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Application of Multibody Simulation for Fatigue Life Estimation

M., Kamal and M. M., Rahman and M. S. M., Sani (2013) Application of Multibody Simulation for Fatigue Life Estimation. International Journal of Automotive and Mechanical Engineering (IJAME), 7. pp. 912-923. ISSN 1985-9325(Print); 2180-1606 (Online)

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In automobile design, the safety of passengers is of prime concern to the manufacturers. Suspension is one of the safety-related automotive systems which is responsible for maintaining traction between the road and tires, and offers a comfortable ride experience to the passengers by absorbing disturbances. One of the critical components of the suspension system is the knuckle, which constantly faces cyclic loads subjecting it to fatigue failure. This paper presents an evaluation of the fatigue characteristics of a knuckle using a gravel road profile acquired using a data acquisition system and standard SAE profiles for the suspension (SAESUS), bracket (SAEBRAKT) and transmission (SAETRN). The gravel road profile was applied as the input to a multi body simulation (MBS), and the load history for various mounting points of the knuckle is extracted. Fatigue life is predicted using the strain-life method. The instantaneous stress distributions and maximum principal stress are used for fatigue life predictions. From the results, the strut connection is found to be the critical region for fatigue failure. The fatigue life from loading extracted from gravel road MBS agreed well with the life prediction when standard SAE profiles were used. This close agreement shows the effectiveness of the load extraction technique from MBS. This method can also be effectively used for more complex loading conditions that occur during real driving environments.

Item Type: Article
Uncontrolled Keywords: Fatigue; multibody simulation; suspension system; knuckle; strain-life method; maximum principal stress.
Subjects: T Technology > TJ Mechanical engineering and machinery
Faculty/Division: Centre of Excellence: Automotive Engineering Centre
Centre of Excellence: Automotive Engineering Centre

Faculty of Mechanical Engineering
Depositing User: Ms Noor Fateeha Mohamad
Date Deposited: 02 Nov 2015 04:33
Last Modified: 23 Jan 2018 00:31
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