[KSCI] Korea Science Citation Index Service

http://dx.doi.org/10.12989/scs.2019.31.1.069

Experimental behavior of VHSC encased composite stub column under compression and end moment

Huang, Zhenyu (Guangdong Provincial Key Laboratory of Durability of Marine Civil Engineering, Shenzhen University)
Huang, Xinxiong (Guangdong Provincial Key Laboratory of Durability of Marine Civil Engineering, Shenzhen University)
Li, Weiwen (Guangdong Provincial Key Laboratory of Durability of Marine Civil Engineering, Shenzhen University)
Mei, Liu (Guangdong Provincial Key Laboratory of Durability of Marine Civil Engineering, Shenzhen University)
Liew, J.Y. Richard (Department of Civil and Environmental Engineering, National University of Singapore)

Publication Information

Steel and Composite Structures / v.31, no.1, 2019 , pp. 69-83 More about this Journal

Abstract

This paper investigates the structural behavior of very high strength concrete encased steel composite columns via combined experimental and analytical study. The experimental programme examines stub composite columns under pure compression and eccentric compression. The experimental results show that the high strength encased concrete composite column exhibits brittle post peak behavior and low ductility but has acceptable compressive resistance. The high strength concrete encased composite column subjected to early spalling and initial flexural cracking due to its brittle nature that may degrade the stiffness and ultimate resistance. The analytical study compares the current code methods (ACI 318, Eurocode 4, AISC 360 and Chinese JGJ 138) in predicting the compressive resistance of the high strength concrete encased composite columns to verify the accuracy. The plastic design resistance may not be fully achieved. A database including the concrete encased composite column under concentered and eccentric compression is established to verify the predictions using the proposed elastic, elastoplastic and plastic methods. Image-oriented intelligent recognition tool-based fiber element method is programmed to predict the load resistances. It is found that the plastic method can give an accurate prediction of the load resistance for the encased composite column using normal strength concrete (20-60 MPa) while the elastoplastic method provides reasonably conservative predictions for the encased composite column using high strength concrete (60-120 MPa).

Keywords

composite column; concrete encased column; high strength concrete; steel-concrete composite; ultra-high strength concrete;

Citations & Related Records

Times Cited By KSCI : 5 (Citation Analysis)

