Fracture Failure Analysis of Rear Axle Suspension Control Arm in Automobile

Li, ZhengYuan; Gao, Yang; Xiao, QingHe

doi:10.64486/m.65.1.3

Metallurgy, Vol. 65 No. 1, 2026.

Original scientific paper

https://doi.org/10.64486/m.65.1.3

Fracture Failure Analysis of Rear Axle Suspension Control Arm in Automobile

ZhengYuan Li ; University Science and Technology Liaoning, College of applied technology, Anshan, China *
Yang Gao ; University Science and Technology Liaoning, College of applied technology, Anshan, China
QingHe Xiao ; University Science and Technology Liaoning, College of applied technology, Anshan, China *

* Corresponding author.

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APA 6th Edition

Li, Z., Gao, Y. & Xiao, Q. (2026). Fracture Failure Analysis of Rear Axle Suspension Control Arm in Automobile. Metalurgija, 65 (1), 28-36. https://doi.org/10.64486/m.65.1.3

MLA 8th Edition

Li, ZhengYuan, et al. "Fracture Failure Analysis of Rear Axle Suspension Control Arm in Automobile." Metalurgija, vol. 65, no. 1, 2026, pp. 28-36. https://doi.org/10.64486/m.65.1.3. Accessed 5 Dec. 2025.

Chicago 17th Edition

Li, ZhengYuan, Yang Gao and QingHe Xiao. "Fracture Failure Analysis of Rear Axle Suspension Control Arm in Automobile." Metalurgija 65, no. 1 (2026): 28-36. https://doi.org/10.64486/m.65.1.3

Harvard

Li, Z., Gao, Y., and Xiao, Q. (2026). 'Fracture Failure Analysis of Rear Axle Suspension Control Arm in Automobile', Metalurgija, 65(1), pp. 28-36. https://doi.org/10.64486/m.65.1.3

Vancouver

Li Z, Gao Y, Xiao Q. Fracture Failure Analysis of Rear Axle Suspension Control Arm in Automobile. Metalurgija [Internet]. 2026 [cited 2025 December 05];65(1):28-36. https://doi.org/10.64486/m.65.1.3

IEEE

Z. Li, Y. Gao and Q. Xiao, "Fracture Failure Analysis of Rear Axle Suspension Control Arm in Automobile", Metalurgija, vol.65, no. 1, pp. 28-36, 2026. [Online]. https://doi.org/10.64486/m.65.1.3

Abstract

Fracture failure occurred in the control arm of the rear axle suspension of a certain vehicle model. To determine the root cause of the failure, comprehensive analyses were conducted, including macroscopic fracture examination, microscopic frac-ture analysis, microstructural characterization, and hardness testing. The results indicate that the failure was caused by the combined effects of material defects, improper manufacturing processes, and service loading conditions. The funda-mental cause of the fracture lies in the initiation of microcracks at the interface between coarse Al-Fe-Si-Mn inclusions and the matrix under cyclic loading. The presence of a strength gradient induced by local segregation of Si further acceler-ated crack propagation along the inclusion/matrix interface. Under cyclic stress, the cracks propagated progressively through a fatigue striation mechanism and exhibited intergranular fracture in the precipitation-enriched zones along grain boundaries. Ultimately, these factors led to premature fatigue failure of the control arm.

Keywords

control arm; fracture analysis; fatigue striation mechanism; intergran-ular fracture

Hrčak ID:

336465

URI

https://hrcak.srce.hr/336465

Publication date:

1.1.2026.

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Metallurgy, Vol. 65 No. 1, 2026.

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