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http://dx.doi.org/10.12989/sss.2015.16.2.367

Reliability-based assessment of steel bridge deck using a mesh-insensitive structural stress method  

Ye, X.W. (Department of Civil Engineering, Zhejiang University)
Yi, Ting-Hua (School of Civil Engineering, Dalian University of Technology)
Wen, C. (School of Civil Engineering, Lanzhou University of Technology)
Su, Y.H. (School of Civil Engineering, Lanzhou University of Technology)
Publication Information
Smart Structures and Systems / v.16, no.2, 2015 , pp. 367-382 More about this Journal
Abstract
This paper aims to conduct the reliability-based assessment of the welded joint in the orthotropic steel bridge deck by use of a mesh-insensitive structural stress (MISS) method, which is an effective numerical procedure to determine the reliable stress distribution adjacent to the weld toe. Both the solid element model and the shell element model are first established to investigate the sensitivity of the element size and the element type in calculating the structural stress under different loading scenarios. In order to achieve realistic condition assessment of the welded joint, the probabilistic approach based on the structural reliability theory is adopted to derive the reliability index and the failure probability by taking into account the uncertainties inherent in the material properties and load conditions. The limit state function is formulated in terms of the structural resistance of the material and the load effect which is described by the structural stress obtained by the MISS method. The reliability index is computed by use of the first-order reliability method (FORM), and compared with a target reliability index to facilitate the safety assessment. The results achieved from this study reveal that the calculation of the structural stress using the MISS method is insensitive to the element size and the element type, and the obtained structural stress results serve as a reliable basis for structural reliability analysis.
Keywords
orthotropic steel bridge deck; welded joints; hot spot stress; finite element analysis; reliability index; failure probability;
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Times Cited By KSCI : 3  (Citation Analysis)
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1 AASHTO (2012), AASHTO LRFD Bridge Design Specifications, 6th Edition, American Association of State Highway and Transportation Officials, Washington D.C., USA.
2 Aygul, M., Al-Emarani, M. and Urushadze, S. (2012), "Modelling and fatigue life assessment of orthotropic bridge deck details using FEM", Int. J. Fatigue, 40, 129-142.   DOI
3 Braml, T., Taffe, A., Feistkorn, S. and Wurzer, O. (2013), "Assessment of existing structures using probabilistic analysis methods in combination with nondestructive testing methods", Struct. Eng. Int., 23(4), 376-385.   DOI
4 Chan, T.H.T., Zhou, T.Q., Li, Z.X. and Guo, L. (2005), "Hot spot stress approach for Tsing Ma Bridge fatigue evaluation under traffic using finite element method", Struct. Eng. Mech., 19(3), 261-279.   DOI
5 Dong, P. (2001), "Astructural stress definition and numerical implementation for fatigue analysis of welded joints", Int. J. Fatigue, 23(10), 865-876.   DOI
6 Dong, P. (2005), "A robust structural stress method for fatigue analysis of offshore/marine structures", J. Offshore Mech. Arct.., 23(10), 865-876.
7 Dong, P., Hong, J.K., Osage, D.A. and Prager, M. (2002), Master S-N Curve Approach for Fatigue Evaluation of Welded Components, Welding Research Council, New York, USA.
8 Fricke, W. (2002), "Recommended hot-spot analysis procedure for structural details of ships and FPSOs based on round-robin FE analyses", Int. J. Offshore Polar., 12(1), 40-47.
9 Gorla, R.S.R. and Tanawade, A. (2013), "Probabilistic structural and thermal analysis of a gasketed flange", Appl. Therm. Eng., 59(1-2), 535-541.   DOI
10 Hasofer, A.M. and Lind, N.C. (1974), "Exact and invariant second-moment code format", J. Eng. Mech.­-ASCE, 100(1), 111-121.
11 Hohenbichler, M. and Rackwitz, R. (1981), "Non-normal dependent vectors in structural safety", J. Eng. Mech. -ASCE, 107(6), 1227-1238.
12 IIW. (2006), Fatigue Analysis of Welded Components -Designer's Guide to the Structural Hot-spot Stress Approach, International Institute of Welding, Cambridge, UK.
13 Jakubczak, H., Sobczykiewicz, W. and Glinka, G. (2006), "Fatigue reliability of structural components", Int. J. Mater. Prod. Tec., 25(1-3), 64-83.   DOI
14 Kyuba, H. and Dong, P. (2005), "Equilibrium-equivalent structural stress approach to fatigue analysis of a rectangular hollow section joint", Int. J. Fatigue, 27(1), 85-94.   DOI
15 Ni, Y.Q., Ye, X.W. and Ko, J.M. (2010), "Monitoring-based fatigue reliability assessment of steel bridges: analytical model and application", J. Struct. Eng. -ASCE, 136(12), 1563-1573.   DOI
16 Ni, Y.Q., Ye, X.W. and Ko, J.M. (2012), "Modeling of stress spectrum using long-term monitoring data and finite mixture distributions", J. Eng. Mech. -ASCE, 138(2), 175-183.   DOI
17 Rackwitz, R. (2001), "Reliability analysis -a review and some perspectives", Struct. Saf., 23(4), 365-395.   DOI
18 Radaj, D. (1996), "Review of fatigue strength assessment of non-weld and welded structures based on local parameters", Int. J. Fatigue, 18(3), 153-170.   DOI
19 Schumacher, A. and Nussbaumer, A. (2006), "Experimental study on the fatigue behavior of welded tubular K-joints for bridges", Eng. Struct., 28(5), 745-755.   DOI
20 Su, C., Luo, J.J. and Xiao, C.F. (2013), "Efficient approach for reliability assessments on aeroinstability of long-span bridges", J. Bridge Eng.-ASCE, 18(6), 570-575.   DOI
21 Tveiten, B.W., Berge, S. and Wang, X.Z. (2013), "Fatigue assessment of aluminum ship details by hotspot stress approach", J. Offshore Mech. Arct., 135(4), 865-876.
22 Yi, T.H., Li, H.N. and Sun, H.M (2013a), "Multi-stage structural damage diagnosis method based on "energy-damage" theory", Smart Struct. Syst., 12(3-4), 345-361.   DOI
23 Yi, T.H., Li, H.N. and Gu, M. (2013b), "Wavelet based multi-step filtering method for bridge health monitoring using GPS and accelerometer", Smart Struct. Syst., 11(4), 331-348.   DOI