Category Archives: CONCRETE

CONCRETE

Reinforced cement concrete – Working and limit state method

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Reinforced cement concrete is a topic you will need to familiarise at some point, if you are into civil engineering field, agree? Well, if you were surfing on the internet for some fresh knowledge and stumbled on to here, then also welcome! Let’s learn.

What is reinforced cement concrete?

Reinforced cement concrete (RCC), a composite material has been accepted worldwide as a construction material, bridges, retaining walls, docks and harbour, airfield pavements, flyovers,multi-storey building,complexes and simple houses etc.,

Okay. now what is the importance of RCC?

Concrete is good in resisting compression but is very weak in resisting tension. Hence reinforcement is provided in the concrete wherever tensile stress is expected. The best reinforcement is steel since the tensile strength of steel is quite high and the bond between steel and concrete is good. As the elastic modulus of steel is high, for the same extension the force resisted by steel is high compared to concrete.

However in tensile zone, hair cracks in concrete are unavoidable. Reinforcements are usually in the form of mild steel or ribbed steel bars of 6 mm to 32 mm diameter. A cage of reinforcements is prepared as per the design requirements, kept in a formwork and then green concrete is poured. After the concrete hardens, the formwork is removed. The composite material of steel and concrete now called R.C.C. acts as a structural member and can resist tensile as well as compressive stresses very well.

Moving onto more technicalities, let’s sneak into the properties of RCC.

Properties of reinforced cement concrete

The properties of a good RCC are,

  1. It should be capable of resisting expected tensile, compressive, bending and shear forces.
  2. It should not show excessive deflection and spoil serviceability requirement.
  3. There should be proper cover to the reinforcement, so that the corrossion is prevented.
  4. The hair cracks developed should be within the permissible limit.
  5. It is a good fire resistant material.
  6. When it is fresh, it can be moulded to any desired shape and size.
  7. Durability is very good.
  8. R.C.C. structure can be designed to take any load.

Ingredients of RCC

1. Cement

We have seen all the details of cement in previous blogs.

MUST READ: 

Field Test For Cement- A Significant step towards quality 

Properties of Cement- Everything you need to know

Manufacturing process of cement – Wet Process

2. Aggregates

These are the inert or chemically inactive materials which form the bulk of cement concrete. These aggregates are bound together by means of cement.

They can be classified into two. The selection of aggregate is based on the purpose and its maximum size.

a) Fine aggregates

The material which is passed through BIS test sieve no. 480 is called a fine aggregate. River sand is an example.

b) Course aggregates

The material which is retained on BIS test sieve no. 480 is termed as a coarse aggregate. Broken stone is and example.

3. Steel

Steel is used for reinforcement in the form of round bars of mild steel. Diameter of the steel bars used is between 6 mm to 40 mm.

4. Water

Nobody wants a description of what water is, right? Instead, let’s talk about why its significant. Water is an important ingredient because its amount determines the mixing of other ingredients in concrete.

5. Admixtures

Admixtures are ingredients other than above that are added in concrete to give it certain improved qualities or for changing different physical properties in its fresh and hardened stages. The addition of an admixture may improve the concrete with respect to its strength, hardness, workability, water-resisting power, etc.

Uses of reinforced cement concrete

It is a widely used building material. Some of its important uses are,

  1. R.C.C. is used as a structural element, the common structural elements in a building where R.C.C. is used are

(a) footings (b) columns

(c) beams and lintels (d) chajjas, roofs, slabs and

(e)stairs

2. R.C.C. is used for the construction of storage structures like

(a) Water tanks                                  (b) Dams

(c) Bins                                             (d) Silos and bunkers.

3. It is used for the construction of big structures like

(a) Bridges (b) Retaining walls

(c) Docks and harbours (d) Under water structures.

4. It is used for precasting

(a) Railway sleepers (b) Electric poles

5. R.C.C. is used for constructing tall structures like,

(a) Multistorey buildings         (b) Chimneys

(c) Towers

6. It is used for paving,

(a) Roads       (b) Airports

7. R.C.C. is used in building atomic plants to prevent danger of radiation. For this purpose R.C.C. walls built are 1.5 m to 2.0 m thick.

