PSC Lecture PPT.pdf

1. PSC 01-INTRODUCTION PRESTRESSED CONCRETE STRUCTURES Definition of Pre-stress Internal stresses are induced in a member to counteract the external stresses which are developed due to the external loads or service loads

2. Concept: Prestressed concrete is basically concrete in which internal stresses of a suitable magnitude and distribution are introduced so that the stresses resulting from the external loads are counteracted to a desired degree. Terminology 1. Tendon: A stretched element used in a concrete member of structure to impart prestress to the concrete.

3. 2. Anchorage: A device generally used to enable the tendon to impart and maintain prestress in concrete.

5. 3. Pretensioning: A method of prestressingconcrete in which the tendons are tensioned before the concrete is placed. In this method, the concrete is introduced by bond between steel & concrete. 4. Post-tensioning: A method of prestressingconcrete by tensioning the tendons against hardened concrete. In this method, the prestress is imparted to concrete by bearing. Materials for prestress concrete members Materials for prestress concrete members Cement: The cement used should be any of the following •Ordinary Portland cement conforming to IS269 •Portland slag cement conforming to IS455. But the slag content should not be more than 50%. •Rapid hardening Portland cement conforming to IS8041. •High strength ordinary Portland cement conforming to IS8112.

6. Concrete: •Prestress concrete requires concrete, which has a high compressive strength reasonably early age with comparatively higher tensile strength than ordinary concrete. •The concrete for the members shall be air-entrained concrete composed of Portland cement, fine and coarse aggregates, admixtures and water. •The air-entraining feature may be obtained by the use of either air- entraining Portland cement or an approved air-entraining admixture. entraining Portland cement or an approved air-entraining admixture. The entrained air content shall be not less than 4 percent or more than 6 percent. •Minimum cement content of 300 to 360 kg/m3 is prescribed for the durability requirement. •The water content should be as low as possible

7. Steel •High tensile steel , tendons , strands or cables The steel used in prestress shall be any one of the following:- •Plain hard-drawn steel wire conforming to IS1785 (Part-I & Part-III) •Cold drawn indented wire conforming to IS6003 •High tensile steel wire bar conforming to IS2090 •Uncoated stress relived strand conforming to IS6006 Durability, Fire Resistance & Cover Requirements For Durability, Fire Resistance & Cover Requirements For P.S.C Members:- According to IS: 1343-1980 •20 mm cover for pretensioned members •30 mm or size of the cable which ever is bigger for post tensioned members. •If the prestress members are exposed to an aggressive environment, these covers are increased by another 10 mm.

8. Necessity of high grade of concrete & steel •Higher the grade of concrete higher the bond strength which is vital in pretensioned concrete, Also higher bearing strength which is vital in post-tensioned concrete. •Generally minimum M30 grade concrete is used for post-tensioned & M40 grade concrete is used for pretensionedmembers History and development of prestress History and development of prestress

9. 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 prestressingstrand. •Tendon: A group of strands or wires are wound to form a prestressingtendon. •Cable: A group of tendons form a prestressingcable. •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. bar is much larger than that of a wire. Bonded tendon When there is adequate bond between the prestressingtendon and concrete, it is called a bonded tendon. Pre-tensioned and grouted post- tensioned tendons are bonded tendons. Unbondedtendon When there is no bond between the prestressingtendon and concrete, it is called unbondedtendon. When grout is not applied after post- tensioning, the tendon is an unbondedtendon.

