[KSCI] Korea Science Citation Index Service

http://dx.doi.org/10.1007/s40069-016-0175-2

Effect of Elevated Temperature on Mechanical Properties of Limestone, Quartzite and Granite Concrete

Tufail, Muhammad (Department of Civil Engineering, University of Engineering and Technology Peshawar)
Shahzada, Khan (Department of Civil Engineering, University of Engineering and Technology Peshawar)
Gencturk, Bora (Sonny Astani Department of Civil and Environmental Engineering, University of Southern California)
Wei, Jianqiang (Sonny Astani Department of Civil and Environmental Engineering, University of Southern California)

Publication Information

International Journal of Concrete Structures and Materials / v.11, no.1, 2017 , pp. 17-28 More about this Journal

Abstract

Although concrete is a noncombustible material, high temperatures such as those experienced during a fire have a negative effect on the mechanical properties. This paper studies the effect of elevated temperatures on the mechanical properties of limestone, quartzite and granite concrete. Samples from three different concrete mixes with limestone, quartzite and granite coarse aggregates were prepared. The test samples were subjected to temperatures ranging from 25 to $650^{\circ}C$ for a duration of 2 h. Mechanical properties of concrete including the compressive and tensile strength, modulus of elasticity, and ultimate strain in compression were obtained. Effects of temperature on resistance to degradation, thermal expansion and phase compositions of the aggregates were investigated. The results indicated that the mechanical properties of concrete are largely affected from elevated temperatures and the type of coarse aggregate used. The compressive and split tensile strength, and modulus of elasticity decreased with increasing temperature, while the ultimate strain in compression increased. Concrete made of granite coarse aggregate showed higher mechanical properties at all temperatures, followed by quartzite and limestone concretes. In addition to decomposition of cement paste, the imparity in thermal expansion behavior between cement paste and aggregates, and degradation and phase decomposition (and/or transition) of aggregates under high temperature were considered as main factors impacting the mechanical properties of concrete. The novelty of this research stems from the fact that three different aggregate types are comparatively evaluated, mechanisms are systemically analyzed, and empirical relationships are established to predict the residual compressive and tensile strength, elastic modulus, and ultimate compressive strain for concretes subjected to high temperatures.

Keywords

concrete; fire resistance; limestone; quartzite; granite; mechanical properties;

Citations & Related Records

Times Cited By KSCI : 2 (Citation Analysis)