Cool. You have known enough to design RCC. Whom are we waiting for?

Design of reinforced cement concrete

Design of reinforced cement concrete
Design of reinforced cement concrete

A structural member made by two or more different components constructing together is called as composite structure. A reinforced concrete structure belongs to this category.

Methods 1- Working stress method

In this method, behavior of the structure is assumed to act as linearly elastic body under the action of service loads.

Assumptions of working Stress Method

1. At any cross section,plane sections before bending remains plane after bending.

2. All tensile stresses are taken up by reinforcement and none by concrete,except otherwise specially permitted.

3. stress-strain relationship of steel and concrete under working load is a straight line.

4. The modular ratio m has the value 280/3 stress (cbc) is permissible compressive stress due to bending in concrete

Keeping the assumptions in mind, let me break down the procedure of working stress method below.

Steps of working stress method

a) The stresses in an element is obtained from the working loads and compared with permissible stresses.

b) The method follows linear stress-strain behaviour of both the materials.

c) Modular ratio can be used to determine allowable stresses,

d) Ultimate load carrying capacity cannot be predicted accurately.

e) The main drawback of this method is uneconomical.

The figure shows the grade of concrete and proportions of ingredients proposed by working stress method

The figure shows the grade of concrete and proportions of ingredients proposed by working stress method
Grade of concrete and proportions

Advantages of working stress method

  1. Its a simple method
  2. The design results give a large section. Therefore, deflection and cracking is less.
  3. The structure designed using the method gives larger serviceability

Disadvantages of working stress method

  1. This method doesn’t show the real strength of structue. And doesn’t give real factor of safety under failure of structure.
  2. Because of creep, the stress- strain relationship of concrete doesn’t have definite modulous of elasticity

Method- 2 Limit state method

It is the method of designing structures based on statistical concept of safety and the associated statistical probability of failure.

The structures designed should satisfy the dual criteria which are safety and serviceability.

a). Safety

It can be defined as an acceptable degree of security against complete collapse. Or, the failure the concrete structure can occur by various modes such as compression, tension, flexure, torsion, shear.

b). Serviceability

The intended structure shouldn’t deteriorate to such an extend that if fails to fullfils the function for which its built. In concrete structure, the state can be reached due to excessive deflection, cracking, vibration, corrosion of reinforcement etc.

The steps in limit state of design

a) The stresses are obtained from design loads and compared with design strength.

b) In this method,it follows linear strain relationship but not linear stress relationship.

c) The ultimate stresses of materials itself are used as allowable stresses.

d) It shall also statisfy the serviceability requirements,such as limitations on deflection and cracking

Reinforced cement concrete books

The important books for clearing all your doubts regarding RCC are,

  1. B.C. Punmia, R.C.C Designs, 2012
  2. S. Pillai, Reinforced concrete designs, 1988
  3. P.C. Varghese, Advanced reinforced concrete design, 2004
  4. B.C. Punmia, Limit state design of reinforced concrete, 2007
  5. S.S. Bhavikatti, Advance R.C.C. design, 2006
  6. Murari Lal Gambhir, Design of reinforced concrete structures, 2008

You may note that other important authors are Unnikrishnan Pillai & Devdas Menon, V.L.Shah & S.R.Karve ( Local publication in Pune), P. Dayaratnam, R.Ramamutham and N. Krishnaraju.

Also you can refer NPTEL lectures and notes which are available in internet.

That’s it about RCC.

Continue reading! Because it makes life joyful.

MUST READ: Quality tests to be done on concrete – Slump Test

CONCRETE

Quality Tests on Concrete-Slump test

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<p value="<amp-fit-text layout="fixed-height" min-font-size="6" max-font-size="72" height="80"><strong><span class="has-inline-color has-vivid-red-color">WHAT DO YOU MEAN BY CONCRETE?</span></strong>WHAT DO YOU MEAN BY CONCRETE?

