing are internal prestressing. In the following figure, concrete
will be cast around the ducts for placing the tendons.
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Figure 1-2.3 Internal prestressing of a box girder
(Courtesy: Cochin Port Trust, Kerala)
Pre-tensioning or Post-tensioning
Pre-tensioning
The tension is applied to the tendons before casting of the concrete. The pre-
compression is transmitted from steel to concrete through bond over the transmission
length near the ends. The following figure shows manufactured pre-tensioned electric
poles.
Figure 1-2.4 Pre-tensioned electric poles
(Courtesy: The Concrete Products and Construction Company, COPCO, Chennai)
Post-tensioning
The tension is applied to the tendons (located in a duct) after hardening of the concrete.
The pre-compression is transmitted from steel to concrete by the anchorage device (at
the end blocks). The following figure shows a post-tensioned box girder of a bridge.
Figure 1-2.5 Post-tensioning of a box girder
(Courtesy: Cochin Port Trust, Kerala)
The details of pre-tensioning and post-tensioning are covered under Section 1.3, Pre-
tensioning Systems and Devices, and Section 1.4, Post-tensioning Systems and
Devices, respectively.
Linear o r Circular Prestressing
Linear PrestressingWhen the prestressed members are straight or flat, in the direction of prestressing, the
prestressing is called linear prestressing. For example, prestressing of beams, piles,
poles and slabs. The profile of the prestressing tendon may be curved. The following
figure shows linearly prestressed railway sleepers.
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Figure 1-2.6 Linearly prestressed railway sleepers
(Courtesy: The Concrete Products and Construction Company, COPCO, Chennai)
Circular Prestressing
When the prestressed members are curved, in the direction of prestressing, the
prestressing is called circular prestressing. For example, circumferential prestressing of
tanks, silos, pipes and similar structures. The following figure shows the containment
structure for a nuclear reactor which is circularly prestressed.
Figure 1-2.7 Circularly prestressed containment structure, Kaiga Atomic Power
Station, Karnataka
(Reference: Larsen & Toubro Ltd, ECC Division, 60 Landmark Years)
Full, Limited or Partial Prestressing
Full Prestressing
When the level of prestressing is such that no tensile stress is allowed in concrete under
service loads, it is called Full Prestressing (Type 1, as per IS:1343 - 1980).
Limited Prestressing
When the level of prestressing is such that the tensile stress under service loads is
within the cracking stress of concrete, it is called Limited Prestressing (Type 2).
Partial PrestressingWhen the level of prestressing is such that under tensile stresses due to service loads,
the crack width is within the allowable limit, it is called Partial Prestressing (Type 3).
Uniaxial, Biaxial or Multiaxial Prestressing
Uniaxial Prestressing
When the prestressing tendons are parallel to one axis, it is called Uniaxial Prestressing.
For example, longitudinal prestressing of beams.
Biaxial Prestressing
When there are prestressing tendons parallel to two axes, it is called Biaxial
Prestressing. The following figure shows the biaxial prestressing of slabs.
Duct for
prestressingtendon
Non-prestressed reinforcement
Duct for
prestressingtendon
Non-prestressed reinforcement
Figure 1-2.8 Biaxial prestressing of a slab
(Courtesy: VSL India Pvt. Ltd., Chennai)
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Multiaxial Prestressing
When the prestressing tendons are parallel to more than two axes, it is called Multiaxial
Prestressing. For example, prestressing of domes.
1.3 Pre-tensioning Systems and Devices
This section covers the following topics.
Introduction
Stages of Pre-tensioning
Advantages of Pre-tensioning
Disadvantages of Pre-tensioning
Devices
Manufacturing of Pre-tensioned Railway Sleepers
1.3.1 Introduction
Prestressing systems have developed over the years and various companies have
patented their products. Detailed information of the systems is given in the product
catalogues and brochures published by companies. There are general guidelines of
prestressing in Section 12 ofIS:1343 - 1980. The information given in this section is
introductory in nature, with emphasis on the basic concepts of the systems.
The prestressing systems and devices are described for the two types of prestressing,
pre-tensioning and post-tensioning, separately. This section covers pre-tensioning.
Section 1.4, Post-tensioning Systems and Devices, covers post-tensioning. In pre-
tensioning, the tension is applied to the tendons before casting of the concrete. The
stages of pre-tensioning are described next.
1.3.2 Stages of Pre-tensioning
In pre-tensioning system, the high-strength steel tendons are pulled between two end
abutments (also called bulkheads) prior to the casting of concrete. The abutments are
fixed at the ends of a prestressing bed.
Once the concrete attains the desired strength for prestressing, the tendons are cut
loose from the abutments.
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The prestress is transferred to the concrete from the tendons, due to the bond between
them. During the transfer of prestress, the member undergoes elastic shortening. If the
tendons are located eccentrically, the member is likely to bend and deflect (camber).
The various stages of the pre-tensioning operation are summarised as follows.
1) Anchoring of tendons against the end abutments
2) Placing of jacks
3) Applying tension to the tendons
4) Casting of concrete
5) Cutting of the tendons.
During the cutting of the tendons, the prestress is transferred to the concrete with elastic
shortening and camber of the member.
The stages are shown schematically in the following figures.
Prestressing bed
Steel tendon
Endabutment
Jack
Prestressing bed
Steel tendon
Endabutment
Jack
(a) Applying tension to tendons
(b) Casting of concrete
Cutting of tendonCutting of tendon
(c) Transferring of prestress
Figure1-3.1 Stages of pre-tensioning
1.3.3 Advantages of Pre-tensioning
The relative advantages of pre-tensioning as compared to post-tensioning are as
follows.
Pre-tensioning is suitable for precast members produced in bulk.
In pre-tensioning large anchorage device is not present.
1.3.4Disadvantages of Pre-tensioning
The relative disadvantages are as follows.
A prestressing bed is required for the pre-tensioning operation.
There is a waiting period in the prestressing bed, before the concrete attains
sufficient strength.
There should be good bond between concrete and steel over the transmission
length.
1.3.5 Devices
The essential devices for pre-tensioning are as follows.
Prestressing bed
End abutments
Shuttering / mould J ack
Anchoring device
Harping device (optional)
Prestressing Bed, End Abutments and Mould
The following figure shows the devices.
Prestressing bed
Mould
Endabutment
Jack
Anchoringdevice
Prestressing bed
Mould
Endabutment
Jack
Anchoringdevice
Prestressing bed
Mould
Endabutment
Jack
Anchoringdevice
Figure1-3.2 Prestressing bed, end abutment and mould
An extension of the previous system is the Hoyer system. This system is generally
used for mass production. The end abutments are kept sufficient distance apart, and
several members are cast in a single line. The shuttering is provided at the sides and
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between the members. This system is also called the Long Line Method. The
following figure is a schematic representation of the Hoyer system
Prestressing bed
A series of moulds
Prestressing bed
A series of moulds
Figure 1-3.3 Schematic representation of Hoyer system
The end abutments have to be sufficiently stiff and have good foundations. This is
usually an expensive proposition, particularly when large prestressing forces arerequired. The necessity of stiff and strong foundation can be bypassed by a simpler
solution which can also be a cheaper option. It is possible to avoid transmitting the
heavy loads to foundations, by adopting self-equilibrating systems. This is a common
solution in load-testing. Typically, this is done by means of a tension frame. The
following figure shows the basic components of a tension frame. The jack and the
specimen tend to push the end members. But the end members are kept in place by
members under tension such as high strength steel rods.
P
Free bodiesPlan or Elevation
TestspecimenHigh
strengthsteel rods
Loading
jack
P
Free bodies
P
Free bodiesPlan or Elevation
TestspecimenHigh
strengthsteel rods
Loading
jack
Plan or Elevation
TestspecimenHigh
strengthsteel rods
Loading
jack
Figure 1-3.4 A tension frame
The frame that is generally adopted in a pre-tensioning system is called a stress bench.
The concrete mould is placed within the frame and the tendons are stretched and
anchored on the booms of the frame. The following figures show the components of a
stress bench.
