Authors: J. Marzbanrad, A. Yadollahi

Abstract:

In the present paper, Fatigue life assessment of an anti-roll bar component of a passenger vehicle, is investigated by ANSYS 11 software. A stress analysis is also carried out by the finite element technique for the determination of highly stressed regions on the bar. Anti-roll bar is a suspension element used at the front, rear, or at both ends of a car that reduces body roll by resisting any unequal vertical motion between the pair of wheels to which it is connected. As a first stage, fatigue damage models proposed by some well-known references and the corresponding assumptions are discussed and some enhancements are proposed. Then, fracture analysis of an anti-roll bar of an automobile is carried out. The analysed type of the anti-roll bar is especially important as many cases are reported about the fracture after a 100,000 km of travel fatigue and fracture conditions. This paper demonstrates fatigue life of an anti-roll bar and then evaluated by experimental analytically results from other researcher.

Keywords: Anti-roll bar, Fracture, Fatigue life, Random loading

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1083111

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References:

[1] H. Heisler, "Vehicle and engine technology," 2nd ed. London: SAE International, 1999.
[2] TD. Gillespie, "Fundamentals of vehicle dynamics," SAE Publication, 1992.
[3] A. Fatemi, L. Yang, "Cumulative fatigue damage and life prediction theories: a survey of the state of the art for homogeneous materials," Int J Fatigue, vol. 20, no. 1, pp. 9-34, 1998.
[4] P. Haupt, "Continuum mechanics and theory of materials," Springer- Verlag, 2002.
[5] G. Sines, "Behavior of metals under complex stresses," In Metal fatigue, G. Sines, JL. Waisman, Ed. New York: McGraw-Hill, 1959.
[6] YC. Fung, P. Tong, "Classical and computational solid mechanics," World Scientific Publishing Co. Inc., 2001.
[7] WN. Findley, "A theory for effect of mean stress on fatigue of metals under combined torsion and axial load or bending," J Eng Ind, pp. 301- 6, 1959.
[8] MW. Brown, KJ. Miller, "A theory for fatigue failure under multiaxial stress-strain conditions," Proc Inst Mech Eng, vol. 187, no. 65, pp. 745- 55, 1973.
[9] A. Carpinteri, R. Brighenti, and A. Spagnoli, "A fracture plane approach in multiaxial high-cycle fatigue of metals," Fatigue Fract Eng Mater Struct, vol. 23, no. 4, pp. 355-64, 2000.
[10] A. Carpinteri, A. Spagnoli, "Multiaxial high-cycle fatigue criterion for hard metals," Int J Fatigue,vol. 23, pp. 135-45, 2001.
[11] A. Spagnoli, "A new high-cycle fatigue criterion applied to out-ofphase biaxial stress state," Int J Mech Sci, vol. 43, pp. 2581-95, 2001.
[12] HJ. Gough, HV. Pollard, "The strength of metals under combined alternating stresses," Proc Inst Mech Eng, vol. 131, pp. 1-103, 1935.
[13] Y. Liu, S. Mahadevan, "A unified multiaxial fatigue damage model for isotropic and anisotropic materials," Int J Fatigue,vol. 29, pp. 347-59, 2007.
[14] DH. Wright, "Testing automotive materials and components," McGraw- Hill Publishing Co., 1993.
[15] M. Shariyat, "A fatigue model developed by modification of Gough-s theory, for andom non-proportional loading conditions and threedimensional stress fields," Int J Fatigue, vol. 30, pp. 1248-1258, 2008.
[16] J. Schijve, "Fatigue of structures and materials," Secaucus, (NJ, USA): Kluwer Academic Publishers, 2001.
[17] ANSYS 5.4 versions users manual.
[18] M. Shariyat, A. Ganjidoust, "Fatigue failure and damage analysis of an anti-roll bar under random fatigue tests," Journal of Solid Mechanics, pp. 3-20, 2010.