<p class="has-text-align-justify" style="font-size:17px" value="<amp-fit-text layout="fixed-height" min-font-size="6" max-font-size="72" height="80"><strong>Concrete </strong>is a composite material, which is produced from a mixture of cement, aggregates (coarse & fine), water and sometimes admixtures in required proportions. These mixture consolidates in course of time to form a dense mass called concrete.Concrete is a composite material, which is produced from a mixture of cement, aggregates (coarse & fine), water and sometimes admixtures in required proportions. These mixture consolidates in course of time to form a dense mass called concrete.

INGREDIENTS OF CONCRETE

a) CEMENT

b) COARSE AGGREGATE

c) FINE AGGREGATE

d) WATER

e) ADMIXTURE

f ) AIR

WHY QUALITY CONTROL OF CONCRETE IS IMPORTANT ?

<p class="has-text-align-justify" style="font-size:17px" value="<amp-fit-text layout="fixed-height" min-font-size="6" max-font-size="72" height="80">Concrete is designed for a particular strength and the total structural stability is dependent on a good quality concrete. and that is why quality control is one of the most important aspects taken into account during the production of concrete . A little variation in water to cement ratio, ingredient proportioning, increase in slump etc will have a major impact on the desired strength of the structure which in turn affects the structural stability.Concrete is designed for a particular strength and the total structural stability is dependent on a good quality concrete. and that is why quality control is one of the most important aspects taken into account during the production of concrete . A little variation in water to cement ratio, ingredient proportioning, increase in slump etc will have a major impact on the desired strength of the structure which in turn affects the structural stability.

The quality control of concrete is done in three stages

a) Production stage ( On fresh concrete before placing)

b) Hardened stage ( hardened concrete specimens)

c) On structures ( tests done on the structures )

TESTS TO BE DONE ON FRESH CONCRETE

a) SLUMP TEST

b) Compaction Factor test

c) Vee- Bee Test

d) k slump test

e) Kelly ball test

f ) Flow table test

TESTS TO BE DONE ON HARDENED CONCRETE

a) COMPRESSIVE STRENGTH TEST (CUBE TEST)

b) WATER PERMEABILITY TEST

c) WATER ABSORPTION TEST

NON DESTRUCTIVE TESTS ON STRUCTURES

a) REBOUND HAMMER

b) UPV TEST

CONCRETE CORE TEST

SLUMP TEST

WHAT IS A SLUMP TEST?

Slump cone test is to determine the workability or consistency of a concrete mix prepared at the laboratory . Slump test shall be done on fresh concrete immediately after production at the batching plant to ensure the workability is in line with the design mix requirements and also at the pour point immediately after releasing from the transit mixture.

HOW DO YOU DO A SLUMP TEST (AS PER IS 1199:1959 REAFFIRMED 2013)

The nominal size of the aggregate shall be less than 38 mm . The cone has 20cm bottom diameter and 10 cm top diameter. The height of the cone is 30 mm. It consists of a 16 mm tamping rod having a length of 600 mm

The mould shall be filled in four layers, each approximately one-quarter of the height of the mould. Each layer shall be tamped with twenty-five strokes of the rounded end of the tamping rod. The cone is removed gently and the decrease in the height of concrete is the slump of concrete.

The slump tolerance shall be +/- 25 mm . If a design mix recommends a slump of 100 mm it cant go beyond 125 mm and go below 75 mm.

Also read

COMPACTION FACTOR TEST

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CONCRETE

READY MIX CONCRETE-OVERVIEW

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READY MIX CONCRETE (RMC)

PLACING OF READY MIX CONCRETE
PLACING OF READY MIX CONCRETE

Concrete is the most widely used building material in the world. Concrete is perfectly inert, and has exceptional durability without the need for special maintenance.Concrete is basically a mixture of Portland Cement, water and aggregates comprising sand and gravel or crushed stone. In traditional construction sites, each of these materials is procured separately and mixed in specified proportions at site to make concrete.
Ready mix concrete refers to a concrete manufactured from a batching plant according to customer/clients requirements & approved Design Mix and conveyed to the site in a ready to use condition. The concrete is conveyed through transit mixers of capacity ranging from 3 cum to 10 cum and more. 6 cum trucks are most commonly used. Batching plants are available in a wide range of capacities and types. ranging from 10 cum per hour to 125 cum/hr and some manufactures have much higher capacity plants.Most commonly used capacities are 30 cum, and 60 cum.