Jack
Threaded rodElevation
Plan
Mould Strands
Jack
Threaded rodElevation
Jack
Threaded rodElevation
Plan
Mould Strands
Plan
Mould Strands
Figure 1-3.5 Stress bench Self straining frame
The following figure shows the free body diagram by replacing the jacks with the applied
forces.
Plan
Load by jack
Tension instrands
Plan
Load by jack
Tension instrands
Figure 1-3.6 Free body diagram of stress bench
The following figure shows the stress bench after casting of the concrete.
Elevation
Plan
Elevation
Plan
Figure 1-3.7 The stress bench after casting concrete
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Jacks
The jacks are used to apply tension to the tendons. Hydraulic jacks are commonly used.
These jacks work on oil pressure generated by a pump. The principle behind the design
of jacks is Pascals law. The load applied by a jack is measured by the pressure
reading from a gauge attached to the oil inflow or by a separate load cell. The following
figure shows a double acting hydraulic jack with a load cell.
Figure 1-3.8 A double acting hydraulic jack with a load cell
Anchoring Dev ices
Anchoring devices are often made on the wedge and friction principle. In pre-tensioned
members, the tendons are to be held in tension during the casting and hardening of
concrete. Here simple and cheap quick-release grips are generally adopted. The
following figure provides some examples of anchoring devices.
Figure 1-3.9 Chuck assembly for anchoring tendons
(Reference: Lin, T. Y. and Burns, N. H.,
Design of Prestressed Concrete Structures)
Harping Devices
The tendons are frequently bent, except in cases of slabs-on-grade, poles, piles etc.
The tendons are bent (harped) in between the supports with a shallow sag as shown
below.
Harping point Hold up device
a) Before casting of concrete
Harping point Hold up device
a) Before casting of concretea) Before casting of concrete
b) After casting of concreteb) After casting of concrete
Figure 1-3.10 Harping of tendons
The tendons are harped using special hold-down devices as shown in the following
figure.
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Figure 1-3.11 Hold-down anchor for harping of tendons
(Reference: Nawy, E. G., Prestressed Concrete: A Fundamental Approach)
1.3.6 Manufacturing of Pre-tensioned Railway Sleepers
The following photos show the sequence of manufacturing of pre-tensioned railway
sleepers (Courtesy: The Concrete Products and Construction Company, COPCO,
Chennai). The steel strands are stretched in a stress bench that can be moved on
rollers. The stress bench can hold four moulds in a line. The anchoring device holds
the strands at one end of the stress bench. In the other end, two hydraulic jacks push a
plate where the strands are anchored. The movement of the rams of the jacks and the
oil pressure are monitored by a scale and gauges, respectively. Note that after the
extension of the rams, the gap between the end plate and the adjacent mould has
increased. This shows the stretching of the strands.
Meanwhile the coarse and fine aggregates are batched, mixed with cement, water and
additives in a concrete mixer. The stress bench is moved beneath the concrete mixer.
The concrete is poured through a hopper and the moulds are vibrated. After the
finishing of the surface, the stress bench is placed in a steam curing chamber for a few
hours till the concrete attains a minimum strength.
The stress bench is taken out from the chamber and the strands are cut. The sleepers
are removed from the moulds and stacked for curing in water. After the complete curing,
the sleepers are ready for dispatching.
(a) Travelling pre-tensioning stress bench
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Wedge andcylinderassembly atthe dead end
Wedge andcylinderassembly atthe dead end
(b) Anchoring of strands
Hydraulic jack atstretching end
Initial gap
Endplate
Hydraulic jack atstretching end
Initial gap
Endplate
(c) Stretching of strands
Extension of ram
Final gap
Threadedrod
Extension of ram
Final gap
Threadedrod
(d) Stretching of strands
Coarse aggregate
Fine aggregate
Coarse aggregate
Fine aggregate
(e) Material storage
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Automatedbatchingby weight
Automatedbatchingby weight
(f) Batching of materials
Hopper belowconcrete mixerHopper belowconcrete mixer
(g) Pouring of concrete
(h) Concrete after vibration of mould
(i) Steam curing chamber
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(j) Cutting of strands
(k) Demoulding of sleeper
(l) Stacking of sleeper
(m) Water curing
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(n) Storage and dispatching of sleepers
Figure 1-3.12 Manufacturing of pre-tensioned railway sleepers
1.4 Post-tensioning Systems and Devices
This section covers the following topics
Introduction
Stages of Post-tensioning
Advantages of Post-tensioning
Disadvantages of Post-tensioning
Devices
Manufacturing of a Post-tensioned Bridge Girder
1.4.1 Introduction
Prestressing systems have developed over the years and various companies have
patented their products. Detailed information of the systems is given in the product
catalogues and brochures published by companies. There are general guidelines of
prestressing in Section 12 ofIS 1343: 1980. The information given in this section is
introductory in nature, with emphasis on the basic concepts of the systems.
The prestressing systems and devices are described for the two types of prestressing,
pre-tensioning and post-tensioning, separately. This section covers post-tensioning.
Section 1.3, Pre-tensioning Systems and Devices, covers pre-tensioning. In post-
tensioning, the tension is applied to the tendons after hardening of the concrete. The
stages of post-tensioning are described next.
1.4.2 Stages of Post-tensioning
In post-tensioning systems, the ducts for the tendons (or strands) are placed along with
the reinforcement before the casting of concrete. The tendons are placed in the ducts
after the casting of concrete. The duct prevents contact between concrete and the
tendons during the tensioning operation.
Unlike pre-tensioning, the tendons are pulled with the reaction acting against the
hardened concrete.
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If the ducts are filled with grout, then it is known as bonded post-tensioning. The grout
is a neat cement paste or a sand-cement mortar containing suitable admixture. The
grouting operation is discussed later in the section. The properties of grout are
discussed in Section 1.6, Concrete (Part-II).
In unbonded post-tensioning, as the name suggests, the ducts are never grouted and
the tendon is held in tension solely by the end anchorages. The following sketch shows
a schematic representation of a grouted post-tensioned member. The profile of the duct
depends on the support conditions. For a simply supported member, the duct has a
sagging profile between the ends. For a continuous member, the duct sags in the span
and hogs over the support.
Figure 1-4.1 Post-tensioning (Reference: VSL International Ltd.)
Among the following figures, the first photograph shows the placement of ducts in a box
girder of a simply supported bridge. The second photograph shows the end of the box
girder after the post-tensioning of some tendons.
Figure 1-4.2 Post-tensioning ducts in a box girder
(Courtesy: Cochin Port Trust, Kerala)
Figure 1-4.3 Post-tensioning of a box girder
(Courtesy: Cochin Port Trust, Kerala)
The various stages of the post-tensioning operation are summarised as follows.
1) Casting of concrete.
2) Placement of the tendons.
3) Placement of the anchorage block and jack.
4) Applying tension to the tendons.
5) Seating of the wedges.
6) Cutting of the tendons.
The stages are shown schematically in the following figures. After anchoring a tendon
at one end, the tension is applied at the other end by a jack. The tensioning of tendons
and pre-compression of concrete occur simultaneously. A system of self-equilibratingforces develops after the stretching of the tendons.
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Casting bed
Duct
Side viewCasting bed
Duct
Side view
(a) Casting of concrete
JackJack
(b) Tensioning of tendons
AnchorAnchor
(c)Anchoring the tendon at the stretching end
Figure 1-4.4 Stages of post-tensioning (shown in elevation)
1.4.3 Advantages of Post-tensioning
The relative advantages of post-tensioning as compared to pre-tensioning are as
follows.
Post-tensioning is suitable for heavy cast-in-place members.
The waiting period in the casting bed is less.
The transfer of prestress is independent of transmission length.
1.4.4 Disadvantage of Post-tensioning
The relative disadvantage of post-tensioning as compared to pre-tensioning is the
requirement of anchorage device and grouting equipment.
1.4.5 Devices
The essential devices for post-tensioning are as follows.
1) Casting bed
2) Mould/Shuttering
3) Ducts
4) Anchoring devices
5) Jacks
6) Couplers (optional)
7) Grouting equipment (optional).
Casting Bed, Mould and Ducts
The following figure shows the devices.
Casting bed
Mould
Duct
Casting bed
Mould
Duct
Figure 1-4.5 Casting bed, mould and duct
Anchor ing Devices
In post-tensioned members the anchoring devices transfer the prestress to the concrete.
