Contents preface (VII) introduction 1—37



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16.8. MASS CONCRETE FOR DAMS
Mass concrete can be defined (6) as any large volume of cast-in-place concrete with dimensions large enough to require measures to cope with the generation of heat and attendant volume change to minimize cracking. Like regular concrete, mass concrete too is primarily composed of cement, aggregate, and water. Additionally, it has pozzolans and other admixtures to improve its characteristics.
Proper proportioning of mass concrete mixture is aimed at: (i) achieving economy, (ii) low temperature-rise potential with adequate workability for placing, and (iii) adequate strength, durability, and impermeability to serve efficiently the structure in which it is used. For this purpose, “low heat” portland cement would always be preferred for massive structures such as dams. Obviously, both economy and low rise in temperature would be achieved by limiting the cement content of mass concrete to as low a value as possible.
Aggregate grading has considerable effect on the workability of concrete. Fine aggregate is defined (6) as aggregate passing No. 4 (4.76 mm) sieve. It may be composed of natural grains, manufactured grains obtained by crushing larger size rock particles, or a mixture of

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the two. Fine aggregate should consist of hard, dense, durable, and uncoated rock fragments, and should not contain harmful grains of clay, silt, dust, mica, organic matter or other impurities to such an extent that they affect adversely the desired properties of concrete.
Coarse aggregate is defined (6) as gravel, crushed gravel, or a crushed rock, or a mixture of these, generally within the range of 4.76 mm to 150 mm in size. Coarse aggregate should also consist of hard, dense, durable, and uncoated rock fragments. Rock which is very fragile or which tends to degrade during processing, transporting, or in storage should be avoided. Further, rocks having an absorption greater than 3 per cent or a specific gravity less than 2.5 are not considered suitable for mass concrete.
The shape of the aggregate particles affects workability and, hence, water requirement. Round particles provide best workability. More than 25 per cent of flat (width-thickness ratio greater than 3) and elongated (length-width ratio greater than 3) particles should not be permitted in each size group.
Water used for preparing mass concrete mix should neither significantly affect the hydration reaction of portland cement nor interfere with the phenomena that are intended to occur during the mixing, placing, and curing of concrete. Water which is suitable for human consumption is acceptable for use in mass concrete.
Pozzolans are used to improve the workability and quality of concrete, to effect economy, and to protect against disruptive expansion caused by the reaction between different constituents of mass concrete. A pozzolan is defined (6) as a siliceous or siliceous and aluminous material which, in itself, possesses little or no cementitious value but will, in finely divided form and in the presence of moisture, chemically react with calcium hydroxide at ordinary temperatures to form compounds possessing cementitious properties. Natural pozzolanic materials occur in the form of obsidian, pumicite, volcanic ashes, tuffs, clays, shales, and diatomaceous earth. Most of these pozzolans require grinding. Fly ash (fuel dust from power plants burning coal) too can be an excellent pozzolan as it has a low carbon content, a fineness about the same as that of portland cement, and occurs in the form of very fine glassy spheres.
Admixtures are generally used to alter the properties of concrete (such as increased workability or reduced water content, acceleration or retardation of setting time, acceleration of strength development, and improved resistance to weather and chemical attacks) to make it more suitable for a particular purpose. For example, calcium chloride can be used to accelerate strength development in mass concrete during winter. Air-entraining admixtures (inexpensive soaps, detergents, etc.) entrain air which greatly improves the workability of concrete and thus permits the use of harsher and more poorly graded aggregates and also those of undesirable shapes.
Mass concrete usually contains low portions of cementing materials, sand and water. Uniformity of batching is, therefore, very essential for achieving the desired level of workability. Since mass concrete is produced on a large scale, the uniformity of batching is easily attained by using the most effective methods and equipment such as (6): (i) finish screening of coarse aggregate at the batching plant, preferably on horizontal screens, (ii) a device for instant reading of approximate moisture content of sand, (iii) refinements in batching equipment such as full-scale springless dials which register all stages of the weighing operation, (iv) automatic weighing and cutoff features, ( v) interlocks to prevent recharging when some material remains in a scale hopper, and (vi) graphic recording of the various weighing and mixing operations.
Mass concrete is best placed in successive layers which should not exceed 45 to 50 cm in thickness with 10 to 15 cm maximum-size aggregate and less than 4 cm slump placed with 3 to



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6 m3 buckets and powerful 15 cm diameter vibrators. Vibration is vital for successful use of efficient, lean, low-slump mass concrete. Mass concrete is best cured with water (for the additional cooling in warm weather) for at least 14 days or up to 28 days if pozzolan is used as one of the cementing materials.


A major problem associated with mass concrete is the probability of high tensile stresses due to generation of heat by the hydration of cement along with subsequent differential cooling. A decrease in temperature of concrete causes volumetric changes resulting in the development of tensile stresses and consequent cracking in the concrete mass. Such cracking in concrete dams is undesirable as it adversely affects their water-tightness, internal stresses, durability, and appearance. Temperature drop is, therefore, controlled by controlling placing temperature, limiting the temperature -rise potential of concrete, controlling lift thickness and placing schedule, and removal of heat through embedded cooling coils. From the considerations of temperature control, the longer interval between successive lifts is preferred provided the ambient temperatures are lower than those of the concrete surfaces while internal temperature is rising. Presently, it is common practice to pre-cool mass concrete before its placement. Best uniformity of mix is attained when maximum use of ice is made for precooling mass concrete.


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