MAJOR CONSUMERS OF READY MIX CONCRETE

a) BIG CONSTRUCTION COMPANIES

They have there own batching plant set up along with expertise for installation, operation and maintaining it. These are used for there own use in construction sites depending on the feasibility in terms of space,quantity and economy.These plants are site specific and no commercial selling may not be permitted.

b) COMMERCIAL RMC SUPPLIERS

They setup there own plant in a specified location with all arrangements for stocking raw materials and commercially manufacture the materials as per customer/ client requirements.

COMMON METHODS USED FOR CONVEYING RMC

a) Transit mixed or truck mixed concrete

b) Shrink mixed concrete

c) Central mixed concrete.

a) Transit mixed concrete

The materials are batched at a central plant and are thoroughly mixed in the truck in transition. Transit-mixing separate water from the cement and aggregates and allows the concrete to be mixed instantly before using at the job site, Frequently partial mixing happens in transit and remaining mixing shall be done at site just before casting. This avoids slump loss, segregation, premature hardening, delays due to traffic jams, pouring delays due to equipment failure etc. The main disadvantage is the truck capacity is less compared to the one carrying fully mixed RMC.

b) Shrink mixed concrete

In shrink-mixed concrete, concrete is partially mixed at the plant to reduce or shrink the volume of the mixture and mixing is completed in transit or at the jobsite. The disadvantage is that concrete that has been remixed tends to set more rapidly than concrete mixed only once.

c) Central mixed concrete

The concrete is batched and completely mixed in a stationary mixer at the plant site before discharging it into the truck mixers. This can enhance the quality of concrete and cater higher production requirements.

HOW RMC IS MANUFACTURED

Ready mix concrete is manufactured from a centralised plant having facilities for storage of raw materials, Lab for inspection of raw material quality and concrete quality, having a series of batching plant/plants of different capacities etc.

RMC PLANT
RMC PLANT

The raw materials are checked to ensure compliance with relevant Indian standards so that there shall no be any quality issues to the end product. The raw materials are stored in separate areas on a firm ground. The RMC plant uses there In house design mixes most to the time. Customisation can also be done with the help of quality engineers. The design mixes are done in a way to give maximum quality with economy.

RAW MATERIAL BIN OF RMC PLANT
RAW MATERIAL BIN OF RMC PLANT

The running time, distance covered, initial settling time, slump etc are controlled using addition of special admixtures(mineral and chemical) etc without hampering the concrete strength. RMC is a totally controlled concrete having high work efficiency.

The raw materials stored shall be conveyed to the mixing drum using conveyor belts or bucket elevator. Cement is stored in silos also are conveyed using screw conveyors attached to the batching plants.

VIDEO SHOWING THE MIXING METHOD OF RMC

Once  the weight of all material types meets the needs of specific amounts,  the door of the weighing hopper is opened automatically. The materials  will then be mixed by a concrete mixer. Once the setting time is over,  the loading door of the concrete mixer opens and the concrete flows into  a transit mixer.

WHAT ARE THE ADVANTAGES OF READ MIX CONCRETE

a) Uses the updated technology in proportioning, mixing and conveying and hence RMC plants can maintain excellent quality.

b) Transportation and placing is very easy. Once the concrete transit mixers reaches site concrete placing can commence immediately through concrete pumps, concrete buckets or boom placers.

c) As the concrete production and mixing is done in another place the site will be free form noise and dust pollution and free from raw material and cement trucks.

d) By using RMC the construction speed can be enhanced and schedule delays can be avoided upto an extent.

c) The concrete produced from RMC plants can be customised as per the client/ customer requirements.

d) RMC plants are a great relief when the site do not have sufficient spaces for stocking of raw materials and locating a batching plant with its raw material bins. RMC plants can cater any quantity of concrete starting from small residences to big construction sites.

e) Onsite wastage of raw materials and concrete can be eliminated by using Ready mix concrete.

d) Labour required for production of concrete and manpower for operation and running of batching plant & its associated machinery can be eliminated .