The devices are based on the following principles of anchoring the tendons.
1) Wedge action
2) Direct bearing
3) Looping the wires
Wedge action
The anchoring device based on wedge action consists of an anchorage block and
wedges. The strands are held by frictional grip of the wedges in the anchorage block.
Some examples of systems based on the wedge-action are Freyssinet, Gifford-Udall,
Anderson and Magnel-Blaton anchorages. The following figures show some patented
anchoring devices.
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Figure 1-4.6 Freyssinet T system anchorage cones
(Reference: Lin, T. Y. and Burns, N. H., Design of Prestressed Concrete Structures)
Figure 1-4.7 Anchoring devices
(Reference: Collins, M. P. and Mitchell, D., Prestressed Concrete Structures)
Figure 1-4.8 Anchoring devices (Reference: VSL International Ltd)
Direct bearing
The rivet or bolt heads or button heads formed at the end of the wires directly bear
against a block. The B.B.R.V post-tensioning system and the Prescon system arebased on this principle. The following figure shows the anchoring by direct bearing.
Figure 1-4.9 Anchoring with button heads
(Reference: Collins, M. P. and Mitchell, D., Prestressed Concrete Structures)
Looping the wires
The Baur-Leonhardt system, Leoba system and also the Dwidag single-bar anchorage
system, work on this principle where the wires are looped around the concrete. Thewires are looped to make a bulb. The following photo shows the anchorage by looping
of the wires in a post-tensioned slab.
Figure 1-4.10 Anchorage by looping the wires in a slab
(Courtesy : VSL India Pvt. Ltd.)
The anchoring devices are tested to calculate their strength. The following photo shows
the testing of an anchorage block.
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Figure 1-4.11 Testing of an anchorage device
Sequence of Anchoring
The following figures show the sequence of stressing and anchoring the strands. The
photo of an anchoring device is also provided.
Figure 1-4.12 Sequence of anchoring
(Reference: VSL International Ltd.)
Figure 1-4.13 Final form of an anchoring device
(Reference: VSL International Ltd)
JacksThe working of a jack and measuring the load were discussed in Section 1.3, Pre-
tensioning Systems and Devices. The following figure shows an extruded sketch of the
anchoring devices.
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Figure 1-4.14 J acking and anchoring with wedges
(Reference: Collins, M. P. and Mitchell, D., Prestressed Concrete Structures)
Couplers
The couplers are used to connect strands or bars. They are located at the junction of
the members, for example at or near columns in post-tensioned slabs, on piers in post-
tensioned bridge decks.
The couplers are tested to transmit the full capacity of the strands or bars. A few types
of couplers are shown.
Figure 1-4.15 Coupler for strands
(Reference: VSL International Ltd)
Figure 1-4.16 Couplers for strands
(Reference: Dywidag Systems International)
Figure 1-4.17 Couplers for strands
(Reference: Dywidag Systems International)
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GroutingGrouting can be defined as the filling of duct, with a material that provides an anti-
corrosive alkaline environment to the prestressing steel and also a strong bond betweenthe tendon and the surrounding grout.
The major part of grout comprises of water and cement, with a water-to-cement ratio of
about 0.5, together with some water-reducing admixtures, expansion agent and
pozzolans. The properties of grout are discussed in Section 1.6, Concrete (Part-II).
The following figure shows a grouting equipment, where the ingredients are mixed and
the grout is pumped.
Figure 1-4.18 Grouting equipment
(Reference: Williams Form Engineering Corp.)
1.4.6 Manufacturing of Post-tensioned Br idge Girders
The following photographs show some steps in the manufacturing of a post-tensioned I-
girder for a bridge (Courtesy: Larsen & Toubro). The first photo shows the fabricated
steel reinforcement with the ducts for the tendons placed inside. Note the parabolic
profiles of the duct for the simply supported girder. After the concrete is cast and cured
to gain sufficient strength, the tendons are passed through the ducts, as shown in the
second photo. The tendons are anchored at one end and stretched at the other end by
a hydraulic jack. This can be observed from the third photo.
(a) Fabrication of reinforcement
(b) Placement of tendons
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(c) Stretching and anchoring of tendons
Figure 1-4.19 Manufacturing of a post-tensioned bridge I-girder
The following photos show the construction of post-tensioned box girders for a bridge
(Courtesy: Cochin Port Trust). The first photo shows the fabricated steel reinforcement
with the ducts for the tendons placed inside. The top flange will be constructed later.
The second photo shows the formwork in the pre-casting yard. The formwork for theinner sides of the webs and the flanges is yet to be placed. In the third photo a girder is
being post-tensioned after adequate curing. The next photo shows a crane on a barge
that transports a girder to the bridge site. The completed bridge can be seen in the last
photo.
(a) Reinforcement cage for box girder
(b) Formwork for box girder
(c) Post-tensioning of box girder
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(d) Transporting of box girder
(e) Completed bridge
Figure 1-4.20 Manufacturing of post-tensioned bridge box girders
1.5 Concrete (Part I)
This section covers the following topics.
Constituents of Concrete
Properties of Hardened Concrete (Part I)
1.5.1 Constituents of Concrete
Introduction
Concrete is a composite material composed of gravels or crushed stones (coarse
aggregate), sand (fine aggregate) and hydrated cement (binder). It is expected that the
student of this course is familiar with the basics of concrete technology. Only the
information pertinent to prestressed concrete design is presented here.
The following figure shows a petrographic section of concrete. Note the scattered
coarse aggregates and the matrix surrounding them. The matrix consists of sand,
hydrated cement and tiny voids.
Figure 1-5.1 Petrographic section of hardened concrete
(Reference: Portland Cement Association, Design and Control of Concrete Mixtures)
Aggregate
The coarse aggregate are granular materials obtained from rocks and crushed stones.
They may be also obtained from synthetic material like slag, shale, fly ash and clay foruse in light-weight concrete.
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The sand obtained from river beds or quarries is used as fine aggregate. The fine
aggregate along with the hydrated cement paste fill the space between the coarse
aggregate.
The important properties of aggregate are as follows.
1) Shape and texture
2) Size gradation
3) Moisture content
4) Specific gravity
5) Unit weight
6) Durability and absence of deleterious materials.
The requirements of aggregate is covered in Section 4.2 of IS:1343 - 1980.
The nominal maximum coarse aggregate size is limited by the lowest of the following
quantities.
1) 1/4 times the minimum thickness of the member
2) Spacing between the tendons/strands minus 5 mm
3) 40 mm.
The deleterious substances that should be limited in aggregate are clay lumps, wood,
coal, chert, silt, rock dust (material finer than 75 microns), organic material, unsound
and friable particles.
CementIn present day concrete, cement is a mixture of lime stone and clay heated in a kiln to
1400 - 1600C. The types of cement permitted by IS:1343 - 1980 (Clause 4.1) for
prestressed applications are the following. The information is revised as per IS:456 -
2000, Plain and Reinforced Concrete Code of Practice.
1) Ordinary Portland cement confirming to IS:269 - 1989, Ordinary Portland Cement,
33 Grade Specification.
2) Portland slag cement confirming to IS:455 - 1989, Portland Slag Cement
Specification, but with not more than 50% slag content.
3) Rapid-hardening Portland cement confirming to IS:8041 - 1990, Rapid Hardening
Portland Cement Specification.
WaterThe water should satisfy the requirements ofSection 5.4 ofIS:456 - 2000.
Water used for mixing and curing shall be clean and free from injurious amounts of oils,
acids, alkalis, salts, sugar, organic materials or other substances that may be
deleterious to concrete and steel.
Admixtures
IS:1343 - 1980 allows to use admixtures that conform to IS:9103 - 1999, Concrete
Admixtures Specification. The admixtures can be broadly divided into two types:
chemical admixtures and mineral admixtures. The common chemical admixtures are as
follows.
1) Air-entraining admixtures
2) Water reducing admixtures
3) Set retarding admixtures
4) Set accelerating admixtures
5) Water reducing and set retarding admixtures
6) Water reducing and set accelerating admixtures.
The common mineral admixtures are as follows.
