Durable concrete

Nano technology in concrete

2011-11-05T07:50:00.000+05:30

Eden Energy reports development of concrete reinforcement using carbon nano-fibers (CNF) and carbon nano-tubes (CNT). The new technology increases the flexural strength of concrete.That will reduced concrete beam dimensions and reduced overall building heights due to thinner floor depths. It can also reduce the amount of steel reinforcement necessary to adequately support structural load leading to reduced project material costs substantially.

Guidelines to select cement for concrete

2009-01-04T16:05:00.003+05:30

GUIDELINES TO SELECT CEMENT FOR CONCRETE

J D Bapat

Concrete is used as a material to build varieties of structures under different surrounding conditions. Here are some guidelines to select appropriate cement or binding material for concrete used for different structural applications.

Sl No	Application	Comments
1	Conventional structural	Select cement for economy
2	Concrete in non-aggressive environment	Any cement as per the Standards. Blends of OPC with GGBS or FA or alternatively PPC or PSC, as per the Standards, have been extensively and successfully used in non-aggressive environment
3	Large placements where temperature rise, due to heat of reaction, is to be kept as low as possible	Best results are likely to be achieved with cements with mineral admixtures contents in excess of 50% GGBS or 25% FA.
4	Structural precast	Choice of cement for precast elements will depend mainly on strength requirements at early ages. High early strengths, without steam curing, will be achieved most economically with cements of strength Grade 43 and higher and with low mineral admixture content. Cements with higher mineral admixture content are better suited to steam curing. Where there is no requirement for rapid strength gain, the choice of cement should be based on economy
5	Precast bricks, blocks and pavers	Provided the elements have sufficient strength to allow handling at an early age, typically the day after casting, the choice of cement should be based on economy.
6	High-performance or High-strength concrete	Strength Grade 43 or higher may be used. The inclusion of about 8% silica fume is common practice in this application. Other mineral admixtures may also be used for durability or economic benefits. Superplasticiser is an essential ingredient in high-performance concrete. The compatibility of the cement/binder material and the Superplasticiser is important and needs to be checked.
7	Reinforced concrete in marine environment	Research and long-term field experience shows that best results in marine environment are obtained, using concrete with cement replacement > 50% by GGBS or FA around 30%
8	Concrete with alkali-reactive aggregates	Cement replacement should be > 40% GGBS or > 20% FA, for alkali-reactive aggregates
9	Concrete exposed to sulphate attack	OPC with 5-8% C₃A possesses good resistance towards sulphate attack. Using high levels of GGBS as cement replacement (above 50%) improves sulphate resistance

Construction chemicals for concrete durability

2009-01-04T14:55:00.005+05:30

CONSTRUCTION CHEMICALS FOR CONCRETE DURABILITY

Dr J D Bapat

The construction chemicals or the chemical admixtures are the ingredients in concrete, other than Portland cement, mineral admixtures, aggregate and water. They are added to concrete immediately before or during mixing. The addition of chemical admixtures modifies the properties of concrete, both in fresh and hardened state.

The effective use of admixtures depends upon the appropriate method of batching and concreting. The chemical admixtures are mostly supplied in ready-to-use liquid form (fraction of solids and density are specified) and are added to concrete at RMC unit or/and jobsite. The admixtures, such as pigments, expansive agents and pumping aids are used in extremely small quantities and usually batched by hand from pre-measured containers.

The effectiveness of an admixture depends on several factors, such as type and amount of cement, water content, mixing time, slump and temperature.

The admixtures are classified according to their function. There are five distinct classes of admixtures: (i) air-entraining, (ii) water-reducing, (iii) retarding, (iv) accelerating and (v) plasticisers (high range water reducing agents (HRWRA) or suerplasticisers). All other varieties of admixtures fall into specialty category, whose functions include corrosion inhibition, shrinkage reduction, alkali-silica reactivity reduction, workability enhancement, bonding, damp proofing and cooling.

The use of air-entraining admixtures (AEA) is not common in India. The AEA stabilises the microscopic air bubbles in concrete, which provide freeze-thaw resistance and improve resistance to deicer salt scaling.