WHAT ARE THE DISADVANTAGES OF RMC

a) Requires huge investment to set an RMC plant.

b) Labour force shall be ready to place the concrete as and when it comes

c) Unforeseen delays and traffic jam leads to concrete rejection.

d) A very efficient and effective transporting system has to be maintained.

e) Quality has to be checked at site as per is standards on fresh concrete and also on hardened specimen.

f) Very effective quality system to be maintained for adjusting the setting time and slump according to the time of transit.

g) For residential construction the customer may not get a better idea of the quality of concrete due to lack of site testing facilities.

h) There are problems due to discrepancies in quantities which cant be convinced properly to the RMC vendors.

CONCRETE, PRESTRESSED CONCRETE

Prestressing methods in Prestressed Concrete – Types and methodology

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The prestressing in Prestressed concrete is done by inducing predetermined compressive stresses to concrete by tensioning the steel, before subjecting it to service loads. In prestressed Concrete the stress developed during the service stage is countered by the already induced compressive stresses. Prestressing is a combination of the high-strength compressive properties of concrete with the high tensile strength of steel. This article is about prestressing in prestressed concrete, different methods of prestressing, and how prestressing works.

Prestressing in prestressed concrete is a critical technique that enhances the strength and durability of structures. The concrete is reinforced against tensile forces by carefully applying pre-determined compressive stresses. This is done through methods like post-tensioning. This approach ensures that prestressed concrete elements maintain their structural integrity over time. This article will cover the fundamentals of prestressing, including key methods and their applications in construction.

  1. Prestressing in Prestressed concrete
    1. Plain Cement Concrete Beam on Loads
    2. Reinforced Cement Concrete beam on loads
  2. Significance of Prestressed Concrete
    1. Ultimate strength
    2. Serviceability
    3. Deflection of steel structures
  3. Prestressed Concrete
  4. SOME STRUCTURES USING PRESTRESSED CONCRETE
  5. Prestressed Concrete – How it works
  6. Principle of Prestressed Concrete
  7. Method of Prestressed Concrete
    1. Pre tensioning Method
    2. Post-Tensioning Method
  8. Comparison between Post- tensioning and pre-tensioning process
  9. What are tendons?
  10. Key Takeaways
  11. Conclusion

Prestressing in Prestressed concrete

Concrete got excellent properties, making them the most preferred material for structural members, but has its weakness too. Let us consider two cases where a concrete beam is subjected to loads.

  • CASE 1 ( PLAIN CEMENT CONCRETE BEAM ON LOADS)
  • CASE 2 (REINFORCEMENT CEMENT CONCRETE ON LOADS)

Plain Cement Concrete Beam on Loads

Let us consider a Plain Cement Concrete (PCC) beam subjected to loads as shown in Fig. The beam bends and cracks are developed in the tensile zone. This confirms that the concrete is very weak in tension and strong in compression.

Beam subjected to loads
Beam subjected to loads

Reinforced Cement Concrete beam on loads

Consider a reinforced Cement Concrete beam subjected to loads as shown in fig. In this case, the beam will not bend or cracks. This is due to the presence of reinforcement steel in the tensile zone. The reinforcement steel takes care of the tensile loads and prevents the member from cracking.

RCC beam subjected to loads
RCC beam subjected to loads

In this case, the RCC beam with steel behaves as a composite member. Concrete’s poor tensile strength and ductility are countered by the reinforcement steel having high tensile strength and ductility.

Significance of Prestressed Concrete

Even though concrete owes the property of good compressive strength, it has the following disadvantages.

Prestressed concrete, achieved through techniques like post-tensioning and pre-tensioning ways, are crucial for enhancing structural performance. By inducing compressive stresses, it counters tensile forces, reducing cracking and increasing load-bearing capacity. This approach allows for longer spans. It also allows for thinner sections and greater durability in construction. This makes it ideal for bridges, high-rise buildings, and other demanding applications.

