Peening methods for AISI 4140 steel to induce stable compressive residual stress against cyclic axial loading

IF 6.8 2区材料科学 Q1 ENGINEERING, MECHANICAL

International Journal of Fatigue Pub Date : 2025-07-28 DOI:10.1016/j.ijfatigue.2025.109200

Tomofumi Aoki , Motoaki Hayama , Shoichi Kikuchi , Jun Komotori

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引用次数: 0

Abstract

In this study, fine-particle peening (FPP) and shot peening (SP) were performed with a maximum compressive residual stress (CRS) of approximately − 650 MPa for AISI 4140 steels to increase the fatigue strength. The CRS stability during the fatigue process was analyzed using in situ X-ray stress measurements under axial compression-tension loading. The hardened layer formed via peening stabilized the CRS against cyclic axial loading, with fatigue strength at the 10⁷th cycle. This occurs because the increased local yield strength prevents localized compressive yielding caused by the superposition of the compressive loading and residual stresses. Although peening induced a CRS in a region deeper than the hardened layer, the CRS below the hardened layer was relaxed by a compressive stress loading lower than that on the surface, reducing the CRS stability in the hardened layer. This is because the compressive loading caused local compressive yielding below the hardened layer and resulted in stress redistribution. SP induced remarkable CRS deeper than the hardened layer, while FPP induced it mainly in the surface layer. Compared to SP, FPP increased the fatigue strength at the 10⁷th cycle by approximately 50 MPa and maintained a high CRS during fatigue testing with axial tension–compression loading and a stress amplitude of 700 MPa. The CRS stability and fatigue properties under axial loading were the most improved when the hardened layer with high yield strength was formed via FPP, and the peak CRS location was within the hardened layer.

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AISI 4140钢在循环轴向载荷下产生稳定残余压应力的强化方法

在本研究中，对AISI 4140钢进行了细颗粒强化（FPP）和喷丸强化（SP），最大压缩残余应力（CRS）约为- 650 MPa，以提高疲劳强度。采用x射线原位应力测量方法，分析了轴向压缩-拉伸载荷作用下CRS在疲劳过程中的稳定性。强化后形成的硬化层使CRS抗轴向循环载荷稳定，疲劳强度达到107次循环。这是因为增加的局部屈服强度阻止了由压缩载荷和残余应力叠加引起的局部压缩屈服。强化处理在淬硬层下方产生CRS，但淬硬层下方的CRS受到低于表面的压应力载荷而松弛，降低了淬硬层CRS的稳定性。这是因为压缩载荷在硬化层以下引起局部压缩屈服，导致应力重分布。SP诱导的CRS较硬化层深，FPP诱导的CRS主要在表层。与SP相比，FPP在第107次循环时的疲劳强度提高了约50 MPa，并且在轴向拉压加载和应力幅值为700 MPa的疲劳试验中保持了较高的CRS。通过FPP形成具有高屈服强度的硬化层时，轴向载荷下CRS的稳定性和疲劳性能得到最大改善，且CRS峰值位于硬化层内。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

International Journal of Fatigue 工程技术-材料科学：综合

CiteScore

10.70

自引率

21.70%

发文量

619

审稿时长

58 days

期刊介绍： Typical subjects discussed in International Journal of Fatigue address: Novel fatigue testing and characterization methods (new kinds of fatigue tests, critical evaluation of existing methods, in situ measurement of fatigue degradation, non-contact field measurements) Multiaxial fatigue and complex loading effects of materials and structures, exploring state-of-the-art concepts in degradation under cyclic loading Fatigue in the very high cycle regime, including failure mode transitions from surface to subsurface, effects of surface treatment, processing, and loading conditions Modeling (including degradation processes and related driving forces, multiscale/multi-resolution methods, computational hierarchical and concurrent methods for coupled component and material responses, novel methods for notch root analysis, fracture mechanics, damage mechanics, crack growth kinetics, life prediction and durability, and prediction of stochastic fatigue behavior reflecting microstructure and service conditions) Models for early stages of fatigue crack formation and growth that explicitly consider microstructure and relevant materials science aspects Understanding the influence or manufacturing and processing route on fatigue degradation, and embedding this understanding in more predictive schemes for mitigation and design against fatigue Prognosis and damage state awareness (including sensors, monitoring, methodology, interactive control, accelerated methods, data interpretation) Applications of technologies associated with fatigue and their implications for structural integrity and reliability. This includes issues related to design, operation and maintenance, i.e., life cycle engineering Smart materials and structures that can sense and mitigate fatigue degradation Fatigue of devices and structures at small scales, including effects of process route and surfaces/interfaces.