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International Journal of Steel Structures

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30-07-2022

Research on Local Buckling of Stainless Steel Lipped C-Section Beam Around Strong-Axis

Authors: Shenggang Fan, Hang Zhou, Zhixia Ding, Chenxu Li, Qinglin Jiang

Published in: International Journal of Steel Structures | Issue 5/2022

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Abstract

To study the local buckling capacity of stainless steel beams with lipped C-sections under strong axis bending, tensile tests were performed on 12 stainless steel coupons based on S30408 austenitic stainless steel (AISI304) in flat and corner areas, and mechanical properties and stress–strain curves were obtained. Then, local buckling capacity tests were performed on 6 specimens of stainless steel beams under strong axis bending to determine their mechanical properties and failure mechanism. The failure phenomenon, load–displacement curve, load–strain curve and local buckling capacity were determined. Results show that the failure modes of the specimens are local buckling failure of the flange and web at mid-span. Additionally, a refined finite element analysis model was developed using Python and ABAQUS to simulate and analyse the mechanical performance and local buckling capacity. Then, the analytical results were compared to the test results, and the accuracy of the refined model was verified. Then, the refined model of the stainless steel C-section beam was simplified including the constraint simplification model, which considered different flange constraints and initial imperfections, and the length simplification model, which was based on different length and support constraints. The comparative analysis results showed that the constraint simplification model can simulate the local buckling failure mode more accurately than other models. Additionally, initial imperfections were shown to have little effect on the local buckling capacity; however, specimen length and the bearing constraint condition did affect the local buckling capacity.

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Becque, J., & Rasmussen, K. J. R. (2009a). Experimental investigation of local-overall interaction buckling of stainless steel lipped channel columns. Journal of Constructional Steel Research, 65(8–9), 1677–1684.CrossRef

Becque, J., & Rasmussen, K. J. R. (2009b). Numerical investigation of local-overall interaction buckling of stainless steel lipped channel columns. Journal of Constructional Steel Research, 65(8–9), 1685–1693.CrossRef

Cheng, Y. (2005). Distortional buckling of cold-formed steel members in bending. Research Report, American Iron and Steel Institute, Committee on Specifications.

Fan, S. G., Liu, F., Zheng, B. F., Shu, G. P., & Tao, Y. L. (2014a). Experimental study on bearing capacity of stainless steel lipped C section stub columns. Thin-Walled Structures, 83, 70–84.CrossRef

Fan, S. G., Tao, Y. L., Zheng, B. F., & Liu, F. (2014b). Capacity of stainless steel lipped C-section stub column under axial compression. Journal of Constructional Steel Research, 103(12), 251–263.

Feng, Z., & Young, B. (2006). Cold-formed stainless steel sections subjected to web crippling. Journal of Structural Engineering, 132(1), 134–144.CrossRef

Feng, Z., & Young, B. (2007). Experimental investigation of cold-formed high-strength stainless steel tubular members subjected to combined bending and web crippling. Journal of Structural Engineering, 133(7), 1027–1034.CrossRef

Gardner, L., & Nethercot, D. A. (2004). Experiments on Stainless Steel Hollow Sections- Part 2: Members Behaviour of Columns and Beams. Journal of Constructional Steel Research, 60(9), 1319–1332.CrossRef

Haidarali, M. R., & Nethercot, D. A. (2011). Finite element modelling of cold-formed steel beams under local buckling or combined local/distortional buckling. Thin-Walled Structures., 49(12), 1554–1562.CrossRef

He, Z. Q., Zhou, X. H., Zou, B., & Chen, P. (2019). Calculation-method investigation on ultimate load-carrying capacities of cold-formed steel columns experiencing distortional-global buckling interaction under axial compression. Journal of Building Structures, 40(3), 192–199.

