Authors: Kazeem K. Adewole, Festus. A. Olutoge, Hamzat Habib

Abstract:

In this paper, the effect of grades 32.4 and 42.5 Portland-limestone cements generally used for concrete production in Nigeria on concrete compressive strength is investigated. Investigation revealed that the compressive strength of concrete produced with Portland-limestone cement grade 42.5 is generally higher than that produced with cement grade 32.5. The percentage difference between the compressive strengths of the concrete cubes produced with Portland-limestone cement grades 42.5 and 32.5 is inversely proportional to the richness of the concrete with the highest and the least percentage difference associated with the 1:2:4 and 1:1:2 mix ratios respectively. It is recommended that cement grade 42.5 be preferred for construction in Nigeria as this will lead to the construction of stronger concrete structures, which will reduce the incidence of failure of building and other concrete structures at no additional cost since the cost of both cement grades are the same.

Keywords: Cement grades, Concrete, Compressive strength, Portland-limestone cement, Ordinary Portland cement.

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1099438

Procedia APA BibTeX Chicago EndNote Harvard JSON MLA RIS XML ISO 690 PDF Downloads 4190

References:

[1] T. R Naik, “Practice periodical on structural design and construction, ASCE, pages 98-103, 2008.
[2] Raw Polymers Ltd – Cement division, http://www.ordinaryportlandcement.com/portlandcement-grades/, accessed on the 19/01/2014.
[3] NIS 444-1:2003. Composition, specification and conformity criteria for common cements. Standards Organisation of Nigeria.
[4] NIS 11: 1974: Specification for ordinary Portland cement, Standards Organisation of Nigeria.
[5] NIS 439:2000. Standard for cement. Standards Organisation of Nigeria.
[6] BS EN 197-1:2011. Cement Part 1: Composition, specifications and conformity criteria for common cements, British Standards Institute.
[7] P. Hawkins, P. D. Tennis and R. J. Detwiler, “The Use of Limestone in Portland Cement: A State-of-the-Art Review”, Portland Cement Association, Skokie, Illinois, USA, 2003.
[8] Lafarge Cement UK Limited, Portland limestone cement, 2002. http://www.lafarge.co.uk/CementDatasheet/Portland%20Limestone%20 Cement.pdf, accessed on 24/04/2012.
[9] C. Emiero, O. J. Oyedepo, “An Investigation on the Strength and Workability of Concrete Using Palm Kernel Shell and Palm Kernel Fibre as a Coarse Aggregate”, International Journal of Scientific & Engineering Research vol 3, Issue 4, pages 1-5, 2000.
[10] K. A. Mujedu, I. O. Lamidi, D. O. Ayelabola, “An Investigation on the Suitability of the Broken Tiles as Coarse Aggregates in Concrete Production”, The International Journal Of Engineering And Science, vol 3, Issue 4, pages 35-41, 2014
[11] J. O. Ukpata, M. E. Ephraim, G. A. Akeke, “Compressive strength of concrete using lateritic sand and quarry dust as fine aggregate”, ARPN Journal of Engineering and Applied Sciences, vol 7, Issue 1, pages 81- 92, 2012.
[12] M. Abdullahi, “Effect of aggregate type on Compressive strength of concrete”, International Journal of Civil and structural engineering, vol 2, Issue 3, pages 791-800, 2012.
[13] L. M. Olanitori, “Cost Implication of Mitigating the Effect of Clay/Silt Content of Sand on Concrete Compressive Strength”, Journal of Civil Engineering and Urbanism, vol 2, Issue 4, pages 143- 148, 2011.
[14] S. P. Ejeh, O.A.U. Uche, “Effect of Crude Oil Spill on Compressive Strength of Concrete Materials”, Journal of Applied Sciences Research, vol 5, issue 10, pages 1756-1761, 2009
[15] J. I. Aguwa, “Effect of Hand Mixing on the Compressive Strength of Concrete, Leonardo Electronic Journal of Practices and Technologies, Volume17, pages 59-68, 2010.
[16] G. L. Oyekan, O. M. Kamiyo, “Effect of Nigerian rice husk ash on some engineering properties of concrete and sandcrete blocks. Proceeding of the 32nd Conference on Our world in concrete and structures, 28 - 29 August 2007, Singapore.
[17] D. O. Onwuka, L. Anyaogu, C. Chijioke, W .E. “Igwegbe, Optimization of Compressive Strength of River Sand-Termite Soil Concrete Using Simplex Design”, International Journal of Scientific and Research Publications, vol 3, Issue 5, pages 1-8, 2013.
[18] D. Dahiru, N. Shehu, “An evaluation of the concrete production in typical construction sites in Nigeria”, Proceedings of the 4th West Africa Built Environment Research (WABER) Conference, 24-26 July 2012, Abuja, Nigeria, Pages 463-472.
[19] R, Mathur, A. K. Misra, P. Goel, “Strength of Concrete vs Grades of Cement”, Central Road Research Institute, New Delhi. http://www.nbmcw.com/articles/concrete/25796-strength-of-concretevs- grades-of-cement.html. Assessed on 17th April, 2014.
[20] H. A. Hodhod, M. A. M Abdeen, “Experimental Comparative and Numerical Predictive Studies on Strength Evaluation of Cement Types: Effect of Specimen Shape and Type of Sand”, Scientific research, Engineering, Volume 2, pages 559-572, 2010.
[21] BS EN 12390-2:2009. Testing hardened concrete. Part 2: Making and curing specimens for strength tests. British Standards Institute.
[22] BS EN 12390-3:2009. Testing hardened concrete. Part 3: Compressive strength of test specimens. British Standards Institute.