1) Fly ash
2) Ground granulated blast-furnace slag
3) Silica fumes
4) Rice husk ash
5) MetakolineThese are cementitious and pozzolanic materials.
1.5.2 Propert ies of Hardened Concrete (Part I)
The concrete in prestressed applications has to be of good quality. It requires the
following attributes.
1) High strength with low water-to-cement ratio
2) Durability with low permeability, minimum cement content and proper mixing,
compaction and curing
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3) Minimum shrinkage and creep by limiting the cement content.
The following topics are discussed.
1) Strength of concrete2) Stiffness of concrete
3) Durability of concrete
4) High performance concrete
5) Allowable stresses in concrete.
Strength of Concrete
The following sections describe the properties with reference to IS:1343 - 1980. The
strength of concrete is required to calculate the strength of the members. For
prestressed concrete applications, high strength concrete is required for the following
reasons.
1) To sustain the high stresses at anchorage regions.
2) To have higher resistance in compression, tension, shear and bond.
3) To have higher stiffness for reduced deflection.
4) To have reduced shrinkage cracks.
Compressive Strength
The compressive strength of concrete is given in terms of the characteristic
compressive strength of 150 mm size cubes tested at 28 days (fck). The characteristic
strength is defined as the strength of the concrete below which not more than 5% of the
test results are expected to fall. This concept assumes a normal distribution of the
strengths of the samples of concrete.
The following sketch shows an idealised distribution of the values of compressivestrength for a sizeable number of test cubes. The horizontal axis represents the values
of compressive strength. The vertical axis represents the number of test samples for a
particular compressive strength. This is also termed as frequency. The average of the
values of compressive strength (mean strength) is represented as fcm. The characteristic
strength (fck) is the value in the x-axis below which 5% of the total area under the curve
falls. The value offck is lower than fcm by 1.65, where is the standard deviation of the
normal distribution.
fck fcm
1.65
Frequency
28 day cube compressive strength
5% area fck fcm
1.65
Frequency
28 day cube compressive strength
5% area
Figure 1-5.2 Idealised normal distribution of concrete strength
(Reference: Pillai, S. U., and Menon, D., Reinforced Concrete Design)
The sampling and strength test of concrete are as per Section 15 of IS:1343 - 1980.The grades of concrete are explained inTable 1 of the Code.
The minimum grades of concrete for prestressed applications are as follows.
30 MPa for post-tensioned members
40 MPa for pre-tensioned members.
The maximum grade of concrete is 60 MPa.
Since at the time of publication of IS:1343 in 1980, the properties of higher strength
concrete were not adequately documented, a limit was imposed on the maximum
strength. It is expected that higher strength concrete may be used after proper testing.
The increase in strength with age as given in IS:1343 - 1980, is not observed in present
day concrete that gains substantial strength in 28 days. Hence, the age factor given in
Clause 5.2.1 should not be used. It has been removed from IS:456 - 2000.
Tensile Strength
The tensile strength of concrete can be expressed as follows.
1) Flexural t ensile strength: It is measured by testing beams under 2 point loading
(also called 4 point loading including the reactions).2) Splitting tensile strength: It is measured by testing cylinders under diametral
compression.
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3) Direct tensile strength: It is measured by testing rectangular specimens under
direct tension.
In absence of test results, the Code recommends to use an estimate of the flexural
tensile strength from the compressive strength by the following equation.
cr ck f = f0.7 (1-5.1)
Here,
fcr =flexural tensile strength in N/mm2
fck =characteristic compressive strength of cubes in N/mm2.
Stiffness of Concrete
The stiffness of concrete is required to estimate the deflection of members. The
stiffness is given by the modulus of elasticity. For a non-linear stress (fc) versus strain
(c) behaviour of concrete the modulus can be initial, tangential or secant modulus.
IS:1343 - 1980 recommends a secant modulus at a stress level of about 0.3fck. The
modulus is expressed in terms of the characteristic compressive strength and not the
design compressive strength. The following figure shows the secant modulus in the
compressive stress-strain curve for concrete.
c
fc
fck
Ec
fc
c
fc
fck
Ecc
fc
fck
Ec
fcfc
Figure 1-5.3 a) Concrete cube under compression, b) Compressive stress-strain
curve for concrete
The modulus of elasticity for short term loading (neglecting the effect of creep) is given
by the following equation.
c cE = f5000 k (1-5.2)
Here,
Ec =short-term static modulus of elasticity in N/mm2
fck =characteristic compressive strength of cubes in N/mm2.
The above expression is updated as per IS:456 - 2000.
Durability of ConcreteThe durability of concrete is of vital importance regarding the life cycle cost of a
structure. The life cycle cost includes not only the initial cost of the materials and labour,
but also the cost of maintenance and repair.
In recent years emphasis has been laid on the durability issues of concrete. This is
reflected in the enhanced section on durability (Section 8) in IS:456 - 2000. It is
expected that the revised version of IS:1343 will also have similar importance on
durability.
The durability of concrete is defined as its ability to resist weathering action, chemical
attack, abrasion, or any other process of deterioration. The common durability
problems in concrete are as follows.
1) Sulphate and other chemical attacks of concrete.
2) Alkali-aggregate reaction.
3) Freezing and thawing damage in cold regions.
4) Corrosion of steel bars or tendons.
The durability of concrete is intrinsically related to its water tightness or permeability.
Hence, the concrete should have low permeability and there should be adequate cover
to reinforcing bars. The selection of proper materials and good quality control are
essential for durability of concrete.
The durability is addressed in IS:1343 - 1980 in Section 7. In Appendix A there are
guidelines on durability. Table 9 specifies the maximum water-to-cement (w-c) ratio
and the minimum cement content for different exposure conditions. The values for
moderate exposure condition are reproduced below.
Table 1-5.1 Maximum water-to-cement (w-c) ratio and the minimum cement content
for moderate exposure conditions (IS:1343 - 1980).
Min. cement content : 300 kg per m3 of concrete
Max w-c ratio* : 0.50
(*The value is updated as per Table 5 ofIS:456 - 2000.)
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Table 10 provides the values for the above quantities for concrete exposed to sulphate
attack.
To limit the creep and shrinkage, IS:1343 - 1980 specifies a maximum cement content
of 530 kg per m3 of concrete (Clause 8.1.1).
High Performance Concrete
With the advancement of concrete technology, high performance concrete is getting
popular in prestressed applications. The attributes of high performance concrete are as
follows.
1) High strength
2) Minimum shrinkage and creep
3) High durability
4) Easy to cast
5) Cost effective.
Traditionally high performance concrete implied high strength concrete with higher
cement content and low water-to-cement ratio. But higher cement content leads to
autogenous and plastic shrinkage cracking and thermal cracking. At present durability
is also given importance along with strength.
Some special types of high performance concrete are as follows.
1) High strength concrete
2) High workability concrete
3) Self-compacting concrete
4) Reactive powder concrete5) High volume fly ash concrete
6) Fibre reinforced concrete
In a post-tensioned member, the concrete next to the anchorage blocks (referred to as
end block) is subjected to high stress concentration. The type of concrete at the end
blocks may be different from that at the rest of the member. Fibre reinforced concrete is
used to check the cracking due to the bursting forces.
The following photo shows that the end blocks were cast separately with high strength
concrete.
Figure 1-5.4 End-blocks in a bridge deck(Courtesy: Cochin Port Trust, Kerala)
Al lowab le Stresses in Concrete
The allowable stresses are used to analyse and design members under service loads.
IS:1343 - 1980 specifies the maximum allowable compressive stresses for different
grades of concrete under different loading conditions in Section 22.8.
Allowable Compressive Stresses under Flexure
The following sketch shows the variation of allowable compressive stresses for different
grades of concrete at transfer. The cube strength at transfer is denoted as fci.
M30 M60 M40 M60
0.51fci0.44fci
0.54fci0.37fci
Post-tension Pre-tension
M30 M60 M40 M60
0.51fci0.44fci
0.54fci0.37fci
Post-tension Pre-tension
Figure 1-5.5 Variation of allowable compressive stresses at transfer
The following sketch shows the variation of allowable compressive stresses for different
grades of concrete at service loads.