Kwon, Y. B., & Hancock, G. J. (1992). Tests of cold-formed channels with local and distortional buckling. Journal of Structural Engineering, 118(7), 1786–1803.CrossRef

Landesmann, A., & Camotim, D. (2016). Distortional failure and DSM design of cold-formed steel lipped channel beams under elevated temperatures. Thin-Walled Structures, 98, 75–93.CrossRef

Lecce, M., & Rasmussen, K. J. R. (2006a). Distortional buckling of cold-formed stainless steel sections: Experimental investigation. Journal of Structural Engineering, 132(4), 497–504.CrossRef

Lecce, M., & Rasmussen, K. J. R. (2006b). Distortional buckling of cold-formed stainless steel sections: Finite element modeling and design. Journal of Structural Engineering, 132(4), 505–514.CrossRef

Li, S., Zhang, L., Liang, Y., & Zhao, O. (2021). Experimental and numerical investigations of hot-rolled stainless steel channel section columns susceptible to flexural buckling. Thin-Walled Structures, 164, 107791.CrossRef

Li, S., Zhang, L., & Zhao, O. (2022a). Global buckling and design of hot-rolled stainless steel channel section beam–columns. Thin-Walled Structures, 170, 108433.CrossRef

Li, S., Zhang, L., & Zhao, O. (2022b). Testing, modelling and design of hot-rolled stainless steel channel sections under combined compression and minor-axis bending moment. Thin-Walled Structures, 172, 108836.CrossRef

Mohammad, R. H., & David, A. N. (2012). Local and distortional buckling of cold-formed steel beams with edge-stiffened flanges. Journal of Constructional Steel Research, 73, 31–42.CrossRef

Niu, S., Rasmussen, K. J. R., Asce, M., Feng, F. (2015a). Local-global interaction buckling of stainless steel I-beams. I: Experimental investigation. Journal of Structural Engineering, 141(8): 04014194.

Niu, S., Rasmussen, K. J. R., Asce, M., Feng, F. (2015b). Local-global interaction buckling of stainless steel I-beams. II: Numerical study and design. Journal of Structural Engineering, 41(8): 04014195.

Rossi, B., Jaspart, J. P., & Rasmussen, K. J. R. (2010a). Combined distortional and overall flexural-torsional buckling of cold-formed stainless steel sections: Experimental investigations. Journal of Structural Engineering, 136(4), 354–360.CrossRef

Rossi, B., Jaspart, J. P., & Rasmussen, K. J. R. (2010b). Combined distortional and overall flexural-torsional buckling of cold-formed stainless steel sections: Design. Journal of Structural Engineering, 136(4), 361–369.CrossRef

Schafer, B. W., & Peköz, T. (1998). Computational modeling of cold-formed steel: Characterizing geometric imperfections and residual stresses. Journal of Constructional Steel Research., 47(3), 193–210.CrossRef

Tang, J., & Young, B. (2002a). Column tests of cold-formed steel channels with complex stiffeners. Journal of Structural Engineering, 128(6), 737–745.CrossRef

Tang, J., & Young, B. (2002b). Compression tests of channels with inclined simple edge stiffeners. Journal of Structural Engineering, 129(10), 1403–1411.

Yu, C., & Schafer, B. W. (2003). Local buckling tests on cold-formed steel Beams. Journal of Structural Engineering, 129(12), 1596–1606.CrossRef

Technical Guide for Cold-Formed Steel Framing Products. Steel Framing Industry Association, (2012).

Wang, H. M. (2099). Study on the stability behavior of cold-formed steel flexural members. School of Civil and Engineering, Harbin Institute of Technology, Harbin.

Yu, C., & Schafer, B. W. (2006). Distortional buckling tests on cold-formed steel beams. Journal of Structural Engineering, 132(4), 515–528.CrossRef

Yuan, H. X. (2014). Local and local-overall buckling behavior of welded stainless steel members under axial compression. Tsinghua University, Beijing.

Zhang, Y. (2009). Performance research on local buckling and distortional buckling of cold-formed thin-wall C-Section steel flexural members. Chongqing University.

Title: Research on Local Buckling of Stainless Steel Lipped C-Section Beam Around Strong-Axis
Authors: Shenggang Fan
Hang Zhou
Zhixia Ding
Chenxu Li
Qinglin Jiang
Publication date: 30-07-2022
Publisher: Korean Society of Steel Construction
Published in: International Journal of Steel Structures / Issue 5/2022
Print ISSN: 1598-2351
Electronic ISSN: 2093-6311
DOI: https://doi.org/10.1007/s13296-022-00644-9

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