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http://dx.doi.org/10.12989/sem.2017.63.6.799

Dominant failure modes identification and structural system reliability analysis for a long-span arch bridge  

Gao, Xin (College of Construction Engineering, Jilin University)
Li, Shunlong (Department of Civil Engineering, Harbin Institute of Technology)
Publication Information
Structural Engineering and Mechanics / v.63, no.6, 2017 , pp. 799-808 More about this Journal
Abstract
Failure of a redundant long-span bridge is often described by innumerable failure modes, which make the structural system reliability analysis become a computationally intractable work. In this paper, an innovative procedure is proposed to efficiently identify the dominant failure modes and quantify the structural reliability for a long-span bridge system. The procedure is programmed by ANSYS and MATLAB. Considering the correlation between failure paths, a new branch and bound operation criteria is applied to the traditional stage critical strength branch and bound algorithm. Computational effort can be saved by ignoring the redundant failure paths as early as possible. The reliability of dominant failure mode is computed by FORM, since the limit state function of failure mode can be expressed by the final stage critical strength. PNET method and FORM for system are suggested to be the suitable calculation method for the bridge system reliability. By applying the procedure to a CFST arch bridge, the proposed method is demonstrated suitable to the system reliability analysis for long-span bridge structure.
Keywords
long-span arch bridge; system reliability; dominant failure mode; identification strategy; branch-and-bound;
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Times Cited By KSCI : 5  (Citation Analysis)
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1 Chen, H.P. and Xiao, N. (2015), "Symptom-based reliability analyses and performance assessment of corroded reinforced concrete structures", Struct. Eng. Mech., 53(6), 1183-1200.   DOI
2 Chen, Z., Cai, Q., Lei, Y. and Zhu, S. (2014), "Damage detection of long-span bridges using stress influence lines incorporated control charts", Sci. China Technol. Sci., 57(9), 1689-1697.   DOI
3 Cheng, J. and Xiao, R.C. (2005), "Serviceability reliability analysis of cable-stayed bridges", Struct. Eng. Mech., 20(6), 609-630.   DOI
4 Cho, T.J. (2007), "Risk assessment for a steel arch bridge system based upon response surface method compared with system reliability", J. Comput. Struct. Eng. Inst. Korea, 20(3), 273-279.
5 Corotis, R.B. and Nafday, A.M. (1989), "Structural system reliability using linear programming and simulation", J. Struct. Eng., 115(10), 2435-2447.   DOI
6 Ditlevsen, O. and Bjerager, P. (1989), "Plastic reliability analysis by directional simulation", J. Eng. Mech., 115(6), 1347-1362.   DOI
7 Dong, C. (2001). Development on Modern Reliability Analysis Theory of Structural Systems and it's Applications, Science Press, Beijing.
8 Gao, X., Wang, L. and Zhang, T. (2013), "Significant failure mode identification for a CFST arch bridge system", Key Eng. Mater., 540, 11-19.   DOI
9 GB/T50283-1999 (1999). Unified Standard for Reliability Design of Highway Engineering Structures, Ministry of Construction, P.R.China Beijing, China.
10 Hohenbichler, M. and Rackwitz, R. (1983), "First-order concepts in system reliability", Struct. Saf., 1(3), 177-188.   DOI
11 Kim, D.S., Ok, S.Y., Song, J. and Koh, H.M. (2013), "System reliability analysis using dominant failure modes identified by selective searching technique", Reliab. Eng. Syst. Saf., 119(0), 316-331.   DOI
12 Melchers, R.E. (1994), "Structural system reliability assessment using directional simulation", Struct. Saf., 16(1), 23-37.   DOI
13 Lee, Y.J. and Song, J. (2011), "Risk analysis of fatigue-induced sequential failures by branch-and-bound method employing system reliability bounds", J. Eng. Mech., 137(12), 807-821.   DOI
14 Lee, Y.J. and Song, J.H. (2012), "Finite-element-based system reliability analysis of fatigue-induced sequential failures", Reliab. Eng. Syst. Saf., 108, 131-141.   DOI
15 Ma, H. and Ang, A.H. (1981), Reliability Analysis of Redundant Ductile Structural Systems.
16 Moses, F. and Rashedi, M.R. (1983), "Application of system reliability to structural safety", Proceedings, 4th International Conference - Applications of Statistics and Probability in Soil and Structural Engineering, Florence, Italy.
17 Moyo, P., Brownjohn, J.M.W. and Omenzetter, P. (2004), "Highway bridge live loading assessment and load carrying capacity estimation using a health monitoring system", Struct. Eng. Mech., 18(5), 609-626.   DOI
18 Nowak, A.S. and Cho, T. (2007), "Prediction of the combination of failure modes for an arch bridge system", J. Constr. Steel Res., 63(12), 1561-1569.   DOI
19 Rackwitz, R. (2001), "Reliability analysis--a review and some perspectives", Struct. Saf., 23(4), 365-395.   DOI
20 Rashedi, R. and Moses, F. (1986), "Application of linear programming to structural system reliability", Comput. Struct., 24(3), 375-384.   DOI
21 Shao, S. and Murotsu, Y. (1999), "Approach to failure mode analysis of large structures", Probab. Eng. Mech., 14(1-2), 169-177.   DOI
22 Zhu, S., Chen, Z., Cai, Q., Lei, Y. and Chen, B. (2014b), "Locate damage in long-span bridges based on stress influence lines and information fusion technique", Adv. Struct. Eng., 17(8), 1089-1102.   DOI
23 Thoft-Christensen, P. and Murotsu, Y. (1986). Application of Structural Systems Reliability Theory, Springer-Verlag, Berlin.
24 Wang, L., Wang, X. and Li, X. (2016b), "Inverse system method for dynamic loads identification via noisy measured dynamic responses", Eng. Comput., 33(4), 1070-1094.   DOI
25 Wang, L., Wang, X., Wang, R. and Chen, X. (2016a), "Reliability-based design optimization under mixture of random, interval and convex uncertainties", Arch. Appl. Mech., 86(7), 1341-1367.   DOI
26 Weng, M.X. and Lei, Y. (2016), "Probability analysis of structure damage identification including system uncertainty", Gongch. Lixue/Eng. Mech., 33, 29-32.
27 Zhu, J.S., Chen, C. and Han, Q.H. (2014a), "Vehicle-bridge coupling vibration analysis based fatigue reliability prediction of prestressed concrete highway bridges", Struct. Eng. Mech., 49(2), 203-223.   DOI