The water-reducing admixtures usually reduce the required water content for a concrete mixture by about 5-10%. Consequently, concrete containing water-reducing admixture needs less water (lower w/c ratio) to reach required slump, than untreated concrete. This usually indicates that higher strength concrete can be produced without increasing the amount of cement.

The retarding admixtures, which slow the setting rate of concrete, are used to counteract the accelerating effect of hot weather on concrete setting. High temperature often causes an increased rate of hardening, which makes placing and finishing difficult. The retarders maintain concrete workability during placement and delay the initial set. Most retarders also function as water reducers and may entrain some air in concrete.

The accelerating admixtures increase the rate of early strength development, reduce the time for curing and protection and speedup the start of finishing operations. The accelerating admixtures are useful to modify the properties of concrete in cold weather.

The superplasticisers, also known as high-range water reducing agents (HRWRA), reduce the water content of concrete by 10-40%. They are added to concrete under two circumstances, (i) to reduce the water-to-cement ratio at the required slump or (ii) to obtain increased slump at the given water-to-cement ratio. The effect of superplasticisers lasts for 30-60 minutes, depending upon the type and the dosage. After that period, the loss of workability is generally rapid. In view of the slump loss, many times it is preferred to add superplastcisers to concrete at the jobsite. The biggest advantage of using superplasicisers is the reduction in water content of concrete. That leads to increased strength and durability of concrete. The use of superplasticisers in concrete offers the following advantages:

(i) Easy pumpability

(ii) Reduced time to achieve stripping strengths for precast products

(iii) Improved pigment dispersion

(iv) Faster placing with fewer site personnel

(v) Optimised cement content

(vi) Increased compressive and flexural strength

(vii) Lower permeability, thus increased water tightness and lower absorption.

(viii) Increased resistance to weathering

(ix) Stronger bond between concrete and reinforcement

(x) Less volume change for wetting and drying

(xi) Reduced shrinkage and cracking

(xii) Improved concrete durability

The commonly used superplasticisers are:

v MLS: Modified Ligno-sulphonates (water reduction up to 10 %)

v SMF: Sulphonated Melamine Formaldehyde Condensate (water reduction up to 25 %)

v SNF: Sulphonated Naphthalene Formaldehyde Condensate (water reduction up to 25 %)

A new generation of superplasticisers belonging to polycarboxylate polymer family, which recently entered the market, namely PCE or the polycarboxylic ethers and acrylic polymers or AP, reduce the water content up to 40 %. They also improve the slump retention characteristics of concrete, thus allowing trouble-free transportation and placement of concrete under difficult conditions at the job site or RMC unit.

The water reduction or slump increase in concrete with the addition of superplasticiser is on account of better dispersion of cement particles in fresh concrete mix. In common superplasticisers (MLS, SMF, SNF), this dispersion effect is caused by the electrostatic repulsion between cement particles negatively charged by the adsorption of superplasticiser on the surface. Whereas in the advanced superplasticisers (PCE), this is caused by the steric repulsion created by the long polymer chains of superplasticiser, in addition the electrostatic repulsion.

The superplasticiser is added to concrete in small quantity (up to 2 % m/m of cement). The specification of superplasticiser used in concrete should conform to the provisions of IS: 9103 and its application to the provisions of IS: 456-2000. The international standards on superplasticisers are ASTM C 494 and EN 934.

The cement-superplasticiser compatibility is defined by the rate at which superplasticised mix consumes water during the first moments after mixing. The compatibility of superplasticiser with cement should be tested before using. The simple empirical test, namely Marsh cone flow time test is commonly performed to measure the compatibility.

Question:

Do you think construction chemicals make concrete durable ?

Using recycled concrete in construction

2009-01-03T15:06:00.003+05:30

USING RECYCLED CONCRETE IN CONSTRUCTION

Dr J D Bapat

The concrete structures which have rendered economic service life are fully / partially demolished for repair or rebuilding. In such cases, large quantity of concrete rubble is required to be disposed off. The recycling of such concrete rubble as an aggregate in new construction is an economic and eco-friendly option. This practice is encouraged and prevalent in many countries. According to one report from the Federal Highway Administration (USA), concrete with recycled concrete aggregate (RCA) performs as good as the concrete with natural coarse aggregate (NCA). The reports on the comparison of strength properties of concrete with NCA and that from RCA show that RCA gives at least two-third of the mechanical properties, namely compressive strength and the elastic modulus in comparison to that with NCA. The plants for production of RCA are similar to those engaged in the production of crushed stone aggregate.