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0.34fck
0.41fck
0.27fck
0.35fck
M 30 M 60
Zone I
Zone II
Figure 1-5.6 Variation of allowable compressive stresses at service loads
Here, Zone I represents the locations where the compressive stresses are not likely to
increase. Zone II represents the locations where the compressive stresses are likely to
increase, such as due to transient loads from vehicles in bridge decks.
Allowable Compressive Stresses under Direct Compression
For direct compression, except in the parts immediately behind the anchorage, the
maximum stress is equal to 0.8 times the maximum compressive stress under flexure.
Allowable Tensile Stresses under Flexure
The prestressed members are classified into three different types based on the
allowable tensile stresses. The amount of prestressing varies in the three types. Theallowable tensile stresses for the three types of members are specified in Section 22.7.
The values are reproduced below.
Table 1-5.2 Allowable tensile stresses (IS:1343 - 1980)
Type 1 No tensile stress
Type 23 N/mm2.
This value can be increased to 4.5 N/mm2 for temporary loads.
Type 3 Table 8 provides hypothetical values of allowable tensile stresses.
The purpose of providing hypothetical values is to use the elastic analysis method for
Type 3 members even after cracking of concrete.
1.6 Concrete (Part II)
This section covers the following topics.
Properties of Hardened Concrete (Part II)
Properties of Grout
Codal Provisions of Concrete
1.6.1 Propert ies of Hardened Concrete (Part II)
The properties that are discussed are as follows.
1) Stress-strain curves for concrete
2) Creep of concrete
3) Shrinkage of concrete
Stress-strain Curves f or Concrete
Curve under uniaxial compression
The stress versus strain behaviour of concrete under uniaxial compression is initially
linear (stress is proportional to strain) and elastic (strain is recovered at unloading). Withthe generation of micro-cracks, the behaviour becomes nonlinear and inelastic. After the
specimen reaches the peak stress, the resisting stress decreases with increase in strain.
IS:1343 - 1980 recommends a parabolic characteristic stress-strain curve, proposed by
Hognestad, for concrete under uniaxial compression (Figure 3 in the Code).
c0 cu
fc
fck
fc
c0 cu
fc
fck
c0 cu
fc
fck
fcfc
Figure 1-6.1 a) Concrete cube under compression, b) Design stress-strain curve for
concrete under compression due to flexure
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The equation for the design curve under compression due to flexure is as follows.
Forc0
c cck ck
f = f -
2
0 0
2 (1-6.1)
Forc< ccu
fc= fck (1-6.2)
Here,
fc = compressive stress
fck = characteristic compressive strength of cubes
c = compressive strain
0 = strain corresponding to fck= 0.002
cu = ultimate compressive strain = 0.0035
For concrete under compression due to axial load, the ultimate strain is restricted to
0.002. From the characteristic curve, the design curve is defined by multiplying the
stress with a size factor of 0.67 and dividing the stress by a material safety factor of m =
1.5. The design curve is used in the calculation of ultimate strength. The following
sketch shows the two curves.
0 cu c
fc
fck
0.447 fck
Characteristic curve
Design curve
0 cu c
fc
fck
0.447 fck
Characteristic curve
Design curve
Figure 1-6.2 Stress-strain curves for concrete under compression due to flexure
In the calculation of deflection at service loads, a linear stress-strain curve is assumed
up to the allowable stress. This curve is given by the following equation.
fc= Ecc (1-6.3)
Note that, the size factor and the material safety factor are not used in the elastic
modulus Ec.
For high strength concrete (say M100 grade of concrete and above) under uniaxial
compression, the ascending and descending branches are steep.
0 c
fcfck
Es
Eci
0 c
fcfck
Es
Eci
Figure 1-6.3 Stress-strain curves for high strength concrete under compression
The equation proposed by Thorenfeldt, Tomaxzewicz and Jensen is appropriate for high
strength concrete.
c
c ck nk
c
n
f = f
n - +
0
0
1
(1-6.4)
The variables in the previous equation are as follows.
fc = compressive stress
fck = characteristic compressive strength of cubes in N/mm2
c = compressive strain
0 = strain corresponding to fck
k = 1 forc0
= 0.67 + (fck / 77.5) forc>0. The value ofkshould be greater than 1.
n = Eci / (Eci Es)
Eci = initial modulus
Es = secant modulus at fck= fck /0.
The previous equation is applicable for both the ascending and descending branches of
the curve. Also, the parameter k models the slope of the descending branch, which
increases with the characteristic strength fck. To be precise, the value of 0 can be
considered to vary with the compressive strength of concrete.
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Curve under uniaxial tension
The stress versus strain behaviour of concrete under uniaxial tension is linear elastic
initially. Close to cracking nonlinear behaviour is observed.
fc
c
fcfc
c
fc
c
fcfc
(a) (b)
Figure 1-6.4 a) Concrete panel under tension, b) Stress-strain curve for concrete
under tension
In calculation of deflections of flexural members at service loads, the nonlinearity is
neglected and a linear elastic behaviourfc= Ecc is assumed. In the analysis of ultimate
strength, the tensile strength of concrete is usually neglected.
Creep of Concrete
Creep of concrete is defined as the increase in deformation with time under constant
load. Due to the creep of concrete, the prestress in the tendon is reduced with time.
Hence, the study of creep is important in prestressed concrete to calculate the loss in
prestress.
The creep occurs due to two causes.
1. Rearrangement of hydrated cement paste (especially the layered products)
2. Expulsion of water from voids under load
If a concrete specimen is subjected to slow compressive loading, the stress versus
strain curve is elongated along the strain axis as compared to the curve for fast loading.
This can be explained in terms of creep. If the load is sustained at a level, the increase
in strain due to creep will lead to a shift from the fast loading curve to the slow loading
curve (Figure 1-6.5).
c
fcFast loading
Slow loading
Effect of creep
c
fcFast loading
Slow loading
Effect of creep
Figure 1-6.5 Stress-strain curves for concrete under compression
Creep is quantified in terms of the strain that occurs in addition to the elastic strain due
to the applied loads. If the applied loads are close to the service loads, the creep strain
increases at a decreasing rate with time. The ultimate creep strain is found to be
proportional to the elastic strain. The ratio of the ultimate creep strain to the elastic
strain is called the creep coefficient.
For stress in concrete less than about one-third of the characteristic strength, the
ultimate creep strain is given as follows.
cr,ult el = (1-6.5)
The variation of strain with time, under constant axial compressive stress, is
represented in the following figure.
strain
Time (linear scale)
cr, ult= ultimate creep strain
el= elastic strain
strain
Time (linear scale)
cr, ult= ultimate creep strain
el= elastic strain
Figure 1-6.6 Variation of strain with time for concrete under compression
If the load is removed, the elastic strain is immediately recovered. However the
recovered elastic strain is less than the initial elastic strain, as the elastic modulus
increases with age.
There is reduction of strain due to creep recovery which is less than the creep strain.
There is some residual strain which cannot be recovered (Figure 1-6.7).
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strain
Time (linear scale)
Residual strain
Creep recovery
Elastic recovery
Unloadingstrain
Time (linear scale)
Residual strain
Creep recovery
Elastic recovery
Unloading
Figure 1-6.7 Variation of strain with time showing the effect of unloading
The creep strain depends on several factors. It increases with the increase in the
following variables.1) Cement content (cement paste to aggregate ratio)
2) Water-to-cement ratio
3) Air entrainment
4) Ambient temperature.
The creep strain decreases with the increase in the following variables.
1) Age of concrete at the time of loading.
2) Relative humidity
3) Volume to surface area ratio.
The creep strain also depends on the type of aggregate.
IS:1343 - 1980 gives guidelines to estimate the ultimate creep strain in Section 5.2.5. It
is a simplified estimate where only one factor has been considered. The factor is age of
loading of the prestressed concrete structure. The creep coefficient is provided for
three values of age of loading.
Table 1-6.1 Creep coefficient for three values of age of loading
Age of Loading Creep Coefficient
7 days 2.2
28 days 1.6
1 year 1.1
It can be observed that if the structure is loaded at 7 days, the creep coefficient is 2.2.
