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Abstract

The primary fracture mode of leaf springs, which function as a spring in commercial vehicle suspension systems, is fatigue fracture. Shot peening (SP) is a surface finishing and cold working process that suppresses crack propagation and extends service life through the induction of residual stress. This study investigates the effect of residual stress on fatigue fracture. Firstly, different residual stress states were obtained by comparing the influences of SP time, prestress, and shot diameter on the residual stress of leaf springs. Secondly, a SP simulation model was developed in Abaqus to compute residual stresses. These stresses were incorporated into fatigue simulations of leaf springs using SIGINI subroutines. And the fatigue life of leaf springs was simulated using Fe-safe software. Finally, concurrent bench experiments were conducted for the purpose of verifying the results of the fatigue simulation. The simulation and experimental results have demonstrated that the surface residual compressive stress layer’s amplitude and the maximum residual compressive stress layer’s depth and amplitude, are positively correlated with SP time and shot diameter, and the optimal prestress is 1200 MPa. The maximum depth of the residual compressive stress layer most conductive to delay fatigue fracture is 0.15–0.2 mm.

Keywords

shot peening leaf spring 52CrMoV4 steel numerical simulations residual stress

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References

Maleki

Unal

Kashyzadeh

KR.

Effects of conventional, severe, over, and re-shot peening processes on the fatigue behavior of mild carbon steel. Surf Coat Technol 2018; 344: 62–74.

Deschênes

Lanteigne

Verreman

, et al. A new experimental method to study the influence of welding residual stresses on fatigue crack propagation. Int J Fatigue 2017; 100: 444–452.

Maleki

Unal

Kashyzadeh

KR.

Fatigue behavior prediction and analysis of shot peened mild carbon steels. Int J Fatigue 2018; 116: 48–67.

Cheng

Chen

Zhang

, et al. The fracture of two-layer leaf spring: experiments and simulation. Eng Fail Anal 2022; 133: 105971.

Hemmesi

Farajian

Fatemi

Application of the critical plane approach to the torsional fatigue assessment of welds considering the effect of residual stresses. Int J Fatigue 2017; 101: 271–281.

Fang

Zhang

, et al. Influence of welding residual stress on subsurface fatigue crack propagation of rail. Eng Fract Mech 2022; 271: 108642.

Maleki

Unal

Kashyzadeh

, et al. A systematic study on the effects of shot peening on a mild carbon steel: microstructure, mechanical properties, and axial fatigue strength of smooth and notched specimens. Appl Surf Sci Adv 2021; 4: 100071.

Wang

Kim

Computational fatigue analysis of the Almen strip treated with double-sided shot peening and its experimental verification. Int J Adv Manuf Technol 2024; 134: 4505–4517.

Chen

Wang

, et al. Analysis of residual stress of gear tooth root after shot peening process. Int J Adv Manuf Technol 2023; 125: 2147–2160.

10.

Meng

Zhou

, et al. Residual stress relaxation and its effects on the fatigue properties of Ti6Al4V alloy strengthened by warm laser peening. Mat Sci Eng A Struct 2017; 680: 297–304.

11.

Duan

Shang

Luo

, et al. Effects of shot peening residual stresses on fatigue crack propagation behavior of 316L. J Laser Appl 2023; 35(3): 032009.

12.

Chen

Lin

, et al. Effects of peening velocity and coverage on peen forming. Proc Inst Mech Eng Part E: J Process Mech Eng 2025; 239(3): 1523–1534.

13.

Miao

Demers

Larose

, et al. Experimental study of shot peening and stress peen forming. J Mater Process Technol 2010; 210: 2089–2102.

14.

Ohta

Analytical prediction of shot peening residual stress distribution using inherent strain in aluminum-magnesium alloy plates under various peening conditions. Int J Adv Manuf Technol 2023; 130: 3065–3079.

15.

Xiao

Tong

, et al. Numerical research on the effect of boundary constraint in shot peen forming. J Mater Eng Perform 2017; 26: 3839–3853.

16.

Xiao

Wang

Zhang

, et al. Numerical research on stress peen forming with prestressed regular model. J Mater Process Technol 2016; 229: 501–513.

17.

Wang

Platts

The optimisation of shot peen forming processes. J Mater Process Technol 2008; 206: 78–82.

18.

Guechichi

Castex

Benkhettab

An analytical model to relate shot peening Almen intensity to shot velocity. Mech Based Des Struct Mach 2013; 41: 79–99.

19.

Zhang

Liu

Gao

, et al. A combined DEM-FEM method for simulating the actual peen forming process to estimate forming effectiveness. J Manuf Process 2024; 109: 115–127.

20.

da Silva

Button

Pavanello

. Finite element impact modelling of shot peen forming. In: 21st Brazilian congress of mechanical engineering, Natal, Rio Grande do Norte, Brazil, 24–28 October 2011.

21.

Gariepy

Larose

Perron

, et al. On the effect of the orientation of sheet rolling direction in shot peen forming. J Mater Process Technol 2013; 213(6): 926–938.

22.

Faucheux

Gosselin

Levesque

Simulating shot peen forming with eigenstrains. J Mater Process Technol 2018; 254: 135–144.

23.

Xing

Zhu

, et al. Effect of the conventional shot peening and multiple shot peening on microstructure and residual stress of TC17 titanium alloy. Surf Coat Technol 2024; 493: 131284.

24.

Fragoudakis

Savaidis

Michailidis

Optimizing the development and manufacturing of 56SiCr7 leaf springs. Int J Fatigue 2017; 103: 168–175.

25.

De la Rosa

CEF

Trejo

Román

, et al. Effect of decarburization on the residual stresses produced by shot peening in automotive leaf springs. J Mater Eng Perform 2016; 25: 2596–2603.

26.

Gomes

VMG

Souto

CDS

Correia

JAFO

, et al. Monotonic and fatigue behaviour of the 51CrV4 steel with application in leaf springs of railway rolling stock. Metals 2024; 14(3): 266.

27.

Liljedahl

CDM

Brouard

Zanellato

, et al. Weld residual stress effects on fatigue crack growth behaviour of aluminium alloy 2024-T351. Int J Fatigue 2009; 31: 1081–1088.

28.

Gakias

Maliaris

Savaidis

An investigation of stress shot peening using a 2D FEM-based simulation approach. Int J Fatigue 2024; 181: 108130.

29.

Atig

Ben Sghaier

Seddik

, et al. A simple analytical bending stress model of parabolic leaf spring. Proc Inst Mech Eng Part C: J Mech Eng Sci 2017; 232: 1838–1850.

30.

James

Hattingh

Matthews

Embrittlement failure of 51CrV4 leaf springs. Eng Fail Anal 2022; 139: 106517.

31.

Fragoudakis

Saigal

Savaidis

, et al. Fatigue assessment and failure analysis of shot-peened leaf springs. Fatigue Fract Eng Mater Struct 2012; 36: 92–101.

32.

Al-Hassani

Mechanical aspects of residual stress development in shot peening. In: Niku-Lari

(ed.) Proceedings of the 1st international conference on Shot Peening. Pergamon Press, 1981, pp.583–602.

The effect of residual stress on fatigue fracture of automotive leaf springs: Experiment and simulation

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