The recycling of concrete is a relatively simple process. It involves breaking, removing and crushing existing concrete into a material with specific size and quality. For example, unprocessed RCA with 50 mm or 37.5 mm size is useful for pavement sub-base. The ACI 555 (2001) gives more information on the subject. The processing of RCA involves removal of reinforcing steel and other embedded materials, contaminants like asphalt, soil, glass, gypsum boards, sealants, plaster, paper, wood and roofing materials. The processed RCA can be used in (a) pavements, shoulders, median barriers, sidewalks, curbs and gutters, bridge foundations, (b) structural grade concrete, (d) soil-cement pavement bases, (d) lean concrete and (e) bituminous concrete.

The crushing characteristics of RCA are similar to those of natural rock and are not significantly affected by the grade and quality of the original concrete. It can be batched, mixed, transported, placed and compacted in the same manner as in conventional concrete.

The use of RCA as coarse aggregate is common but using it as fine aggregate needs more care. The substitution of fine aggregate up to 10-20 % by the RCA is beneficial; optimal rate may be decided by trials.

The water absorption of RCA has been found to be higher due to higher porosity. Therefore it is recommended that RCA be batched in pre-wetted and close- to-saturated surface-dry condition. In order to achieve the same workability, slump and water-to-cement ratio, the paste content (i.e. the amount of cementitious) or the amount of superplasticiser may have to be increased.

It is generally accepted that, when natural sand is used, up to 30 % of NCA can be replaced with RCA, without significantly affecting the mechanical properties of concrete; replacing higher amounts may result in increased drying shrinkage.

With the growing construction activity, the shortage of aggregate is growing, especially in cities. At the same time, concrete waste such as rejected concrete elements and rubble from demolished concrete structures, is also growing at a fast rate, raising ecological and environmental threats. The RCA is a viable alternative to using natural aggregate in concrete, especially in situations where natural aggregate is not locally available or transported over a long distance. Although the processing cost of recycled aggregate is higher in some cases, the situation will change as the natural aggregate becomes scarce.

Question:

Do you think recycling the buildings waste in concrete is proper and effective utilisation of waste ?

Suppliers of construction chemicals in India

2009-01-03T14:33:00.001+05:30

SUPPLIERS OF CONSTRUCTION CHEMICALS IN INDIA

Dr J D Bapat

The following is the list of suppliers of construction chemicals in India. They are organic compounds used as chemical admixtures in concrete. When added as superplasticisers, these chemicals improve water-to-cement ratio or workability of concrete.

Altret Performance Chemicals Gujarat Pvt. Ltd.
Aqua Seal Construction Chemicals
Atul Ltd.
BASF Construction Chemicals (India) Pvt. Ltd.
Beck India Ltd.
Chemistik
Choksey Chemicals Pvt. Ltd.
Chowgule Koster India Construction Chemicals Pvt. Ltd.
Cico Group- India
Concare Chemicals Pvt. Ltd.
Dr Fixit
Excel Admixtures Pvt. Ltd.
Fibrex Construction Chemicals
Fairmate Chemicals Pvt. Ltd.
Fosroc Chemicals (India) Pvt. Ltd.
Greenshield India Construction Chemicals Pvt. Ltd.
Kamsons Chemicals Pvt. Ltd.
MC-Bauchemie (India) Pvt. Ltd.
Perma Construction Aids Pvt. Ltd.
Pinc Group
Polygon Chemicals Pvt. Ltd.
Riddhi Chemicals
Roffe Chemicals
Samrock Murexin
STP Construction Chemicals
Taj Hitech
Tytan Organics
Uclid technology Ltd.
Sika India Pvt. Ltd.

Question:

What do users expect from the suppliers of construction chemicals ?