This means that the creep strain is 2.2 times the elastic strain. Thus, the total strain is
more than thrice the elastic strain. Hence, it is necessary to study the effect of creep inthe loss of prestress and deflection of prestressed flexural members. Even if the
structure is loaded at 28 days, the creep strain is substantial. This implies higher loss of
prestress and higher deflection.
Curing the concrete adequately and delaying the application of load provide long term
benefits with regards to durability, loss of prestress and deflection.
In special situations detailed calculations may be necessary to monitor creep strain with
time. Specialised literature or international codes can provide guidelines for such
calculations.
Shrinkage of Concrete
Shrinkage of concrete is defined as the contraction due to loss of moisture. The study of
shrinkage is also important in prestressed concrete to calculate the loss in prestress.
The shrinkage occurs due to two causes.
1. Loss of water from voids
2. Reduction of volume during carbonation
The following figure shows the variation of shrinkage strain with time. Here, t0 is the time
at commencement of drying. The shrinkage strain increases at a decreasing rate with
time. The ultimate shrinkage strain (sh) is estimated to calculate the loss in prestress.
Shrinkage
strain
t0 Time (linear scale)
sh
Shrinkage
strain
t0 Time (linear scale)
sh
Figure 1-6.8 Variation of shrinkage strain with time
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Like creep, shrinkage also depends on several factors. The shrinkage strain increases
with the increase in the following variables.
1) Ambient temperature2) Temperature gradient in the members
3) Water-to-cement ratio
4) Cement content.
The shrinkage strain decreases with the increase in the following variables.
1) Age of concrete at commencement of drying
2) Relative humidity
3) Volume to surface area ratio.
The shrinkage strain also depends on the type of aggregate.
IS:1343 - 1980 gives guidelines to estimate the shrinkage strain in Section 5.2.4. It is a
simplified estimate of the ultimate shrinkage strain (sh).
For pre-tension
sh = 0.0003 (1-6.6)
For post-tension
(1-6.7)
( )sh =
log t +10
0.0002
2
Here, tis the age at transfer in days. Note that for post-tension, tis the age at transfer
in days which approximates the curing time.
It can be observed that with increasing age at transfer, the shrinkage strain reduces. Asmentioned before, curing the concrete adequately and delaying the application of load
provide long term benefits with regards to durability and loss of prestress.
In special situations detailed calculations may be necessary to monitor shrinkage strain
with time. Specialised literature or international codes can provide guidelines for such
calculations.
1.6.2 Properties of Grout
Grout is a mixture of water, cement and optional materials like sand, water-reducingadmixtures, expansion agent and pozzolans. The water-to-cement ratio is around 0.5.
Fine sand is used to avoid segregation.
The desirable properties of grout are as follows.
1) Fluidity
2) Minimum bleeding and segregation
3) Low shrinkage
4) Adequate strength after hardening
5) No detrimental compounds
6) Durable.
IS:1343 - 1980 specifies the properties of grout in Sections 12.3.1 and Section 12.3.2.
The following specifications are important.
1) The sand should pass 150 m Indian Standard sieve.
2) The compressive strength of 100 mm cubes of the grout shall not be less than 17
N/mm2 at 7 days.
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1.6.5 Codal Provisions of Concrete
The following topics are covered in IS:1343 - 1980 under the respective sections. These
provisions are not duplicated here.
Table 1-6.2 Topics and sections
Workability of concrete Section 6
Concrete mix proportioning Section 8
Production and control of concrete Section 9
Formwork Section 10
Transporting, placing, compacting Section 13
Concrete under special conditions Section 14
Sampling and strength test of concrete Section 15
Acceptance criteria Section 16
Inspection and testing of structures Section 17
1.7 Prestressing Steel
This section covers the following topics.
Forms of Prestressing Steel
Types of Prestressing Steel
Properties of Prestressing Steel
Codal Provisions of Steel
1.7.1 Forms of Prestressing Steel
The development of prestressed concrete was influenced by the invention of high
strength steel. It is an alloy of iron, carbon, manganese and optional materials. The
following material describes the types and properties of prestressing steel.
In addition to prestressing steel, conventional non-prestressed reinforcement is used for
flexural capacity (optional), shear capacity, temperature and shrinkage requirements.
The properties of steel for non-prestressed reinforcement are not covered in this section.
It is expected that the student of this course is familiar with the conventional
reinforcement.
Wires
A prestressing wire is a single unit made of steel. The nominal diameters of the wires
are 2.5, 3.0, 4.0, 5.0, 7.0 and 8.0 mm. The different types of wires are as follows.
1) Plain wire: No indentations on the surface.
2) Indented wire: There are circular or elliptical indentations on the surface.
Strands
A few wires are spun together in a helical form to form a prestressing strand. The
different types of strands are as follows.
1) Two-wire strand: Two wires are spun together to form the strand.
2) Three-wire strand: Three wires are spun together to form the strand.
3) Seven-wire strand: In this type of strand, six wires are spun around a central wire.
The central wire is larger than the other wires.
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Tendons
A group of strands or wires are placed together to form a prestressing tendon. The
tendons are used in post-tensioned members. The following figure shows the cross
section of a typical tendon. The strands are placed in a duct which may be filled with
grout after the post-tensioning operation is completed (Figure 1-7.1).
Duct
Grout
Duct
Grout
Figure 1-7.1 Cross-section of a typical tendon
Cables
A group of tendons form a prestressing cable. The cables are used in bridges.
Bars
A tendon can be made up of a single steel bar. The diameter of a bar is much larger
than that of a wire. Bars are available in the following sizes: 10, 12, 16, 20, 22, 25, 28
and 32 mm.
The following figure shows the different forms of prestressing steel.
Reinforcing barsPrestressing wires,strands and barsReinforcing bars
Prestressing wires,strands and bars
Figure 1-7.2 Forms of reinforcing and prestressing steel
1.7.2 Types of Prestressing Steel
The steel is treated to achieve the desired properties. The following are the treatmentprocesses.
Cold working (cold drawing)
The cold working is done by rolling the bars through a series of dyes. It re-aligns the
crystals and increases the strength.
Stress relieving
The stress relieving is done by heating the strand to about 350 C and cooling slowly.
This reduces the plastic deformation of the steel after the onset of yielding.
Strain tempering f or low relaxation
This process is done by heating the strand to about 350 C while it is under tension.
This also improves the stress-strain behaviour of the steel by reducing the plastic
deformation after the onset of yielding. In addition, the relaxation is reduced. The
relaxation is described later.
IS:1343 - 1980 specifies the material properties of steel in Section 4.5. The following
types of steel are allowed.
1) Plain cold drawn stress relieved wire conforming to IS:1785, Part 1, Specification
for Plain Hard Drawn Steel Wire for Prestressed Concrete, Part I Cold Drawn
Stress Relieved Wire.
2) Plain as-drawn wire conforming to IS:1785, Part 2, Specification for Plain HardDrawn Steel Wire for Prestressed Concrete, Part II As Drawn Wire.
3) Indented cold drawn wire conforming to IS:6003, Specification for Indented Wire
for Prestressed Concrete.
4) High tensile steel bar conforming to IS:2090, Specification for High Tensile Steel
Bars used in Prestressed Concrete.
5) Uncoated stress relieved strand conforming to IS:6006. Specification for
Uncoated Stress Relieved Strand for Prestressed Concrete.
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1.7.3 Properties of Prestressing Steel
The steel in prestressed applications has to be of good quality. It requires the followingattributes.
1) High strength
2) Adequate ductility
3) Bendability, which is required at the harping points and near the anchorage
4) High bond, required for pre-tensioned members
5) Low relaxation to reduce losses
6) Minimum corrosion.
Strength of Prestressing Steel
The tensile strength of prestressing steel is given in terms of the characteristic tensile
strength (fpk).
The characteristic strength is defined as the ultimate tensile strength of the coupon
specimens below which not more than 5% of the test results are expected to fall.
The ultimate tensile strength of a coupon specimen is determined by a testing machine
according to IS:1521 - 1972, Method for Tensile Testing of Steel Wire. The following
figure shows a test setup.
