In this study, two types of aggregate were used for making self-compacting concrete. Standard cubic specimens were exposed to different temperatures. Seventy-two standard cylindrical specimens (150×300 mm) and Seventy-two cubic specimens (150 mm) were tested. Compressive strengths of the manufactured specimens at 23°C were about 33 MPa to 40 MPa. The variable parameters among the self-compacting concrete specimens were of sand stone type. The specimens were exposed to 23, 100, 200, 400, 600, and 800°C and their mechanical specifications were controlled. The heated specimens were subjected to the unconfined compression test with a quasi-static loading rate. The corresponding stress-strain curves and modulus of elasticity were compared. The results showed that, at higher temperatures, Scoria aggregate showed less sensitivity than ordinary aggregate. The concrete made with Scoria aggregate exhibited less strain. The heated self-compacting concrete had similar slopes before and after the peak. In fact, increasing heat produced gradual symmetrical stress-strain diagram span.

1 Khennane, A., "Uniaxial model for concrete under variable temperature and stress" 119 (119): 1507-1525, 1993

2 Tanyildizi, H., "The effect of high temperature on compressive strength and splitting tensile strength of structural lightweight concrete containing fly ash" 22 (22): 2169-2175, 2008

3 Lo, T. Y., "The effect of high temperature curing on strength and carbonation of pozzolanic structural lightweight concretes" 23 (23): 1306-1310, 2009

4 Hu, B. L., "Test on strength and deformation of concrete under complex stress at elevated temperature" 20 (20): 47-50, 1994

5 Xiao, J., "Study on concrete at high temperature in China an overview" 39 (39): 89-103, 2004

6 Sanad, A. M., "Structural behavior in fire compartment under different heating regimes-Part 1(slab thermal gradients)" 35 (35): 99-116, 2000

7 Carreira, D. J., "Stress-strain relationship for plain concrete in compression" 82 (82): 797-804, 1985

8 Li, L., "Stress-strain constitutive equations of concrete material at elevated temperatures" 40 (40): 669-686, 2005

9 Jia, F., "Strength inspection on heated concrete with impact device" 26 (26): 51-55, 1996

10 Chandra, S., "Some effects of polymer addition on the fire resistance of concrete" 10 (10): 367-375, 1980

11 Annerel, E., "Revealing the temperature history in concrete after fire exposure by microscopic analysis" 39 (39): 1239-1249, 2009

12 Chang, Y. F., "Residual stress-strain Relationship for concrete after exposure to high temperatures" 36 (36): 1999-2005, 2006

13 Kodur, V. K. R., "Predicting the fire resistance behavior of high strength concrete columns" 26 (26): 141-153, 2004

14 Tanyildizi, H., "Performance of lightweight concrete with silica fume after high temperature" 22 (22): 2124-2129, 2008

15 Ali, F., "Outcomes of a major research on fire resistance of concrete columns" 39 (39): 433-445, 2004

16 Terro, M. J., "Numerical modeling of the behavior of concrete structures in fire" 95 (95): 183-193, 1998

17 Tanyildizi, H., "Molding mechanical performance of lightweight concrete containing silica fume exposed to high temperature using genetic programming" 24 (24): 2612-2618, 2010

18 Schneider, U., "Modelling of concrete behavior at high temperatures" 53-69, 1986

19 Georgali, B., "Microstructure of firedamaged concrete" 27 (27): 255-263, 2005

20 Mydin, M. A., "Mechanical properties of foamed concrete exposed to high temperatures" 26 (26): 638-654, 2012

21 Ismail, M., "Influence of elevated temperatures on physical and compressive strength properties of concrete containing palm oil fuel ash" 25 (25): 2358-2364, 2011

22 Alghamri, R., "Impregnation and encapsulation of lightweight aggregates for self-healing concrete" 124 : 910-921, 2016

23 Youssef, M. A., "General Stress-strain relationship for concrete at elevated temperatures" 29 (29): 2618-2634, 2006

24 Lie, T. T., "Fire performance of reinforced concrete columns" 176-205, 1985

25 Hernández, O. F., "Fire performance of recycled rubber-filled high-strength concrete" 34 (34): 109-117, 2004

26 Cui, H. Z., "Experimental investigation and development of analytical model for pre-peak stress-strain curve of structural lightweight aggregate concrete" 36 : 845-859, 2012

27 "Eurocode2; Design of concrete structures Part 1&2, general rules, structural fire design"

28 Shafigh, P., "Engineering properties of lightweight aggregate concrete containing limestone powder and high volume fly ash" 135 : 148-157, 2016

29 Othumn, M. A., "Elevated-temperature thermal properties of light weight foamed concrete" 25 (25): 705-716, 2011

30 Petkovski, M., "Effects of stress during heating on strength and stiffness of concrete at elevated temperature" 40 (40): 1744-1755, 2010

31 Karamloo, M., "Effects of maximum aggregate size on fracture behaviors of selfcompacting lightweight concrete" 123 : 508-515, 2016

32 Arioz, O., "Effects of elevated temperatures on properties of concrete" 42 (42): 516-522, 2007

33 Sancak, E., "Effects of elevated temperature on compressive strength and weight loss of the light-weight concrete with silica fume and superplasticizer" 30 (30): 715-721, 2008

34 Mirza, F. A., "Effects of alkali-resistant glass fiber reinforcement on crack and temperature resistance of lightweight concrete" 24 (24): 223-227, 2002

35 Janotka, I., "Effect of temperature on structural quality of the cement paste and high-strength concrete with silica fume" 235 (235): 2019-2032, 2005

36 Sengul, O., "Effect of expanded perlite on the mechanical properties and thermal conductivity of lightweight concrete" 43 (43): 671-676, 2011

37 Fathi, H., "Effect of cyclic loadings on heated self-compacting concrete" 69 : 26-31, 2014

38 Sun, W., "Compressive strength and pore structure of high-performance concrete after exposure to high temperature up to 800°C" 30 (30): 247-251, 2000

39 Poon, C. S., "Compressive behavior of fiber reinforced high-performance concrete subjected to elevated temperatures" 34 (34): 2215-2222, 2004

40 Falade, F., "Behavior of lightweight concrete containing periwinkle shells at elevated temperature" 5 (5): 379-390, 2010

41 Choi, Y. W., "An experimental research on the fluidity and mechanical properties of high-strength lightweight self-compacting concrete" 36 (36): 1595-1602, 2006