[KSCI] Korea Science Citation Index Service

http://dx.doi.org/10.12989/scs.2018.27.4.509

Residual bond behavior of high strength concrete-filled square steel tube after elevated temperatures

Chen, Zongping (College of Civil Engineering and Architecture, Guangxi University)
Liu, Xiang (College of Civil Engineering and Architecture, Guangxi University)
Zhou, Wenxiang (College of Civil Engineering and Architecture, Guangxi University)

Publication Information

Steel and Composite Structures / v.27, no.4, 2018 , pp. 509-523 More about this Journal

Abstract

This paper presents experimental results on the residual bond-slip behavior of high strength concrete-filled square steel tube (HSCFST) after elevated temperatures. Three parameters were considered in this test: (a) temperature (i.e., $20^{\circ}C$ , $200^{\circ}C$ , $400^{\circ}C$ , $600^{\circ}C$ , $800^{\circ}C$ ); (b) concrete strength (i.e., C60, C70, C80); (c) anchorage length (i.e., 250 mm, 400 mm). A total of 17 HSCFST specimens were designed for push-out test after elevated temperatures. The load-slip curves at the loading end and free end were obtained, in addition, the distribution of steel tube strain and the bond stress along the anchorage length were analyzed. Test results show that the shape of load-slip curves at loading ends and free ends are similar. With the temperature constantly increasing, the bond strength of HSCFST increases first and then decreases; furthermore, the bond strength of HSCFCT proportionally increases with the anchoring length growing. Additionally, the higher the temperature is, the smaller and lower the bond damage develops. The energy dissipation capacity enhances with the concrete strength rasing, while, decreases with the temperature growing. What is more, the strain and stress of steel tubes are exponentially distributed, and decrease from the free end to loading end. According to experimental findings, constitutive formula of the bond slip of HSCFST experienced elevated temperatures is proposed, which fills well with test data.

Keywords

square steel tube; high strength concrete; elevated temperatures test; static test; residual bond strength;

Citations & Related Records

Times Cited By KSCI : 4 (Citation Analysis)