Extensometer
Wedge grips
Coupon specimen
Extensometer
Wedge grips
Coupon specimen
(a) Test set-up
(b) Failure of a strand
Figure 1-7.3 Testing of tensile strength of prestressing strand
The minimum tensile strengths for different types of wires as specified by the codes are
reproduced.
Table 1-7.1 Cold Drawn Stress-Relieved Wires (IS: 1785 Part 1)
Nominal Diameter (mm) 2.50 3.00 4.00 5.00 7.00 8.00
Minimum Tensile Strength fpk
(N/mm2)
2010 1865 1715 1570 1470 1375
The proof stress (defined later) should not be less than 85% of the specified tensile
strength.
Table 1-7.2 As-Drawn wire (IS: 1785 Part 2)
Nominal Diameter (mm) 3.00 4.00 5.00
Minimum Tensile Strength fpk(N/mm2) 1765 1715 1570
The proof stress should not be less than 75% of the specified tensile strength.Table 1-7.3 Indented wire (IS: 6003)
Nominal Diameter (mm) 3.00 4.00 5.00
Minimum Tensile Strength fpk(N/mm2) 1865 1715 1570
The proof stress should not be less than 85% of the specified tensile strength.
For high tensile steel bars (IS: 2090), the minimum tensile strength is 980 N/mm
2
. Theproof stress should not be less than 80% of the specified tensile strength.
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Stiffness of Prestressing Steel
The stiffness of prestressing steel is given by the initial modulus of elasticity. The
modulus of elasticity depends on the form of prestressing steel (wires or strands or
bars).
IS:1343 - 1980 provides the following guidelines which can be used in absence of test
data.
Table 1-7.4 Modulus of elasticity (IS: 1343 - 1980)
Type of steel Modulus of elasticity
Cold-drawn wires 210 kN/mm2
High tensile steel bars 200 kN/mm2
Strands 195 kN/mm2
Al lowab le Stress in Prest ressing Steel
As per Clause 18.5.1, the maximum tensile stress during prestressing (fpi) shall not
exceed 80% of the characteristic strength.
pi pf 0.8 kf (1-7.1)
There is no upper limit for the stress at transfer (after short term losses) or for the
effective prestress (after long term losses).
Stress-Strain Curves for Prestressing Steel
The stress versus strain behaviour of prestressing steel under uniaxial tension is initially
linear (stress is proportional to strain) and elastic (strain is recovered at unloading).
Beyond about 70% of the ultimate strength the behaviour becomes nonlinear and
inelastic. There is no defined yield point.
The yield point is defined in terms of the proof stress or a specified yield strain. IS:1343
- 1980 recommends the yield point at 0.2% proof stress. This stress corresponds to an
inelastic strain of 0.002. This is shown in the following figure.
0.002
Proof
stress
p
fp
0.002
Proof
stress
p
fp
Figure 1-7.4 Proof stress corresponds to inelastic strain of 0.002
The characteristic stress-strain curves are given in Figure 5 ofIS:1343 - 1980. The
stress corresponding to a strain can be found out by using these curves as shown next.
0.002 0.005
0.95fpk
0.9fpk
p
fp
0.002 0.005
0.95fpk
0.85fpk
p
fp
Stress relieved wires,strands and bars As-drawn wires
0.002 0.005
0.95fpk
0.9fpk
p
fp
0.002 0.005
0.95fpk
0.9fpk
p
fp
0.002 0.005
0.95fpk
0.85fpk
p
fp
0.002 0.005
0.95fpk
0.85fpk
p
fp
Stress relieved wires,strands and bars As-drawn wires
Figure 1-7.5 Characteristic stress-strain curves for prestressing steel
(Figure 5, IS:1343 - 1980)
The stress-strain curves are influenced by the treatment processes. The following figure
shows the variation in the 0.2% proof stress for wires under different treatment
processes.
low relaxation
stress relieved
as-drawn
p
fplow relaxation
stress relieved
as-drawn
p
fp
Figure 1-7.6 Variation in the 0.2% proof stress for wires under different treatment
processes
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The design stress-strain curves are calculated by dividing the stress beyond 0.8fpkby a
material safety factor m=1.15. The following figure shows the characteristic and design
stress-strain curves.
0.8fpk
p
fp
Characteristic curve
Design curve0.8fpk
p
fp
Characteristic curve
Design curve
Figure 1-7.7 Characteristic and design stress-strain curves forprestressing steel
Relaxation of Steel
Relaxation of steel is defined as the decrease in stress with time under constant strain.
Due to the relaxation of steel, the prestress in the tendon is reduced with time. Hence,
the study of relaxation is important in prestressed concrete to calculate the loss in
prestress.
The relaxation depends on the type of steel, initial prestress and the temperature. The
following figure shows the effect of relaxation due to different types of loading conditions.
p
fp
Fast loading
With sustained loadingEffect of relaxation
p
fp
Fast loading
With sustained loadingEffect of relaxation
Figure 1-7.8 Effect of relaxation due to different types of loading conditions
The following figure shows the variation of stress with time for different levels of
prestressing. Here, the instantaneous stress (fp) is normalised with respect to the initialprestressing (fpi) in the ordinate. The curves are for different values offpi/fpy, where fpyis
the yield stress.
100
90
8070
60
5010 100 1000 10,000 100,000
Time (hours)
fp
fpi p i
p y
f=
f
0.6
0.70.8
0.9
100
90
8070
60
5010 100 1000 10,000 100,000
Time (hours)
fp
fpi p i
p y
f=
f
0.6
0.70.8
0.9
Figure 1-7.9 Variation of stress with time for different levels of prestressing
It can be observed that there is significant relaxation loss when the applied stress is
more than 70% of the yield stress.
The following photos show the test set-up for relaxation test.
Load cell
Specimen
Load cell
Specimen
(a) Test of a single wire strand
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SpecimenSpecimen
(b) Test of a seven-wire strand
Figure 1-7.10 Set-up for relaxation test
The upper limits of relaxation loss are specified as follows.
Table 1-7.5 Relaxation losses at 1000 hours (IS:1785, IS:6003, IS:6006, IS:2090)
Cold drawn stress-relieved wires 5% of initial prestress
Indented wires 5% of initial prestress
Stress-relieved strand 5% of initial prestress
Bars 49 N/mm2
In absence of test data, IS:1343 - 1980 recommends the following estimates of
relaxation losses.
Table 1-7.6 Relaxation losses at 1000 hours at 27C
Initial Stress Relaxation Loss (N/mm2)
0.5fpk 0
0.6fpk 35
0.7fpk 70
0.8fpk 90
Fatigue
Under repeated dynamic loads the strength of a member may reduce with the number
of cycles of applied load. The reduction in strength is referred to as fatigue.
In prestressed applications, the fatigue is negligible in members that do not crack under
service loads. If a member cracks, fatigue may be a concern due to high stress in the
steel at the location of cracks.
Specimens are tested under 2 x 106 cycles of load to observe the fatigue. For steel,
fatigue tests are conducted to develop the stress versus number of cycles for failure (S-
N) diagram. Under a limiting value of stress, the specimen can withstand infinite number
of cycles. This limit is known as the endurance limit.
The prestressed member is designed such that the stress in the steel due to service
loads remains under the endurance limit. The following photo shows a set-up for
fatigue testing of strands.
Figure 1-7.11 Set-up for fatigue testing of strands
Durability
Prestressing steel is susceptible to stress corrosion and hydrogen embrittlement in
aggressive environments. Hence, prestressing steel needs to be adequately protected.
For bonded tendons, the alkaline environment of the grout provides adequate protection.
For unbonded tendons, corrosion protection is provided by one or more of the following
methods.
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1) Epoxy coating
2) Mastic wrap (grease impregnated tape)
3) Galvanized bars
4) Encasing in tubes.
1.7.4 Codal Provis ions o f Steel
The following topics are covered in IS:1343 - 1980 under the respective sections. These
provisions are not duplicated here.
Table 1-7.7 Topics and sections
Assembly of prestressing and reinforcing steel Section 11
Prestressing Section 12
2.1 Losses in Prestress (Part I)
This section covers the following topics.
Introduction Elastic Shortening
The relevant notations are explained first.
Notations
Geometric Properties
The commonly used geometric properties of a prestressed member are defined as
follows.Ac = Area of concrete section
= Net cross-sectional area of concrete excluding the area of
prestressing steel.
