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Transient thermomechanical analysis of automotive disc brake with gray cast iron composition

Published online by Cambridge University Press:  13 November 2012

A. Belhocine  and
M. Bouchetara
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Abstract

The vehicle braking system is considered as one of the most fundamental safety-critical systems in modern vehicles as its main purpose is to stop or decelerate the vehicle. The frictional heat generated during braking application can cause numerous negative effects on the brake assembly such as brake fade, premature wear, thermal cracks and disc thickness variation (DTV). In this paper, transient and contact analysis of the brake disc is presented. The analysis was carried out using ANSYS Multiphysics 11.0 based on the thermomechanical coupled case. The temperature distribution obtained by the transient thermal analysis is used in the calculations of the stresses on the disc surface. The results presented are for the temperature during contact, for different values of time, deformations established in the disc, total stress and pressure contact distribution in the pads. The results obtained by the simulation are satisfactory compared with those of the specialized literature.

Keywords

Brake discspadsheat transfer coefficientVon Mises stresscontact pressure
Type
Research Article
Information
Metallurgical Research & Technology , Volume 109 , Issue 6: Light Alloys for Transport , 2012 , pp. 427 - 441
Copyright
© EDP Sciences 2012

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References

D. Majcherczak, P. Dufrénoy, M. Naït-Abdelaziz, Thermal simulation of a dry sliding contact using a multiscale model-application to the braking problem, Thermal stresses, Osaka (Japan), 2001, pp. 437-440
Colin, F., Floquet, A., Play, D., ASME J. Tribol. 110 (1988) 247-252
Choi, J.H., Lee, I., Journal of Thermal Stresses 26 (2003) 223-244
Choi, J.H., Lee, I., Wear 257 (2004) 47-58
Gao, C.H., Lin, X.Z., J. Mater. Proc. Technol. 129 (2002) 513-517
Gao, C.H., Huang, J.M., Lin, X.Z., Tang, X.S., J. Tribol. Trans. ASME 129 (2007) 536-543
P. Hwang, X .Wu, S.W.Cho, Y.B. Jeon, Temperature and coning analysis of ventilated brake disc based on finite element technique, SAE 2007-01-3670, 2007
P. Hwang, X. Wu, Y.B. Jeon, Repeated brake temperature analysis of ventilated brake disc on the downhill road, SAE 2008-01-2571, 2008
J. Reimpel, Technologie de freinage, Vogel Verlag, Würzburg, 1998
P. Gotowicki, F. Nigrelli, V. Mariotti, Numerical and experimental analysis of a pegs- wing ventilated disk brake rotor, with pads and cylinders, 10 th EAEC European Automotive Congress – Paper EAEC05YU- AS04–P 5, 2005
G. Dhatt, G. Touzot, Une présentation de la méthode des éléments finis, Malouine S.A., Paris, 1984
Y. Debard, Méthode des éléments finis : Modélisation Numérique et Réalité Virtuelle, Master Université du Maine, mars 2006
K.-J. Bathe, Finite element procedures in engineering analysis, Englewood Cliffs, New Jersey, 1996
K.H. Huebner, E.A. Thornton, T.G. Byron, The finite element method for engineers. New York : John Wiley & Sons, 3rd ed., 1995
R.W. Lewis, K. Morgan, H. Thomas, K.N. Seetharamu, The finite element method in heat transfer analysis, John Wiley & Sons, Chichester, 1996
H.C. Galindo-Lopez, Evaluating new ways of conducting convective heat dissipation experiments with ventilated brake discs Cranfield University, Bedfordshire, MK43 OAL, UK
N. Coudeyras, Analyse non –linéaire des instabilités multiples aux interfaces frottantes : application au crissement de frein, Thèse de doctorat de l’École Centrale de Lyon spécialité : mécanique, 2009