Reference
Cited By KSCI

1	Tokgoz, S., Dundar, C. and Tanrikulu, A.K. (2012), "Experimental behaviour of steel fiber high strength reinforced concrete and composite columns", J. Const. Steel Res., 74(1), 98-107. DOI
2	Wang, Z. (2007), Experimental Study and Nonlinear Analysis of Eccentric Columns with High Strength and High Performance of Steel Reinforced Concrete, Xi'an University of Architectural Science and Technology, Xi'an, China.
3	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
4	Wee, T.H., Chin, M.S. and Mansur, M.A. (1996), "Sress-strain relationship of high-strength concrete in compression", J. Mater. Civil Eng., 8(2), 70-76. DOI
5	Xiong, M. and Liew, J.Y.R. (2016), "Mechanical behaviour of ultra-high strength concrete at elevated temperatures and fire resistance of ultra-high strength concrete filled steel tubes", Mater. Des., 104(1), 414-427. DOI
6	Yang, Y., Chen, Y., Zhang, J., Xue, Y., Liu, R. and Yu, Y. (2018), "Experimental investigation on shear capacity of partially prefabricated steel reinforced concrete columns", Steel Compos. Struct., Int. J., 28(1), 73-82.
7	YB 9082 (2007), Technical specification for steel reinforced concrete structures; General Institute of Architectural Research of China Metallurgical Group, Beijing, China.
8	Ye, L. (1995), "Experimental study on stiffened reinforced concrete columns under eccentric compression", J. Architect. Struct., 16(6), 45-52.
9	Zhang, L. (2011), Theoretical Study on the Mechanical Behavior and Design Calculation of High Strength and High Performance Concrete Columns with Steel Profile, Xi'an University of Architectural Science and Technology, Xi'an, China.
10	Chen, S. and Wu, P. (2016), "Analytical model for predicting axial compressive behavior of steel reinforced concrete column", J. Const. Steel Res., 128, 649-660. DOI
11	Choe, G., Kim, G., Gucunski, N. and Lee, S. (2015), "Evaluation of the mechanical properties of 200MPa ultra-high-strength concrete at elevated temperatures and residual strength of column", Constr. Build. Mater., 86(1), 159-168. DOI
12	Deng, Z. and Qu, J. (2015), "The experimental studies on behavior of ultrahigh-performance concrete confined by hybrid fiberreinforced polymer tubes", Adv. Mater. Sci. Eng., 1-18.
13	Du, Y., Chen, Z., Wang, Y.-B. and Richard Liew, J.Y. (2017), "Ultimate resistance behavior of rectangular concrete-filled tubular beam-columns made of high-strength steel", J. Const. Steel Res., 133, 418-433. DOI
14	El-Tawil, S. and Deierlein, G.G. (1999), "Strength and ductility of concrete encased composite columns", J. Struct. Eng., 125(9), 1009-1019. DOI
15	Ellobody, E. and Young, B. (2011), "Numerical simulation of concrete encased steel composite columns", J. Const. Steel Res., 67(2), 211-222. DOI
16	Ellobody, E., Young, B. and Lam, D. (2011), "Eccentrically loaded concrete encased steel composite columns", Thin-Wall. Struct., 49(1), 53-65. DOI
17	Elwi, A.E., Begum, M. and Driver, R.G.(2015), "Parametric study on eccentrically-loaded partially encased composite columns under major axis bending", Steel Compos. Struct., Int. J., 19(5), 1299-1319. DOI
18	Eurocode 2 (2004), Design of concrete strctures, part 1-1: General rules and rules for buildings; European Committee for Standardisation, Brussels, Belgium.
19	Eurocode 4 (2004), EN 1994-1-1 Design of composite steel and concrete structures; European Committee for Standardisation, Brussels, Belgium.
20	Zhu, W., Jia, J. and Zhang, J. (2017), "Experimental research on seismic behavior of steel reinforced high-strength concrete short columns", Steel Compos. Struct., Int. J., 25(5), 603-615.
21	Zohrevand, P. and Mirmiran, A. (2013), "Stress-Strain Model of Ultrahigh Performance Concrete Confined by Fiber-Reinforced Polymers", J. Mater. Civil Eng., 25(12), 1822-1829. DOI
22	Huang, Z.Y., Wang, J.Y., Liew, J.R. and Marshall, P.W. (2015), "Lightweight steel-concrete-steel sandwich shell subject to punching shear", Ocean Eng., 102, 146-161. DOI
23	Gentian, Z., Chunhua, W., Chunyan, G. and Chenxia, W. (2006), "Experimental study on Mechanical behavior of long columns under eccentric Compression of Steel reinforced concrete", J. Baotou Univ. Iron Steel Technol., 25(4), 384-400.
24	Huang, Z. and Liew, J.Y.R. (2016a), "Structural behaviour of steel-concrete-steel sandwich composite wall subjected to compression and end moment", Thin-Wall. Struct., 98, 592-606. DOI
