Commenced in January 2007
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Comparative Safety Performance Evaluation of Profiled Deck Composite Slab from the Use of Slope-Intercept and Partial Shear Methods
Authors: Izian Abd. Karim, Kachalla Mohammed, Nora Farah A. A. Aziz, Law Teik Hua
Abstract:
The economic use and ease of construction of profiled deck composite slab is marred with the complex and un-economic strength verification required for the serviceability and general safety considerations. Beside these, albeit factors such as shear span length, deck geometries and mechanical frictions greatly influence the longitudinal shear strength, that determines the ultimate strength of profiled deck composite slab, and number of methods available for its determination; partial shear and slope-intercept are the two methods according to Euro-code 4 provision. However, the complexity associated with shear behavior of profiled deck composite slab, the use of these methods in determining the load carrying capacities of such slab yields different and conflicting values. This couple with the time and cost constraint associated with the strength verification is a source of concern that draws more attentions nowadays, the issue is critical. Treating some of these known shear strength influencing factors as random variables, the load carrying capacity violation of profiled deck composite slab from the use of the two-methods defined according to Euro-code 4 are determined using reliability approach, and comparatively studied. The study reveals safety values from the use of m-k method shows good standing compared with that from the partial shear method.Keywords: Composite slab, first order reliability method, longitudinal shear, partial shear connection, slope-intercept.
Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1107860
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[1] Gholamhoseini, A., et al., Longitudinal Shear Stress and Bond–Slip Relationships in Composite Concrete Slabs. Engineering Structures, 2014. 69(0): p. 37-48.
[2] Degtyarev, V., Reliability-Based Evaluation of U.S. Design Provisions for Composite Steel Deck in Construction Stage. Journal of Structural Engineering, 2012. 138(3): p. 308-317.
[3] Marimuthu, V., et al., Experimental Studies on Composite Deck Slabs to Determine the Shear-Bond Characteristic Values of the Embossed Profiled Sheet. Journal of Constructional Steel Research, 2007. 63(6): p. 791-803.
[4] Tsalkatidis, T. and A. Avdelas. The Unilateral Contact Problem in Composite Slabs: Experimental Study and Numerical Treatment. Journal of Constructional Steel Research, 2010. 66(3): p. 480-486.
[5] Chen, S., Load Carrying Capacity of Composite Slabs with Various End Constraints. Journal of Constructional Steel Research, 2003. 59(3): p. 385-403.
[6] Burnet, M.J. and D.J. Oehlers, Rib Shear Connectors in Composite Profiled Slabs. Journal of Constructional Steel Research, 2001. 57(12): p. 1267-1287.
[7] Tenhovuori, A.I. and M.V. Leskelä, Longitudinal Shear Resistance of Composite Slabs. Journal of Constructional Steel Research, 1998. 46(1– 3): p. 228.
[8] Marčiukaitis, G., B. Jonaitis, and J. Valivonis, Analysis of Deflections of Composite Slabs with Profiled Sheeting up to the Ultimate Moment. Journal of Constructional Steel Research, 2006. 62(8): p. 820-830.
[9] Tzaros, K.A., E.S. Mistakidis, and P.C. Perdikaris, A Numerical Model Based on Nonconvex–Nonsmooth Optimization for the Simulation of Bending Tests on Composite Slabs with Profiled Steel Sheeting. Engineering Structures, 2010. 32(3): p. 843-853.
[10] Abdullah, R. and W. Samuel Easterling, New Evaluation and Modeling Procedure for Horizontal Shear Bond in Composite Slabs. Journal of Constructional Steel Research, 2009. 65(4): p. 891-899.
[11] EC4, Eurocode: 4 in Design of Composite Steel and Concrete Structures. Part1.1: General Rules and Rules for Building (PrEN 1994-1- 1:2003)2003, European committee for standardization.
[12] Cifuentes, H. and F. Medina, Experimental Study on Shear Bond Behavior of Composite Slabs According to Eurocode 4. Journal of Constructional Steel Research, 2013. 82(0): p. 99-110.
[13] Hedaoo, N., L. Gupta, and G. Ronghe, Design of Composite Slabs with Profiled Steel Decking: A Comparison between Experimental and Analytical Studies. International Journal of Advanced Structural Engineering, 2012. 4(1): p. 1.
[14] Johnson, R.P., Composite Structures of Steel and Concrete. Second ed. Vol. 1 Beams, Slabs, Columns and Frames for Building. 2004: Blackwell Publishing, London. 228.
[15] Stephen, H., Composite Slab, in EN 1994-Eurocode 4: Design of Composite Steel and Concrete Structures, 2008, The Steel Construction Institute: Silwood Park, Ascot, Berkshire, SL5 7QN, United Kingdom.
[16] Ganesh, G.M., A. Upadhyay, and S.K. Kaushik, Simplified Design of Composite Slabs Using Slip Block Test. Journal of Advanced Concrete Technology, 2005. 3(3): p. 403-412.
[17] Okasha, N. and M. Aichouni, Proposed Structural Reliability-Based Approach for the Classification of Concrete Quality. Journal of Materials in Civil Engineering, 2014. 0(0): p. 04014169.
[18] Adrzej, S.N., M.R. Anna, and K.S. Ewa, Revised Statistical Resistance Model for Reinforced Concrete Structural Component. ACI, 2012. 284: p. 1-16.
[19] Melchers, R.E., Structural Reliability Analysis and Prediction, 1999, Newyork: Wiley.
[20] Ellingwood, B. and T.V. Galambos, Probability-Based Criteria for Structural Design. Structural Safety, 1982. 1(1): p. 15-26.
[21] Liu, J., Y. Tian, and S. Orton, Vulnerability of Disproportionate Collapse in Older Flat Plate Buildings Subjected to Sudden Removal of a Bearing Column, in Structures Congress 20132013. p. 2814-2823.
[22] Mohammed, B.S., Structural Behavior and m–k Value of Composite Slab Utilizing Concrete Containing Crumb Rubber. Construction and Building Materials, 2010. 24(7): p. 1214-1221.