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Reliability Analysis for Cyclic Fatigue Life Prediction in Railroad Bolt Hole
Authors: Hasan Keshavarzian, Tayebeh Nesari
Abstract:
Bolted rail joint is one of the most vulnerable areas in railway track. A comprehensive approach was developed for studying the reliability of fatigue crack initiation of railroad bolt hole under random axle loads and random material properties. The operation condition was also considered as stochastic variables. In order to obtain the comprehensive probability model of fatigue crack initiation life prediction in railroad bolt hole, we used FEM, response surface method (RSM), and reliability analysis. Combined energy-density based and critical plane based fatigue concept is used for the fatigue crack prediction. The dynamic loads were calculated according to the axle load, speed, and track properties. The results show that axle load is most sensitive parameter compared to Poisson’s ratio in fatigue crack initiation life. Also, the reliability index decreases slowly due to high cycle fatigue regime in this area.Keywords: Rail-wheel tribology, rolling contact mechanic, finite element modeling, reliability analysis.
Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1132106
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D. F. Cannon, K.-O. Edel, S. L. Grassie, K. Sawley, Rail defects: an overview. Fatigue Fract. Engng Mater Struct 26, 2003, pp. 865-887.[2] U. Zerbst, R. Lunden, K.-O. Edel, R. A. Smith, Introduction to the damage tolerance behavior of railway rails – a review. J. Eng Fract Mech76, 2009, pp. 2563-2601.
[3] Zefeng Wen, Xuesong Jin, Weihua Zhang, Contact-impact stress analysis of rail joint using the dynamic finite element method. J. Wear 358, 2005, pp. 1301-1309.
[4] Ronald A. Mayville, Peter D. Hilton, Fracture mechanics analysis of rail-end bolt hole crack. Theoret appl. Fract. Mech. 1, 1984, pp. 51-60.
[5] R. A. Mayville, R. G. Stringfellow. Numerical analysis of a railroad bolt hole fracture mechanics. Theoret appl. Fract. Mech. 24, 1995, pp. 1-12.
[6] H. Kataoka, N. Abe, O. Wakatsuki. Evaluation of service life of jointed rails. QR of RTRI 43, 2002, pp. 101-106.
[7] Y. Cheng, D. Chen, F. Nogata. Fatigue behavior of rail steel under low and high loading rates. Fatigue Fract. Eng. Master. Sci 17, 1994, pp. 113-118.
[8] D.K. Arnold, E.C. Joel. Analysis and test of bonded insulated rail joints subjected to vertical wheel load. Int. J. Mech. Sci 41, 1991, pp. 1253-1272.
[9] Wu Cai, Zefeng Wen, Xuesong Jin, Wanming Zhai. Dynamic stress analysis of rail joint with height difference defect using finite element mrthod. J. Eng Failure Analysis 14, 2007 pp. 1488-1499.
[10] K. Ding, M. Danasekar. Flexural Behavior of Bonded-Bolted Butt Joints Due to Bolt Looseness. J. Advances. Eng. Software 38, 2007, pp. 598-606.
[11] Brandon Talamini, David Y. Jeong, Jeff Gordon. Estimation of Fatigue Life of Railroad Joint Bars. ASME/IEEE joint rail conference & internal combustion engine, Colorado, USA. March, 2007, pp. 13-16 .
[12] Anne K. Himebaugh, Raymond H. Plaut, David A. Dillard. Finite Element Analysis of Bonded Insulated Rail Joints. Int .J. Adhesion & Adhesives28, 2008, pp. 142-150.
[13] W. Jianxi, X. Yude, L. Songliang, W. Liying. Probabilistic Prediction Model for Initiation of RCF Cracks in Heavy-Haul Railway. Int. J. Fatigue 33, 2011, pp. 212-216.
[14] B. L. Josefson, J.W. Ringsberg. Assessment of Uncertainties in Life Prediction of Fatigue Initiation and Propagation In Welded Rails. Int. J. Fatigue 31, 2009, pp. 1413-1421.
[15] S. Mohammadzadeh, M. Sharavi, H. Keshavarzian. Reliability analysis of fatigue crack initiation of railhead in boltea rail joint. Eng. Failure Analysis, 29, 2013, pp. 132-148.
[16] Yongming Liu, Liming Liu, Brant Stratman, Sankaran Mahadevan. Multiaxial Fatigue Reliability Analysis of Railroad Wheels. J. Reliability Eng. & Sys. Safety 93, 2008, pp. 456-467.
[17] H.H Jenkins, J.E Stephenson, G.A Clayton, G.W Morland, D Lyon. The Effect of Track and Vehicle Parameters in Wheel/Rail Vertical Dynamic Forces. Railway Eng. J, 2, 1974, pp. 2-16.
[18] W. Ringsberg, Jonas. Life Prediction of Rolling Contact Fatigue Crack Initiation. Int. J. Fatigue 23, 2001, 575-589.
[19] J. Das, S.M. Sivakumar. An Evaluation of Multiaxial Fatigue Life Assessment Methods for Engineering Component. Int. J. Pressure Vessel & Piping 76, 1999, pp. 741-746.
[20] S.K. Choi, R.V. Grandhi, R.A. Canfild. Reliability-Based Structural Design. Springer-Verlag London, 2007.