25	Huang, Z. and Liew, J.Y.R. (2016b), "Steel-concrete-steel sandwich composite structures subjected to extreme loads", Int. J. Steel Struct., 16(14),1009-1028. DOI
26	Javed, M.F., Sulong, N.H.R., Memon, S.A., Rehman, S.K.U. and Khan, N.B. (2017), "FE modelling of the flexural behaviour of square and rectangular steel tubes filled with normal and high strength concrete", Thin-Wall. Struct., 119, 470-481. DOI
27	JGJ 138 (2016), Code for design of composite structure, Ministry of Housing and Urban-Rural Construction of the People's Republic of China; Beijing, China
28	Kim, C.S., Park, H.G., Chung, K.S. and Choi, I.R. (2012), "Eccentric Axial Load Testing for Concrete-Encased Steel Columns Using 800 MPa Steel and 100 MPa Concrete", J. Struct. Eng., 138(8), 1019-1031. DOI
29	Kim, C.S., Park, H.G., Chung, K.S. and Choi, I.R. (2014), "Eccentric axial load capacity of high-strength steel-concrete composite columns of various sectional shapes", J. Struct. Eng., 140(4), 04013091. DOI
30	Kim, C.S., Park, H.G., Choi, I.R. and Chung, K.S. (2017a), "Effect of Sustained Load on Ultimate Strength of High-Strength Composite Columns Using 800-MPa Steel and 100-MPa Concrete", J. Struct. Eng., 143(3), 04016189. DOI
31	Lin, M. (2006), Study on High Strength Steel Reinforced Concrete Columns, Xi'an University of Architectural Science and Technology, Xi'an, China.
32	Kim, C.S., Park, H.G., Lee, H.J., Choi, I.R. and Chung, K.S. (2017b), "Eccentric axial load test for high-strength composite columns of various sectional configurations", J. Struct. Eng., 43(8), 04017075.
33	Lee, J.H. (2013), "Evaluation on Fire Resistance of Ultra-High- Strength Concrete Depending on Aggregates and Fibers Types", J. Kor. Soc. Hazard Mitigat., 13(6), 91-97. DOI
34	Lim, J.C. and Ozbakkaloglu, T. (2014), "Stress-strain model for normal- and light-weight concretes under uniaxial and triaxial compression", Constr. Build. Mater., 71, 492-509. DOI
35	Lou, Y. (1996), "Simplified calculation method for stiffened concrete long columns", Indust. Constr., 26(3), 20-22.
36	Pereira, M.F., Nardin, S.D. and Debs, A.L.H.C.E. (2016), "Structural behavior of partially encased composite columns under axial loads", Steel Compos. Struct., Int. J., 20(6), 1305-1322. DOI
37	Lu, X.L., Yin, X.W. and Jiang, H.J. (2014), "Experimental study on hysteretic properties of SRC columns with high steel ratio", Steel Compos. Struct., Int. J., 17(3), 287-303. DOI
38	Lu, D., Du, X., Wang, G., Zhou, A. and Li, A. (2016), "A threedimensional elastoplastic constitutive model for concrete", Comput. Struct., 163, 41-55. DOI
39	Papanikolaou, V.K. and Kappos, A.J. (2007), "Confinementsensitive plasticity constitutive model for concrete in triaxial compression", Int. J. Solids Struct., 44(21), 7021-7048. DOI
40	Piscesa, B., Attard, M.M., Samani, A.K. and Tangaramvong, S. (2017), "Plasticity Constitutive Model for Stress-Strain Relationship of Confined Concrete", ACI Struct J., 114(2), 361-371. DOI
41	ASTM C39/C39M (2014), Standard Test Method for Compressive Strength of Cylindrical Concrete Specimens; West Conshohocken, PA, USA.
42	ACI 318 (2014), Building Code Requirements for Structural Concrete; American Concrete Institude, Farmington Hills, MI48331, USA.
43	AIJ (2010), Standard for Structural Calculation of Steel Reinforced Concrete Structures; Architectural Institute of Japan, Tokyo, Japan.
44	AISC 360 (2010), Specification for Structural Steel Buildings; Chicago, IL, USA
45	ASTM C136/C136M - 14 (2014), Standard Test Method for Sieve Analysis of Fine and Coarse ;ggregates, West Conshohocken, PA, USA.
46	ASTM C1611/C1611M-14(2018), Standard test method for slump flow of self-consolidating concrete; West Conshohocken, PA, USA.
47	ASTM E8/E8M - 16A (2016), Standard Test Methods for Tension Testing of Metallic Materials; West Conshohocken, PA, USA.
48	Barbos, G.A. (2016), "Long-term Behavior of Ultra - High Performance Concrete (UHPC) Bended Beams", Procedia Technology, 22(1), 203-210. DOI
49	Begum, M., Driver, R.G. and Elwi, A.E. (2013), "Behaviour of partially encased composite columns with high strength concrete", Eng. Struct., 56(1), 1718-1727. DOI
50	Carreira, D.J. and Chu, K.H. (1985), "Stress-strain relationship for plain concrete in compression", ACI Journal, 82(6), 797-804.