Reference
Cited By KSCI

1	Yao, W., & Zheng, X. (2007). Effect of mix proportion on coefficient of thermal expansion of concrete. Tongji Daxue Xuebao/Journal of Tongji University, 35(1), 77-81 + 87.
2	Zhang, W., Qian, H., Sun, Q., & Chen, Y. (2015). Experimental study of the effect of high temperature on primary wave velocity and microstructure of limestone. Environmental Earth Sciences, 74(7), 5739-5748. DOI
3	ASTM. (2014). Standard test method for static modulus of elasticity and Poisson's ratio of concrete in compression. West Conshohocken, PA: American Society of Testing Materials (ASTM). ASTM C469/C469M-14.
4	Behnood, A., & Ghandehari, M. (2009). Comparison of compressive and splitting tensile strength of high-strength concrete with and without polypropylene fibers heated to high temperatures. Fire Safety Journal, 44(8), 1015-1022. DOI
5	ASTM. (2015). Standard test method for density, relative density (specific gravity), and absorption of coarse aggregate. West Conshohocken, PA: American Society of Testing Materials (ASTM). ASTM C127-15.
6	ASTM. (2015). Standard test method for density, relative density (specific gravity), and absorption of fine aggregate. West Conshohocken, PA: American Society of Testing Materials (ASTM). ASTM C128-15.
7	ASTM. (2015). Standard test method for slump of hydraulic-cement concrete. West Conshohocken, PA: American Society for Testing of Materials (ASTM). ASTM C143/C143M-15.
8	Behnood, A., & Ziari, H. (2008). Effects of silica fume addition and water to cement ratio on the properties of high-strength concrete after exposure to high temperatures. Cement & Concrete Composites, 30(2), 106-112. DOI
9	Bentz, D. P. (2007). Transient plane source measurements of the thermal properties of hydrating cement pastes. Materials and Structures, 40(10), 1073-1080. DOI
10	Bentz, D. P., Peltz, M. A., Duran-Herrera, A., Valdez, P., & Juarez, C. A. (2011). Thermal properties of high-volume fly ash mortars and concretes. Journal of Building Physics, 34(3), 263-275. DOI
11	Brown, W. L. (1989). Alkali feldspars: Ordering rates, phase transformations and behaviour diagrams for igneous rocks. Mineralogical Magazine, 53(369), 25-42. DOI
12	EN. (1992). Design of concrete structures. Part 1-2: General rules-structural fire design. Brussels, Belgium: European Standards (EN).
13	Chen, L.-J., He, J., Chao, J.-Q.,&Qin, B.-D. (2009). Swelling and breaking characteristics of limestone under high temperatures. Mining Science and Technology (China), 19(4), 503-507. DOI
14	Cheng, F., Kodur, V., & Wang, T. (2004). Stress-strain curves for high strength concrete at elevated temperatures. Journal of Materials in Civil Engineering, 16(1), 84-90. DOI
15	Cruz, C. R., & Gillen, M. (1980). Thermal expansion of Portland cement paste, mortar and concrete at high temperatures. Fire and Materials, 4(2), 66-70. DOI
16	Ghandehari, M., Behnood, A., & Khanzadi, M. (2009). Residual mechanical properties of high-strength concretes after exposure to elevated temperatures. Journal of Materials in Civil Engineering, 22(1), 59-64. DOI
17	Gluekler, E. L. (1979). Local thermal and structural behavior of concrete at elevated temperatures. 5th international conference on structural mechanics in reactor technology Berlin: International Association.
18	Goldsmith, J. R. (1980). The melting and breakdown reactions of anorthite at high pressures and temperatures. American Mineralogist, 65, 272-284.
19	Hager, I. (2013). Behaviour of cement concrete at high temperature. Bulletin of the Polish Academy of Sciences: Technical Sciences, 61, 145. DOI
20	Heikal, M. (2000). Effect of temperature on the physico-mechanical and mineralogical properties of homra pozzolanic cement pastes. Cement and Concrete Research, 30(11), 1835-1839. DOI
21	Husem, M. (2006). The effects of high temperature on compressive and flexural strengths of ordinary and high-performance concrete. Fire Safety Journal, 41(2), 155-163. DOI
22	Naus, D. (2010). In: D. J. Naus (Ed.), A compilation of elevated temperature concrete material property data and information for use in assessments of nuclear power plant reinforced concrete structures. U.S. Nuclear Regulatory Commission, Office of Nuclear Regulatory Research. Report no: NUREG/CR-7031, Washington, DC.
23	Abrams, M. S. (1971). Compressive strength of concrete at temperatures to 1600F. ACI Special Publication, 25, 33-58.