10. 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. 3) Final: It can be subdivided into two stages. a) At service, during operation. b) At ultimate, during extreme events. Advantages of Prestressing •Section remains uncracked under service loads •High span-to-depth ratios •Suitable for precast construction

11. Limitations of Prestressing •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 equipment. • There is need for quality control and inspection. Types of Prestressing External or internal prestressing External or internal prestressing Pre-tensioning or post-tensioning Linear prestressing Circular pre stressing Full, limited or partial prestressing Uniaxial, biaxial or multi-axial prestressing

12. Differences of Prestressed Concrete Over Reinforced Concrete In prestress concrete member steel plays active role. The stress in steel prevails whether external load is there or not. But in R.C.C., steel plays a passive role. The stress in steel in R.C.C members depends upon the external loads. i.e., no external load, no stress in steel. Source of Prestressing Force •Hydraulic Prestressing •Electrical Prestressing •Mechanical Prestressing external loads. i.e., no external load, no stress in steel. In prestress concrete the stresses in steel is almost constant where as in R.C.C the stress in steel is variable with the lever arm. concrete has more shear resistance, where as shear resistance of R.C.C is less. In prestress concrete members, deflections are less In prestress concrete fatigue resistance is more compare to R.C.C In prestress concrete dimensions are less because external stresses are counterbalance by the internal stress induced by prestress

13. Pre-tensioning Systems and Devices Introduction Stages of Pre-tensioning Advantages of Pre-tensioning Disadvantages of Pre-tensioning Devices Manufacturing of Pre-tensioned Railway Sleepers Manufacturing of Pre-tensioned Railway Sleepers Introduction There are general guidelines of prestressing in Section 12 of IS:1343 - 1980. In pre-tensioning, the tension is applied to the tendons before casting of the concrete. The stages of pre-tensioning are described next.

14. 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 Once the concrete attains the desired strength for prestressing, the tendons are cut loose from the abutments. 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).

15. The various stages of the pre-tensioning operation are summarized 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.

17. 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. Disadvantages of Pre-tensioning The relative disadvantages are as follows. • A prestressing bed is required for the pre-tensioning operation. • 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.

18. Devices The essential devices for pre-tensioning are as follows. • Prestressing bed • End abutments • Shuttering / mould • Jack • Anchoring device • Anchoring device • Harping device (optional)

19. Prestressing Bed, End Abutments 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 between the members. This system is also called the Long Line Method.

20. The end abutments have to be sufficiently stiff and have good foundations This is usually an expensive proposition, particularly when large prestressing forces are required 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. equilibrating systems. This is a common solution in load-testing. Typically, this is done by means of a ‘tension frame’.

21. 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. 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. Free body diagram by replacing the jacks with the applied forces

22. 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 Pascal’s 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.

23. Anchoring Devices 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.

24. 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.

25. Manufacturing of Pre-tensioned Railway Sleepers 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 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. 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.

29. Post-tensioning Systems and Devices Introduction There are general guidelines of prestressing in Section 12 of IS 1343: 1980. The information given in this section is introductory in nature, with emphasis on the basic concepts of the systems. In post-tensioning, the tension is applied to the tendons after hardening of the concrete. hardening of the concrete.

30. 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. Stages of Post-tensioning Unlike pre-tensioning, the tendons are pulled with the reaction acting against the hardened concrete. 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.

31. 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 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.

33. 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. 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-equilibrating forces develops after the stretching of the tendons.

35. 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. • The transfer of prestress is independent of transmission length. Disadvantage of Post-tensioning The relative disadvantage of post-tensioning as compared to pre- tensioning is the requirement of anchorage device and grouting equipment.

36. Devices The essential devices for post-tensioning are as follows. 1) Casting bed 2) Mould/Shuttering 3) Ducts 4) Anchoring devices 4) Anchoring devices 5) Jacks 6) Couplers (optional) 7) Grouting equipment (optional).

37. Casting Bed, Mould and Ducts The following figure shows the devices.

38. Anchoring 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 3) Looping the wires

39. 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.

40. Direct bearing The rivet or bolt heads or button heads formed at the end of the wires 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 are based on this principle. The following figure shows the anchoring by direct bearing.

41. 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. The wires are looped to make a bulb. The following photo shows the anchorage by looping of the wires in a post-tensioned slab.

42. Sequence of Anchoring

43. Jacks

44. 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 transmit the full capacity of the strands or bars. A few types of couplers are shown.

45. Grouting Grouting 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 between the 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 shows a grouting equipment, where the ingredients are mixed and the grout is pumped.

46. Manufacturing of Post-tensioned Bridge Girders

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