Books on concrete technology

2009-01-01T21:18:00.004+05:30

Books on concrete technology

Dr J D Bapat

(1) Concrete Technology(3^rd Edition), Author: Gambhir M L, Publisher: Tata Mcgraw Hill Publishing Co Ltd

(2) Concrete Technology Theory & Practice, Author: Shetty M S, Publisher: S Chand & Company Ltd

(3) Concrete Technology, Author: Neville A M, Brooks J J, Publisher: Pearson Education Limited

(4) Concrete Technology, Author: Neville A M, Publisher: Pearson Education India

(5) Laboratory Manual on Concrete Technology, Author: Hemant Sood, Mittal L N, Kulkarni P D, Publisher: Cbs Publishers & Distributors

(6) Concrete Technology, Author: Santhakumar A R, Publisher: Oxford University Press, N Delhi

(7) Textbook Of Concrete Technology, Author: Kulkarni P D, Ghosh R K, Phull Y R, Publisher: New Age International (p) Ltd

(8) Concrete: Microstructure Properties & Matter (CD), Author: Mehta P K, Publisher: Tata Mcgraw Hill Publishing Co Ltd

(9) Precast Concrete: Materials, Manufacture, Properties And Usage, Author: Maurice Levitt, Publisher: Taylor & Francis

(10) Reinforced Concrete Design, Author: Sawhney, Publisher: Macmillan India

(11) Concrete Formwork Systems, Author: Hanna Awad S, Publisher: Marcel Dekker

(12) Design Of Concrete Structures, Author: Arthur H Nilson, David Darwin, Charles W Dolan, Publisher: Tata Mcgraw Hill Publishing Co Ltd

(13) Concrete Technology, Quantity Surveying and Valuation, Author: Gupta and Subhash Chander, Publisher: Jain Publishers, New Delhi

(14) Manual Of Ready-mixed Concrete, Author: Spon, Publisher: Spon E and F

(15) Concrete Admixtures Handbook, Author: V S Ramachandran, Publisher: William Andrew Publishing

(16) Pozzolanic and Cementitious Materials, Author: V Mohan Malhotra, Povindar K Mehta, Publisher: Taylor & Francis

(17) Fly Ash in Concrete: Properties and Performance, Author: Karlhans Wesche, Publisher: Taylor & Francis

(18) Fly Ash in Concrete: Production, Properties and Uses, Author: Ramesh C Joshi, Lohtia, R P, Rajinder P, Publisher: Taylor & Francis

(19) Cement-Based Composites: Materials, Mechanical Properties and Performance, Author: Andrzej Marek Brandt, Publisher: Taylor & Francis

(20) Modern Concrete Materials: Binders, Additions and Admixtures, Author: Ravindra K Dhir, Thomas D Dyer, Publisher: Thomas Telford

(21)Concrete Materials: Properties, Specifications and Testing, Author: Sandor Popovics, Publisher: William Andrew Inc.

(22) Waste Materials Used in Concrete Manufacturing, Author: Satish Chandra, Publisher: William Andrew Inc.

(23) Innovations and Developments in Concrete Materials and Construction, Author: Ravindra K Dhir, P C Hewlett, Laszlo J Csetenyi, Publisher: Thomas Telford

(24) Mineral admixtures in cement and concrete, Editor: Shondeep L Sarkar, Publisher: ABI Books Pvt Ltd, New Delhi

(25) Durability of Concrete Structures: Investigation, Repair, Protection, Author: Geoffrey Mays, Publisher: Taylor & Francis

(26) High Performance Concrete: From Material to Structure, Author: Yves Malier, Publisher: Taylor & Francis

(27) Concrete Technology for a Sustainable Development in the 21st Century, Author: Odd E Gjłrv, Koji Sakai, Publisher: Taylor & Francis

(28) Mineral admixtures in cement and concrete, Editor: S N Ghosh, S L Sarkar, S Harsh, Publisher: ABI Books, Pvt Ltd, New Delhi

(29) Concrete and its chemical behavior, Author: M. S. Eglinton, Publisher: Thomas Telford Ltd

(30) Fundamentals of High-Performance Concrete, Author: Edward G Nawy, Publisher: John Wiley and Sons

(31) High-Performance Concrete, Author: Pierre-Claude Aïtcin, Publisher: Taylor & Francis

Question:

Write a paragraph on the best book you read on the concrete technology

Shrinkage compensating concrete

2008-12-31T17:53:00.001+05:30

SHRINKAGE COMPENSATING CONCRETE

Dr J D Bapat

Shrinkage compensating concrete can be produced using expansive cement or expansive constituents.