  • Tensile strength is weak
  • Brittle
  • Non ductile

A good designer anticipates the areas of failure and designs the structure to overcome them. The design developed through this method is optimised.
The Design is based on Design criteria ( Goal of the design). Each design should satisfy the design criteria of ultimate strength and Serviceability.

Let us go through the details of Ultimate strength and Serviceability

Ultimate strength

In this design Criteria, the structures are designed on ultimate strength and will not collapse even in the worst condition. For example, if the proposed structure for a bridge can handle a load of traffic without a collapse. Then it satisfies the Design criteria of ultimate strength.

Serviceability

The structures are to be checked for serviceability conditions like stability analysis, deflection checks, etc. In the service stage if the structure tends to deflect on moments, then the serviceability criteria is not satisfied.

Let us analysis the impact of service loads on RCC structure like a bridge.

Deflection of steel structures

Deflection On Service loads
Deflection On Service loads

The figure presents what happens when an RCC structure is subjected to service loads. The moments cause the structure to deflect. The ductile reinforcement elongates to negotiate the loads. However concrete with poor tensile strength fails on tensile loads and develops cracks.

Beam subjected to loads
Beam subjected to loads
Cracks developed on deflection
Cracks developed on deflection

The cracks absorb moisture and gradually rust the reinforcement steel. This leads to spalling of concrete and initiates an ultimate collapse of the structure.
Prestressed concrete is introduced to minimise deflection cracks, for increasing the strength of members. Prestressing gives the designers, the flexibility of optimising the design while negotiating large spans.

Prestressed Concrete

Prestressing is a method of inducing Compressive stress into a structural member. This is done by tensioning the steel before subjecting it to service loads.

This process, known as prestressing, enhances the concrete’s ability to withstand tensile forces, reducing cracking and improving load-bearing capacity. Prestressed concrete combines high-strength steel reinforcement with concrete’s compressive strength. This combination enables the construction of structures with longer spans. It also allows for thinner sections and increased durability.

Prestressing is adopted for structures like bridges,large spanned auditoriums, silos, reservoirspile foundationsprefabricated elements etc.

Prestressed Concrete
Prestressed Concrete

SOME STRUCTURES USING PRESTRESSED CONCRETE

Prestressing in Prestressed Concrete
Prestressing in Prestressed Concrete

Prestressed Concrete – How it works

The figure below explains how an RCC member subjected to loads deflects and gets cracked

Deflection and cracks on service loads
Deflection and cracks on service loads

Principle of Prestressed Concrete

In prestressed concrete, the steel/tendons are stretched along the axis before pouring concrete as shown in fig.
The tendons are released once the concrete reaches the desired strength. On detaching, the tendons induce compressive stresses in the structural member.

Mechanism of Prestressed Concrete
Mechanism of Prestressed Concrete

The compressive stress is induced in the structural member on releasing the tensioned steel. It counterbalances the compression that arises due to loads applied in the service stage. In prestressed concrete, tensioning of steel initiates negative deflections in the member. These defections balance the compressive stress due to service loads and prevent the concrete from cracking.

Prestressed bridge on service loads
Prestressed bridge on service loads

Prestressing method provides the designers with the much-needed flexibility in designing large spanned structures. Whereas deriving economical and optimised designs in RCC seems difficult.

Method of Prestressed Concrete

Prestressing is done in two methods

  • Pre-tensioning Method
  • Post – tensioning Method

Pre tensioning Method

In Pre tensioning method, the tendons are stretched before pouring the concrete. Once the concrete attains the desired strength the tendons are released. After releasing the tendon the structure is subjected to service loads.
The High-strength steel tendons are placed between two abutments/buttress. The tendons are stretched around 70% of their ultimate strength or as per design requirements. Concrete is poured with Tendons kept stretched. The tendons are released once the concrete attains its desired strength. On release, the steel tries to regain its original length due to its high ductility. During this process, the tensile stress in steel is converted to compressive stress in concrete. This conversion initiates a negative deflection. These compressive stresses induced in the structural member counters the compressive stress in the service stage.

