Coarse aggregates have a great effect on properties of concrete, so gradation of coarse aggregates will always end up giving concretes of different properties. This project is an effort to provide properly detailed information concerning the influence of coarse aggregates grading on properties of concrete. Chippings of sizes 10mm, 20mm and 25mm were selected and used for this work. Preliminary tests like sieve analysis were conducted on the fine aggregate (sand) andalso on the three selected coarse aggregates. 10mm and 25mm coarse aggregates were mixed in various proportions to produce five different concretes. Concrete C1 [100% of 10mm + 0% 25mm coarse aggregates], concrete C2 [75% of 10mm + 25% of 25mm coarse aggregates ], concrete C3 [50% of 10mm + 50% of 25mm coarse aggregates], concrete C4 [25% of 10mm +75% of 25mmcoarse aggregates], and concrete C5 [0% 10mm + 100% 25mm coarse aggregates], Another concrete, [concrete C6] was casted with only 20mm and used as check, as 20mm coarse aggregate is mostly used in construction. In each mixture, slump test was performed and six cubes casted. The cubes were cured in water, and at 7days and 28days the selected cubes were crushed to obtain their compressive strength. After all the crushing it was found that the compressive strength increases as the percentage of 25mm coarse aggregate increases in a mixture, while workability decreases as the percentage of 25mm increases in each mixture. Additionally, the sieve analysis graphs of the fine and coarse aggregates, the slump histogram of the three coarse aggregates and the graph of the concretes' compressive strengths, all went a long way in throwing more light on the properties of all the concretes.

ACI Committee 211.1-91 (1991). Standard Practice for selecting proportion for normal, Heavyweight and Mass Concrete. Detroit, American Concrete Institute.

Aitcin .P, & Mehta. P.(1990). Effect of Coarse Aggregate Characteristics Mechanical Properties of High-Strength Concrete. ACI Materials Journal , 103-107.

Dhir, R. K., McCarthy, M. J., Zhou, S., and Tittle, P. A. J. (2004). Role of cement content and specifications for concrete durability: cement type influences. Structures and Buildings, Institution of Civil Engineers, U.K., 113-127.

Donza, H ., Cabrera, O ., & Irassar, E. (2002). High strength cocrete with different fine aggregate. Cement and Concrete Research. 32 (11), 17551761.

Frankham, W. (1890): Monthly reports by the inspector on materials received at Fort Cautley. New Zealand Defences (unpublished).

Kosmatka, S., Kerkhoff, B., and Panarese, W.C. (2002). Design and control of concrete mixtures, 14th Edition., Portland Cement Association, Skokie, IL, USA.

Lafrenz, J. (1997). Aggregate Grading Control for PCC Pavements Improving Constructability of Concrete Pavements by Assuring Consistency of Mixes. Austin, Texas: Fifth Annual

International Center for Aggregates Research Symposium.

Larrard, F ., & Belloc, A. (1997). Influence of aggregate on the compressive strength of normal and high-strength concrete. ACI Material Journal, 417-426.

McNally, G. (1998). Soil and Rock Construction Materials (First). New York: Rutledge.

Marsh, C.f., (1905), “Reinforced concrete designâ€. Archibald Constable and Company, London.

Mindess, S., Young, J, F., and Darwin, D. (2003). “Concreteâ€. 2nd Edition, Prentice-Hall

Incorporated. Englewood Cliffs, New Jersey.

Mitchell, C.F. (1909). “Components services and finishesâ€. Mitchell’s advanced building

construction. Revised by Denzil Nield. B.T. Batsford, London. Pp. 12-28.

Mehta, K. P., and Monteiro, P. J. M., (1993). “Concrete structure, properties, and materialsâ€.

Second Edition., Prentice Hall incorporated, New Jersey.

Mohammed, M. S ., Salim, Z ., & Said, B. (2010). Effect of content and particle size distribution of coarse aggregate on the compressive strength of concrete. Construction and Building Materials , 24, 505-512.

Montgomery, D.c., Peck, EA., and Vining, G.G., (2001) Introduction to linear Regression, 3rd Edition. John Wiley and Sons, Inc. New York.

Neville, A. M. (1995), Properties of Concrete, 4th Edition. Addisson Wesley Longman, England.

Neville, A ., & Brooks, J. (2010). Concrete Technology (2nd.). London: Prentice Hall.

Ozturan, T., and Cecen, C., (1997), Effect of Coarse Aggregate Type on Mechanical Properties of Concretes with Different Strength, Cement and Concrete Research, Vol 27, Issue 2, Pp 165-170

Popovics, S. (1994). “The Slump Test is useless†Concrete International, Volume 16, Number.9. Pp. 30-33.

Ruiz, W. (1966). Effect of Volume of Aggregate on the Elastic and Inelastic Properties of Concrete. Cornell: Cornell University.

Stensatter, G. A. (1963). Influence of aggregate particle shape upon concrete strength. Bozeman, Montana: Montana State College.

Woode, A ., Amoah, D. K ., Aguba, I. A ., & Ballow, P. (2015). The Effect of Maximum Coarse Aggregate Size on the Compressive Strength of Concrete Produced in Ghana Civil and Environmental Research, 7, 7.

Zhou, F, Barr, B ., & Lydon, F. (1995). Effect of coarse aggregate on the elastic modulus and compressive strength of high performance concrete. Cement and Concrete Research, 177186

Zhou, F ., Barr, B ., & Lydon, F. (1995), Fracture Properties of High Strength Concrete with varying Silica Fume content and aggregates. Cement and Concrete Research , 543-552.

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