The expansive cement, also known as sulfoaluminate cement or modified Portland cement, comes in the category of hydraulic cements that expand slightly during the early hardening period after setting. They meet the requirements of ASTM C 845 in which the group of expansive cement varieties is designated as Type E-1. Expansive cement is used to make shrinkage-compensating concrete that is used to (a) compensate for volume decrease due to drying shrinkage, (b) induce tensile stress in reinforcement and (c) improve dimensional stability of post-tensioned concrete structures. One of the major advantages of using expansive cement is in the control and reduction of drying-shrinkage cracks. In recent years, shrinkage-compensating concrete has been of particular interest in bridge deck construction, where crack development must be minimized. It is also used to minimize cracks in the concrete slabs and structures.

Three types of expansive cement are defined in ASTM C 845.

* Type K: Contains anhydrous calcium aluminate along with calcium sulphate and free lime in Portland cement

* Type M: Contains calcium aluminate along with calcium sulfate in Portland cement

* Type S: Contains tricalcium aluminate along with excess of calcium sulfate in Portland cement

The Type K is more commonly used

Concrete is generally mixed with more water than what is needed to hydrate the cement; that is done to obtain desired workability. After the hydration, i.e. during the process of concrete hardening, remaining water evaporates, causing the concrete to shrink. The amount of shrinkage due to drying depends on the characteristics of the constituent materials, mixture proportions and placing methods. When drying in pavements or structural members is restrained by sub-grade friction, reinforcement or other parts of the structure, drying shrinkage will induce tensile stresses. The tensile stress due to drying shrinkage usually exceeds the concrete tensile strength, which results in cracking. When expansive cement is used in concrete it induces stress, in opposite direction, large enough to compensate for drying shrinkage stress and minimize cracking. When the magnitude of expansion is small but usually adequate to offset the tensile stress (about 0.2 to 0.7 MPa) from restrained drying shrinkage, the concrete is known as Shrinkage Compensating Concrete.

The expansive cement can also be used to produce self-stressing concrete. That is done by restraining the expansion to induce a compressive stress high enough to result in a significant residual compression in the concrete after drying shrinkage has occurred.

Shrinkage-compensating concrete can be produced by using an expansive agent provided that an adequate wet curing, for at least one week, is carried out after demolding. A synergistic effect on the shrinkage reduction is observed, when the shrinkage reducing admixture and the expansive agent are used together.

Some water-reducing admixtures may be incompatible with expansive cement. Fly ash and other pozzolans may affect expansion and may also influence strength development and other physical properties. The air-entraining admixtures are as effective with shrinkage-compensating concrete as with Portland Cement in improving freeze-thaw durability.

The structural properties, namely tensile, flexural, and compressive strength of shrinkage compensating concrete are comparable to those of Portland cement concrete (PCC). Some superplasticisers, when added, do not require concrete to be wet cured, it is claimed.

This ACI Standard Practice, ACI 223, gives details on the use of shrinkage-compensating concrete in structures (reinforced and post-tensioned slabs, both on grade and elevated) and pavements. The recommendations cover proportioning, mixing, placing, finishing, curing, and testing of concrete. The scope of this standard practice is limited to shrinkage-compensating concrete made with expansive cements. The recommendations of this standard practice are not applicable to self-stressing expansive cement concretes proportioned to produce a prestressed concrete structure for load-bearing purposes. Procedures for proportioning, handling, and curing of self-stressing concretes are often radically different from procedures for shrinkage-compensating concretes used to compensate for normal drying shrinkage.