Reference
Cited By KSCI

1	AIJ (1997), Recommendations for design and construction of concrete filled steel tubular structure; Architectural Institute of Japan, Tokyo, Japan.
2	Aslani, F., Uy, B. and Tao, Z. (2015), "Predicting the axial load capacity of high-strength concrete filled steel tubular columns", Steel Compos. Struct., Int. J., 19(4), 967-993. DOI
3	BS 540025 (2005), Steel concrete and composite bridges: Part 5: Code of Practice for the Design of Composite Bridges; British Standard Institute, London, Britain.
4	BS EN 1994-1-1 (2004), Eurocode 4: Design of composite steel and concrete structures: Part1.1, General rules and rules for buildings; British Standards Institution, London, Britain.
5	Chiang, C.H. and Tsai, C.L. (2003), "Time-temperature analysis of bond strength of a rebar after fire exposure", J. Cement Concrete Res., 33(10), 1651-1654. DOI
6	Dong, C.X., Kwan, A.K.H. and Ho, J.C.M. (2015), "A constitutive model for predicting the lateral strain of confined concrete", Eng. Struct., 91, 155-166. DOI
7	El-Hawary, M.M. and Hamoush, S.A. (1996), "Bond shear modulus of reinforced concrete at high temperatures", Eng. Fract. Mech., 55(6), 991-999. DOI
8	Kwan, A.K.H., Dong, C.X. and Ho, J.C.M. (2015), "Axial and lateral stress-strain model for FRP confined concrete", Eng. Struct., 99, 285-295. DOI
9	Guler, S., Copur, A. and Aydogan, M. (2014), "A comparative study on square and circular high strength concrete-filled steel tube columns", Adv. Steel Constr., 10(2), 234-247.
10	Haddad, R.H. and Shannis, L.G. (2004), "Post-fire behavior of bond between high strength pozzolanic concrete and reinforcing steel", Constr. Build. Mater., 18(6), 425-435. DOI
11	Lai, M.H. and Ho, J.C.M. (2014), "Experimental and theoretical studies of confined HSCFST columns under uni-axial compression", Earthq. Struct., Int. J., 7(4), 527-552. DOI
12	Ma, Y.S. and Wang, Y.F. (2012), "Creep of high strength concrete filled steel tube columns", Thin-Wall. Struct., 53(2), 91-98. DOI
13	Moliner, V., Espinos, A. and Romero, M.L. (2013), "Fire behavior of eccentrically loaded slender high strength concrete-filled tubular columns", J. Constr. Steel Res., 83, 137-146. DOI
14	Patel, V.I., Liang, Q.Q. and Hadi, M.N.S. (2014), "Numerical analysis of high-strength concrete-filled steel tubular slender beam-columns under cyclic loading", J. Constr. Steel Res., 92(1), 183-194. DOI
15	Song, T.Y., Tao, Z. and Han, L.H. (2017), "Bond behavior of concrete-filled steel tubes at elevated temperatures", J. Struct. Eng., 143(11), 04017147 DOI
16	Qu, X., Chen, Z. and Nethercot, D.A. (2014), "Push-out tests and bond strength of rectangular CFST columns", Steel Compos. Struct., Int. J., 19(1), 21-41.
17	Romero, M.L., Espinos, A. and Portoles, J.M. (2015), "Slender double-tube ultra-high strength concrete-filled tubular columns under ambient temperature and fire", Eng. Struct., 99, 536-545. DOI
18	Schaumann, P., Kodur, V. and Bahr, O. (2009), "Fire behaviour of hollow structural section steel columns filled with high strength concrete", J. Constr. Steel Constr., 65(8-9), 1794-1802. DOI
19	Schaumann, P and Kleibomer, I. (2017), "Experimental and numerical investigations of the composite behaviour in concrete-filled tubular columns with massive steel core at high temperatures", J. Struct. Fire Eng., 9(2), 147-160.
20	Shakir-Khalil, H. (1993), "Push out strength of concrete-filled steel hollow sections", Struct. Engr., 71, 230-233.
21	Su, Q.T., Yang, G.T. and Bradford, M.A. (2014), "Static behaviour of multi-row stud shear connectors in high- strength concrete", Steel Compos. Struct., Int. J., 17(6), 967-980. DOI
22	Tao, Z., Han, L.H. and Uy, B. (2011), "Post-fire bond between the steel tube and concrete in concrete-filled steel tubular columns", J. Constr. Steel Res., 67(3), 484-496. DOI
23	Xu, C., Huang, C.K. and Jiang, D.C. (2009), "Push-out test of prestressing concrete filled circular steel tube columns by means of expansive cement", Constr. Build. Mater., 23(1), 491-497. DOI
24	Tao, Z., Song, T.Y. and Uy, B. (2016), "Bond behavior in concretefilled steel tubes", J. Constr. Steel Res., 120, 81-93. DOI
25	Wang, Y.B. and Liew, J.Y.R. (2016), "Constitutive model for confined ultra-high strength concrete in steel tube", Constr. Build. Mater., 126, 812-822. DOI
26	Xiong, M.X. and Liew, J.Y.R. (2016), "Mechanical behavior of ultra-high strength concrete at elevated temperatures and fire resistance of ultra-high strength concrete filled steel tubes", Mater. Des., 104, 414-427. DOI
27	Xu, J.J., Chen, Z.P. and Xue, J.Y. (2013), "Failure mechanism of interface bond behavior between circular steel tube and recycled aggregate concrete by push-out test", J. Build. Struct., 34(7), 148-156. [In Chinese]
28	Yang, Z., Li, G. and Lang, Y. (2017), "Flexural behavior of high strength concrete filled square steel tube with inner CFRP circular tube", Ksce J. Civil Eng., 21(7), 2728-2737. DOI

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1	(2018) Steel & Composite structures : an international journal Experimental and numerical investigation on post-earthquake fire behaviour of the circular concrete-filled steel tube columns / 38 (1) , 17