Post tensioning process

The post-tensioning method is for precast girders of bridge spans, metro lines, and flyovers. It is also used for railway sleepers, piles, and prefabricated elements. These elements are subjected to heavy loads. The structures are prestressed in the prestressing yards, conveyed, and lifted for erection at the site.

The post-tensioned structures have size limitations. They have to be carried from the fabrication yard to the site. They are then erected at the site.

Post-Tensioning Method

In the post-tensioning method tendons are tensioned, once the concrete attains design strength. For this purpose, ducts or profiles are strategically placed within the concrete during casting.

Once the concrete hardens and attains design strength, the tendons are inserted through the already placed ducts or profiles. The tendons are tensioned using jacks as per design requirements. On completion of post-tensioning works, the structure is released for service loads.

Post tensioning Method
Post tensioning Method

In bonded type post-tensioning, the tendons are grouted with special grouts after tensioning. In unbounded type, tendon grouting is not necessary.

Post-tensioning is done at the site and not in the fabrication yard like a pre-tensioning system. The post-tensioning method is used in viaducts, segmental construction of large bridge spans, large slabs, reservoirs, big silos of cement plants, coal washeries, etc

Comparison between Post- tensioning and pre-tensioning process

AspectPost-TensioningPre-Tensioning
DefinitionPrestressing method where steel cables are tensioned after concrete has set.Prestressing method where steel cables are tensioned before concrete is poured.
ApplicationCommonly used in large-scale projects like bridges and high-rise buildings.Typically used in precast concrete elements like beams and slabs.
ProcessCables are placed in ducts, which are then tensioned after the concrete cures.Cables are tensioned before the concrete is cast around them.
Construction TimeLonger, as tensioning occurs after curing.Shorter, as tensioning is completed before casting.
FlexibilityAllows for adjustments in cable tension during construction.Less flexibility, as tensioning is fixed before casting.
MaintenanceEasier to inspect and maintain the tensioned cables.More challenging to inspect as cables are embedded in the concrete.
CostHigher due to the need for additional equipment and labor.Typically lower due to simpler setup and fewer materials.

This comparison highlights the key differences between post-tensioning and pre-tensioning in prestressed concrete applications.

What are tendons?

Tendons consist of single wires, multi-wire strands, or threaded bars. These are most commonly made from high-tensile steels, carbon fiber, or aramid fiber.

Tendons are high-strength steel cables or rods used in prestressing concrete to enhance its structural performance. In prestressed concrete, tendons are either pre-tensioned before the concrete is poured or post-tensioned after curing. During post-tensioning, tendons are threaded through ducts. They are then tensioned to apply compressive stresses to the concrete. This process improves its load-bearing capacity and reduces cracking.

Key Takeaways

  1. Prestressing Methods: Two primary methods, pre-tensioning and post-tensioning, enhance concrete’s performance. Pre-tensioning involves tensioning tendons before pouring concrete, while post-tensioning occurs after the concrete has cured.
  2. Benefits: Prestressed concrete combines high-strength steel with concrete’s compressive strength, leading to longer spans, thinner sections, and greater durability.
  3. Applications: These ways are crucial in structures requiring high load-bearing capacity and durability. Examples include bridges, high-rise buildings, and large spans.
  4. Tendons: Tendons are made of high-tensile steel or other materials. They are central to prestressing. The tendons provide the necessary compressive stresses to counteract tensile forces.

Conclusion

Prestressing in concrete is vital for optimizing structural performance by introducing compressive stresses to counteract tensile forces. Both pre-tensioning and post-tensioning methods effectively enhance the concrete’s strength and durability. Pre-tensioning is used before casting, while post-tensioning is applied after curing. These techniques are instrumental in building efficient, long-lasting structures like bridges and high-rise buildings. Understanding and implementing these methods ensure the structural integrity and longevity of prestressed concrete elements in various demanding applications.