Ap = Area of prestressing steel
= Total cross-sectional area of the tendons.
A = Area of prestressed member
= Gross cross-sectional area of prestressed member.
=Ac+Ap
At = Transformed area of prestressed member
= Area of the member when steel is substituted by an equivalent
area of concrete.
=Ac+ mAp
=A + (m 1)Ap
Here,
m = the modular ratio = Ep/Ec
Ec = short-term elastic modulus of concrete
Ep = elastic modulus of steel.
The following figure shows the commonly used areas of the prestressed members.
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= +
A Ac Ap At
= +
A Ac Ap At
Figure 2-1.1 Areas for prestressed members
CGC = Centroid of concrete
= Centroid of the gross section. The CGC may lie outside the
concrete (Figure 2-1.2).CGS = Centroid of prestressing steel
= Centroid of the tendons. The CGS may lie outside the tendons or
the concrete (Figure 2-1.2).
I = Moment of inertia of prestressed member
= Second moment of area of the gross section about the CGC.
It = Moment of inertia of transformed section
= Second moment of area of the transformed section about the
centroid of the transformed section.
e = Eccentricity of CGS with respect to CGC
= Vertical distance between CGC and CGS. If CGS lies below CGC,
e will be considered positive and vice versa (Figure 2-1.2).
CGSCGCe
CGS
CGCe
CGSCGCeCGSCGCCGSCGCe
CGS
CGCe
CGS
CGC
CGS
CGC
CGS
CGCe
Figure 2-1.2 CGC, CGS and eccentricity of typical prestressed members
Load Variables
Pi = Initial prestressing force= The force which is applied to the tendons by the jack.
P0 = Prestressing force after immediate losses
= The reduced value of prestressing force after elastic shortening,
anchorage slip and loss due to friction.
Pe = Effective prestressing force after time-dependent losses
= The final value of prestressing force after the occurrence of creep,
shrinkage and relaxation.
2.1.1 Introduction
In prestressed concrete applications, the most important variable is the prestressing
force. In the early days, it was observed that the prestressing force does not stay
constant, but reduces with time. Even during prestressing of the tendons and the
transfer of prestress to the concrete member, there is a drop of the prestressing force
from the recorded value in the jack gauge. The various reductions of the prestressing
force are termed as the losses in prestress.
The losses are broadly classified into two groups, immediate and time-dependent. The
immediate losses occur during prestressing of the tendons and the transfer of prestress
to the concrete member. The time-dependent losses occur during the service life of the
prestressed member. The losses due to elastic shortening of the member, friction at the
tendon-concrete interface and slip of the anchorage are the immediate losses. The
losses due to the shrinkage and creep of the concrete and relaxation of the steel are the
time-dependent losses. The causes of the various losses in prestress are shown in the
following chart.
Losses
Immediate Time dependent
Elasticshortening
Friction Anchorageslip
Creep Shrinkage Relaxation
Figure 2-1.3 Causes of the various losses in prestress
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2.1.2 Elastic Shortening
Pre-tensioned MembersWhen the tendons are cut and the prestressing force is transferred to the member, the
concrete undergoes immediate shortening due to the prestress. The tendon also
shortens by the same amount, which leads to the loss of prestress.
Post-tensioned Members
If there is only one tendon, there is no loss because the applied prestress is recorded
after the elastic shortening of the member. For more than one tendon, if the tendons
are stretched sequentially, there is loss in a tendon during subsequent stretching of the
other tendons.
The elastic shortening loss is quantified by the drop in prestress (fp) in a tendon due to
the change in strain in the tendon (p). It is assumed that the change in strain in the
tendon is equal to the strain in concrete (c) at the level of the tendon due to the
prestressing force. This assumption is called strain compatibility between concrete
and steel. The strain in concrete at the level of the tendon is calculated from the stress
in concrete (fc) at the same level due to the prestressing force. A linear elastic
relationship is used to calculate the strain from the stress.
The quantification of the losses is explained below.
p p p
p c
cp
c
p c
f = E
= E
f= EE
f = mf (2-1.1)
For simplicity, the loss in all the tendons can be calculated based on the stress in
concrete at the level of CGS. This simplification cannot be used when tendons are
stretched sequentially in a post-tensioned member. The calculation is illustrated for the
following types of members separately.
Pre-tensioned Axial Members
Pre-tensioned Bending Members
Post-tensioned Axial Members
Post-tensioned Bending Members
Pre-tensioned Axial Members
The following figure shows the changes in length and the prestressing force due to
elastic shortening of a pre-tensioned axial member.
Original length of member at transfer of prestress
Length after elastic shortening
Pi
P0
Original length of member at transfer of prestress
Length after elastic shortening
Pi
P0
Figure 2-1.4 Elastic shortening of a pre-tensioned axial member
The loss can be calculated as per Eqn. (2-1.1) by expressing the stress in concrete in
terms of the prestressing force and area of the section as follows.
(2-1.2)
p c
c
i ip
t
f = mf
P= m
A
P Pf = m m
A A
0
Note that the stress in concrete due to the prestressing force after immediate losses
(P0/Ac) can be equated to the stress in the transformed section due to the initialprestress (Pi /At). This is derived below. Further, the transformed area At of the
prestressed member can be approximated to the gross areaA.
The following figure shows that the strain in concrete due to elastic shortening (c) is the
difference between the initial strain in steel (pi) and the residual strain in steel (p0).
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Pi
P0
Length of tendon before stretchingpi
p0 c
Pi
P0
Length of tendon before stretchingpi
p0 c
Figure 2-1.5 Strain variables in elastic shortening
The following equation relates the strain variables.
c=pi- p0 (2-1.3)
The strains can be expressed in terms of the prestressing forces as follows.
c
c c
P =
A E0
(2-1.4)
ipi
p p
P =
A E
(2-1.5)
p
p p
P =
A E0
0
(2-1.6)
Substituting the expressions of the strains in Eqn. (2-1.3)
i
c c p p p p
i
c c p p p p
i
c p p
i
c p c
P PP= -
A E A E A E
P, P + =
A E A E A E
Pm 1P + =
A A A
P P=
A mA + A
0 0
0
0
0
1 1or
or,
or,
0or i
c t
P P=
A A
(2-1.7)
Thus, the stress in concrete due to the prestressing force after immediate losses (P0/A
c)
can be equated to the stress in the transformed section due to the initial prestress (Pi
/At).
The following problem illustrates the calculation of loss due to elastic shortening in an
idealised pre-tensioned railway sleeper.
Example 2-1.1
A prest ressed concrete sleeper produced by pre-tension ing method has a
rectangular cross-section of 300mm 250 mm (b h). It is prestressed with 9
numbers of straight 7mm diameter wires at 0.8 times the ultimate strength of 1570
N/mm2. Estimate the percentage loss of stress due to elastic shortening of
concrete. Considerm = 6.
250
40
300
40
Solution
a) Approximate solution considering gross section
The sectional properties are calculated as follows.
Area of a single wire, Aw = /4 72
= 38.48 mm2
Area of total prestressing steel, Ap = 9 38.48
= 346.32 mm2
Area of concrete section, A = 300 250
= 75 103 mm2
Moment of inertia of section, I = 300 2503/12
= 3.91 108
mm4
Distance of centroid of steel area (CGS) from the soffit,
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( )438.48 250- 40 +538.4840y =
938.48
=115.5 mm
Prestressing force, Pi = 0.8 1570 346.32 N
= 435 kN
Eccentricity of prestressing force,
e = (250/2) 115.5
= 9.5 mm
The stress diagrams due to Piare shown.
Since the wires are distributed above and below the CGC, the losses are calculated for
the top and bottom wires separately.
Stress at level of top wires (y= yt= 125 40)
115.5
e
=+
iP-A
i iP P .e- yA I
iP .e yI
( )
( )3 3
3 8
2
435 10 435 10 9.5= - + 125- 40
7510 3.9110
= -5.8+ 0.9
= -4.9 N/mm
i ic tt
P P .ef = - + y
A I
Stress at level of bottom wires (y= yb = 125 40),
( )
( )3 3
3 8
2
435 10