Fatigue life assessment of welded joints in a crane boom using different structural stress approaches

Authors

  • Brahami Riad Laboratoire de Génie de la Construction et Architecture (LGCA), Faculté de Technologie, Université de Bejaia, 06000 Bejaia, Algeria Phone : +213 664429440
  • Hamri Okba Laboratoire de Génie Mécanique et Développement (LGMD), Ecole Nationale Polytechnique, 16200 Alger, Algeria
  • Sfarni Samir Laboratoire de Génie de la Construction et Architecture (LGCA), Faculté de Technologie, Université de Bejaia, 06000 Bejaia, Algeria Phone : +213 664429440

DOI:

https://doi.org/10.15282/jmes.13.2.2019.20.0417

Keywords:

Fatigue assessment, Welded joints, Structural stress approach, Finite element analysis, Fatigue strength

Abstract

This article presents a study of the fatigue strength of welded parts in a crane boom. First, a finite element analysis was carried out over the whole structure. Two critical welded zones were identified and a detailed analysis was carried on them, in the form of sub-models. Three different approaches for estimating the structural stress in welded zones, were presented and applied to each sub-model. Results were compared and discussed. The evaluation of fatigue resistance by the use of appropriate S-N curves for each method was also carried out and discussed. The use of these approaches on a complex industrial structure, and on tubular joints with hollow sections required to perform many adaptations and to solve several difficulties presented hereafter.

References

Standards E. Eurocode 3: Design of steel structures - Part 1-9: Fatigue. vol. 1. 2005.

BSI. BSI Standards Publication Guide to fatigue design and assessment of steel products. BSI; 2014.

Zhao XL, Packer JA. Fatigue design procedure for welded hollow section joints: Recommendations of IIW subcommission XV-E. Abington Publishing; 2000.

Hobbacher A. Recommendations for fatigue design of welded joints and components. Second Edition. Springer International Publishing; 2016.

Niemi E. Stress determination for fatigue analysis of welded Components. Cambridge CB 1 6AH, England: Abington Publishing; 1995.

Fricke W. Fatigue analysis of welded joints: State of development. Marine Structures. 2003;16:185–200.

Temarel P, Chen XB, Ergin A, Hermanski G, Hermundstad OA, Hirdaris SE. 17th International Ship and Offshore Structures Congress. ISSC, 2009;1:127–210.

Aygül M, Al-Emrani M, Urushadze S. Modelling and fatigue life assessment of orthotropic bridge deck details using FEM. International Journal of Fatigue. 2012;40:129–142.

Hobbacher AF. The new IIW recommendations for fatigue assessment of welded joints and components - A comprehensive code recently updated. International Journal of Fatigue. 2009;31:50–58.

Radaj D. Design and analysis of fatigue resistant welded structures. Cambridge England: Woodhead Publishing Ltd; 1990.

Radaj D, Sonsino C.M, Fricke W. Fatigue assessment of welded joints by local approaches. Second edition. Cambridge England: Woodhead Publishing Limited; 2006;136.

Poutiainen I, Tanskanen P, Marquis G. Finite element methods for structural hot spot stress determination - A comparison of procedures. International Journal of Fatigue. 2004;26:1147–1157.

Lee JM, Seo JK, Kim MH, Shin SB, Han MS, Park JS. Comparison of hot spot stress evaluation methods for welded structures. International Journal of Naval Architecture and Ocean Engineering. 2010;2:200–210.

Radaj D. Review of fatigue strength assessment of nonwelded and welded structures based on local parameters. International Journal of Fatigue. 1996;18:153–170.

Gorash Y, Comlekci T, Mackenzie D. Comparative study of FE-models and material data for fatigue life assessments of welded thin-walled cross-beam connections. Procedia Engineering. 2015;133:420–432.

Fricke W, Kahl A. Comparison of different structural stress approaches for fatigue assessment of welded ship structures. Marine Structures. 2005;18:473–488.

Kim MH, Kim SM, Kim YN, Kim SG, Lee KE, Kim GR. A comparative study for the fatigue assessment of a ship structure by use of hot spot stress and structural stress approaches. Ocean Engineering. 2009;36:1067–1072.

Niemi E, Fricke W, Maddox SJ. Structural hot-spot stress approach to fatigue analysis of welded components. Springer; 2018.

Dong P. A structural stress definition and numerical implementation for fatigue analysis of welded joints. International Journal of Fatigue. 2001;23:865–876.

Xiao ZG, Yamada K. A method of determining geometric stress for fatigue strength evaluation of steel welded joints. International Journal of Fatigue. 2004;26:1277–1293.

Kim Y, Oh JS, Jeon SH. Novel hot spot stress calculations for welded joints using 3D solid finite elements. Marine Structures. 2015;44:1–18.

Shen W, Yan R, Barltrop N, Liu E, Song L. A method of determining structural stress for fatigue strength evaluation of welded joints based on notch stress strength theory. International Journal of Fatigue. 2016;90:87–98.

Kyuba H, Dong P. Equilibrium-equivalent structural stress approach to fatigue analysis of a rectangular hollow section joint. International Journal of Fatigue. 2005;27:85–94.

Dong P, Hong JK, De Jesus AMP. Analysis of recent fatigue data using the structural stress procedure in ASME Div 2 Rewrite. Journal of Pressure Vessel Technology. 2007;129:355–362.

Dong P, Pei X, Xing S. A structural strain method for fatigue evaluation of welded components. San Francisco, California, USA: ASME; 2014, p. V005T03A037.

Dong P, Cao Z, Hong JK. Low cycle fatigue evaluation using the weld master

S-N curve. ASME Pressure Vessels and Piping Division Conference 2006:1–10.

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Published

2019-06-28

How to Cite

[1]
B. Riad, H. Okba, and S. Samir, “Fatigue life assessment of welded joints in a crane boom using different structural stress approaches”, J. Mech. Eng. Sci., vol. 13, no. 2, pp. 5048–5073, Jun. 2019.

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