Bibliography:

[1] Standard practice for the use of shrinkage — Compensating concrete (ACI 223) : Published by the American Concrete Institute, Publications Department, P.O. Box 19150, Detroit, Michigan 48129, USA, Jan 1, 1998

[2] Fu Y., Xie P., Gu P., Beaudoin J.J., “ Characteristics of shrinkage compensating expansive cement containing a pre-hydrated high alumina cement-based expansive additive” J. Cement and Concrete Research, Vol. 24, Iss. 2, 1994, pp 267-276

[3] Maltese C., Pistolesi C., Lolli A., Bravo A., Cerulli T., Salvioni D. “ Combined effect of expansive and shrinkage reducing admixtures to obtain stable and durable mortars”, J. Cement and Concrete Research, Vol. 35, Iss. 12, 2005, pp 2244-2251

[4] Nagataki S., Gomi H., “Expansive admixtures (mainly ettringite)”, J. Cement and Concrete Composites, Vol. 20, Iss. 2-3, 1998, pp. 163-170

[5]Collepardi M., Borsoi A., Collepardi S., Olagot J.J.O., Troli R., “Effects of shrinkage reducing admixture in shrinkage compensating concrete under non-wet curing conditions”, J. Cement and Concrete Composites, Vol. 27, Iss. 6, 2005, pp. 704-708

[6] Shuguang H., Yue L., “Research on the hydration, hardening mechanism, and microstructure of high performance expansive concrete”, J. Cement and Concrete Research, Vol. 29, Iss. 7, 1999, pp. 1013-1017

Question:

Give three possible applications of shrinkage compensating concrete

Testing concrete for corrosion resistance

2008-12-31T15:00:00.001+05:30

Testing Concrete for Corrosion Resistance

Dr J D Bapat

The deleterious agents causing corrosion of reinforcement are water, oxygen, carbon dioxide and salts. They reach reinforcement penetrating concrete surface. The concrete mixtures designed for service exposure environments reduce the opportunities for reinforcement corrosion. The resistance of concrete towards corrosion is measured by its resistance towards the penetration of these agents. The rapid test methods provide a fast and reasonable approximation of the corrosion resistance of concrete. Some of the test methods are given as follows.

Rapid Chloride Permeability Test (RCPT), ASTM C1202: This is quick and the most frequently used test. The RCPT is a measurement of the electrical charge that travels between two sides of a concrete specimen over a six-hour period. This charge is correlated to chloride ions passing through the pore system. Lower values signify a higher resistance to chloride intrusion.

A more rapid test for permeability than the RCPT was recently developed by Florida’s Department of Transportation (FDOT 2004). This procedure uses the Werner probe array method for testing resistivity of concrete on 100x200 mm specimens. ACI 222R (2001) also recommends using this method for assessing the permeability of in-place concrete. The results of the electrical resistivity test have been correlated to the RCPT permeability rating system. The surface resistivity is measured in a matter of seconds thereby allowing for a much larger sample size. The Florida standard requires 8 tests each on 3 specimens, while the RCPT can only provide a single test per specimen because of the inherently destructive preparation requirements.

Determining the Apparent Bulk Diffusion Coefficient of Cementitious Mixtures by Bulk Diffusion, ASTM C1556: The ASTM C1556 is a more rigorous method to calculate concrete permeability. Test results from C1556 typically provide lower variability in test results. The test specimens are moist cured for 28 days and later subjected to unidirectional chloride intrusion. The depth of chloride intrusion is measured over time, beginning at 35 days of soaking period. The successive layers from the specimen are ground. The chloride level of each layer is measured using Standard Test Method for Acid-Soluble Chloride in Mortar and Concrete, ASTM C1152,. This procedure gives a direct correlation to the permeability of the concrete and is considered a useful method for prequalification of concrete mixtures. Unfortunately, C1556 is very time consuming and requires about 3 months to complete.

Standard Test Method for Determining the Penetration of Chloride Ion into Concrete by Ponding, ASTM C1543 (AASHTO T259): The test is commonly used by many highway agencies. A concrete slab (test specimen) is cast and moist cured for 14 days and then air cured to 28 days. The top surface is bermed and ponded with a salt solution for 90 days. Cores are then taken from the exposed surface and sliced into approximately half-inch thick discs. Each disc is crushed and the chloride content of each layer is determined. Unfortunately, this test requires almost six months to complete and there is no clear way provided for interpretation of the results in the method. Transport mechanisms in this test also include undefined components of absorption, diffusion and wick action.

Predicting Chloride Penetration of Hydraulic Cement Concrete by the Rapid Migration Procedure, AASHTO TP 64: In this method a 50-mm long, 100-mm diameter concrete sample is saturated using the vacuum saturation procedure of the RCPT. This test ranks multiple concretes in the same order as ASTM C1202, but has the advantage of not being influenced by strongly ionic admixtures, such as calcium nitrite. The specimen does not experience a temperature rise during the test. The test also has been shown to have a somewhat lower variability than the RCPT.