24	ACI. (2014). Building code requirements for structural concrete (ACI 318-14) and commentary (ACI 318-14R). American Concrete Institute (ACI): Farmington Hills, MI.
25	Akhavan, A. C. (2005). The quartz page. Retrieved 07/24, 2016. http://www.quartzpage.de/gen_mod.html.
26	Koksal, F., Gencel, O., Brostow, W., & Lobland, H. E. H. (2012). Effect of high temperature on mechanical and physical properties of lightweight cement based refractory including expanded vermiculite. Materials Research Innovations, 16(1), 7-13. DOI
27	Li, H., & Liu, G. (2016). Tensile properties of hybrid fiberreinforced reactive powder concrete after exposure to elevated temperatures. International Journal of Concrete Structures and Materials, 10(1), 29-37. DOI
28	Pancar, E. B., & Akpinar, M. V. (2016). Temperature reduction of concrete pavement using glass bead materials. International Journal of Concrete Structures and Materials, 10(1), 39-46. DOI
29	Peng, G.-F., & Huang, Z.-S. (2008). Change in microstructure of hardened cement paste subjected to elevated temperatures. Construction and Building Materials, 22(4), 593-599. DOI
30	Plevova, E., Vaculikova, L., Kozusnikova, A., Ritz, M., & Simha Martynkova, G. (2016). Thermal expansion behaviour of granites. Journal of Thermal Analysis and Calorimetry, 123(2), 1555-1561. DOI
31	Poon, C.-S., Azhar, S., Anson, M., & Wong, Y.-L. (2001). Comparison of the strength and durability performance of normal- and high-strength pozzolanic concretes at elevated temperatures. Cement and Concrete Research, 31(9), 1291-1300. DOI
32	Rodriguez-Navarro, C., Ruiz-Agudo, E., Luque, A., Rodriguez-Navarro, A. B., & Ortega-Huertas, M. (2009). Thermal decomposition of calcite: Mechanisms of formation and textural evolution of CaO nanocrystals. American Mineralogist, 94, 578-593. DOI
33	ASTM. (2013). Standard test method for surface moisture in fine aggregate. West Conshohocken, PA: American Society of Testing Materials (ASTM). ASTM C70-13.
34	Ali, F., Nadjai, A., Silcock, G., & Abu-Tair, A. (2004). Outcomes of a major research on fire resistance of concrete columns. Fire Safety Journal, 39(6), 433-445. DOI
35	Arioz, O. (2007). Effects of elevated temperatures on properties of concrete. Fire Safety Journal, 42(8), 516-522. DOI
36	ASTM. (2009). Standard test method for bulk density ("Unit Weight") and voids in aggregate. West Conshohocken, PA: American Society for Testing of Materials (ASTM). C29/C29M-09.
37	ASTM. (2011). Standard test method for splitting tensile strength of cylindrical concrete specimens. West Conshohocken, PA: American Society of Testing Materials (ASTM). ASTM C496-11.
38	ASTM. (2013). Standard specification for concrete aggregates. West Conshohocken, PA: American Society for Testing of Materials (ASTM). C33/C33M-13.
39	ASTM. (2013). Standard test method for total evaporable moisture content of aggregate by dryin. West Conshohocken, PA: American Society of Testing Materials (ASTM). ASTM C566-13.
40	ASTM. (2014). Standard test method for compressive strength of cylindrical concrete specimens. West Conshohocken, PA: American Society of Testing Materials (ASTM). ASTM C39/C39M-14.
41	ASTM. (2014). Standard test method for resistance to degradation of small-size coarse aggregate by abrasion and impact in the Los Angeles machine. West Conshohocken, PA: American Society for Testing and Materials (ASTM). C131/C131M-14.
42	ASTM. (2014). Standard test method for sieve analysis of fine and coarse aggregates. West Conshohocken, PA: American Society for Testing of Materials (ASTM). ASTM C136/C136M-14.
43	Wenk, H. R., & Bulakh, A. (2004). Minerals: Their constitution and origin. Cambridge: Cambridge University Press.
44	Sakr, K., & El-Hakim, E. (2005). Effect of high temperature or fire on heavy weight concrete properties. Cement and Concrete Research, 35(3), 590-596. DOI
45	Savva, A., Manita, P., & Sideris, K. K. (2005). Influence of elevated temperatures on the mechanical properties of blended cement concretes prepared with limestone and siliceous aggregates. Cement&Concrete Composites, 27(2), 239-248. DOI
46	Uygunoglu, T., & Topcu I. B. (2012). Effect of aggregate type on linear thermal expansion of self-consolidating concrete at elevated temperatures. Science and Engineering of Composite Materials, 19(3), 259.

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