Question:

Discuss possible ways to protect rebars from corrosion

Slag cement for durable structures

2008-12-30T19:14:00.001+05:30

SLAG CEMENT FOR DURABLE STRUCTURES

Dr J D Bapat

The corrosion of reinforcement is the major factor responsible for distress and deterioration of concrete structures under marine conditions. The ingress of chlorides is the principal cause of corrosion; carbonation and sulphate attack are the main factors assisting it. The ground granulated blast furnace slag (GGBS) (like fly ash and silica fume)is a mineral admixture and can be added to the ordinary Portland cement (OPC) , in the cement plant, and marketed as Portland slag cement (PSC) or as an admixture to cement concrete, at the site. The paper reviews the impact of all the three deteriorating factors on the concrete , considering corrosion of reinforcement as principal factor , and the contribution of mineral admixture like GGBS towards improving its durability, under marine conditions. The carbonation depends upon the relative humidity of the environment, permeability of the concrete and the curing conditions. The data on the carbonation of structures available through a number of long term researches carried out world over, on different types of cements, have established that there is no connection between the degree of carbonation and the type of cement. The sodium and the magnesium sulphate, both deleterious to the concrete, are obtained under marine conditions along with high content of chlorides. The deterioration caused due to magnesium sulphate is mainly seen in terms of the reduction in the compressive strength and that due to sodium sulphate in terms of expansion, in the concrete structures. The long term experiments carried out under actual sea water conditions reveal that the concrete with PSC/GGBS has better resistance towards sulphate attack. The refinement of pore structure and the chloride binding capacity of concrete with PSC/GGBS are the principal causes behind the reduced permeability, higher electrical resistance and the resultant higher corrosion resistance and the durability of such concrete under marine conditions.

FAQ:

What are admixtures ?

Admixtures are ingredients other than water, aggregates and hydraulic cement, that are mixed to make concrete. The proper use of admixtures offers certain beneficial effects to concrete, including improved quality, acceleration or retardation of setting time, enhanced frost and sulfate resistance, control of strength development, improved workability and enhanced finishability. It is estimated that 80% of concrete produced in North America these days contains one or more types of admixtures. According to a survey by the National Ready Mix Concrete Association,

USA

, 39% of all ready-mixed concrete producers use fly ash and at least 70% of produced concrete contains a water-reducing admixture. Admixtures vary widely in chemical composition and many perform more than one function. Two basic types of admixtures are available: chemical and mineral. The pulverised fuel ash or fly ash, blast furnace slag or ggbs, silica fume come under the category of mineral admixtures. All admixtures to be used in concrete construction should meet specifications; tests should be performed to evaluate how the admixture will affect the properties of the concrete to be made with the specified job materials, under the anticipated ambient conditions and by the anticipated construction procedures.

Which is the one property of hardened concrete that affects the durability ?

Permeability is the one property that affects the durability of concrete

Is it possible to measure the permeability of concrete, in situ ?

Yes, it is possible to make the in situ measurement, using Concrete Permeability Tester. The equipment measures air permeability and relative humidity of cover concrete on site. A blind hole drilled or formed in the concrete is sealed with a special plug, and the resulting cavity pressurized with air. The permeability of the concrete is calculated from the time taken for the pressure to drop. If the capillary pores are partially blocked with moisture, the permeability is reduced. Therefore the relative humidity of the cavity is also measured.

References:

(1) Bapat J. D., “ Portland slag cement / ggbs for durable structures under marine conditions ” Cement J., Vol. XXXV, No. 1, January 2002, pp 7-18

(2) Bapat J.D., “ GGBS/PSC for concrete structures with corrosion resistance ”, The Masterbuilder, Vol. 4, No. 1, Feb.-Mar. 2002, pp 26-33

(3) Bapat J. D., “ Performance of cement concrete with mineral admixtures ”, J. Adv.Cem.Res. , Vol. 13, No. 4, October 2001, pp 139-155

Question:

How does slag make concrete durable ?