Quantifying the intensity of high-frequency mechanical impact treatment

IF 2.4 4区 材料科学 Q2 METALLURGY & METALLURGICAL ENGINEERING
Jan Schubnell, Takeshi Hanji, Kazuo Tateishi, Stefanos Gkatzogiannis, Thomas Ummenhofer, Majid Farajian
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Abstract

High-frequency mechanical impact (HFMI) is a user-friendly and efficient mechanical post-weld treatment method, and the achieved fatigue life improvement is statistically proved and is attributed to HFMI-induced compressive residual stresses amongst other effects. Several studies have shown in the past that the process parameters (treatment time and working speed) have an influence on the stress state introduced by the HFMI treatment. Thus far, however, only device-specific quantitative recommendation for the HFMI treatment exists based on the instructions of each HFMI device manufacturer. It is not clear if a certain treatment time for a given intensity leads to optimum results regarding the enhanced fatigue life and the treatment parameters of the several HFMI devices cannot be directly compared with each other. For these reasons, a universal and simple definition of the HFMI treatment’s intensity based on the kinetic energy of the HFMI pin was used to quantitatively correlate the HFMI-induced compressive residual stress with the HFMI-process parameters for two different HFMI devices: pneumatical impact treatment (PIT) and high-frequency impact treatment (HiFIT). To this purpose, data from former studies of HFMI-treated base material and welded specimens are revaluated. It is shown, that the compressive residual stresses show only slight changes after reaching a threshold value of the applied kinetic energy (\(\approx\) 50 to 100 J/mm). This energy-based approach for the quantification of the treatment intensity was also used for a case study with PIT- and HiFIT-treated transverse stiffeners with different treatment intensities (2 J/mm and 7 J/mm). A high influence of the treatment intensity on the residual stress state was determined.

Abstract Image

量化高频机械冲击处理的强度
高频机械冲击(HFMI)是一种方便用户使用的高效焊后机械处理方法,其疲劳寿命的提高已得到统计证明,并归因于高频机械冲击引起的压缩残余应力以及其他效应。过去的一些研究表明,工艺参数(处理时间和工作速度)对 HFMI 处理引入的应力状态有影响。不过,到目前为止,只有根据每个高频金属模具制造商的说明提出的针对具体模具的高频金属模具处理定量建议。目前还不清楚特定强度下的特定处理时间是否能带来提高疲劳寿命的最佳结果,而且几种高频脉冲光束设备的处理参数也无法直接相互比较。基于这些原因,我们使用了一个基于高频金属撞击销动能的通用而简单的高频金属撞击处理强度定义,用于定量关联高频金属撞击引起的压缩残余应力和两种不同高频金属撞击装置的高频金属撞击处理过程参数:气动撞击处理(PIT)和高频撞击处理(HiFIT)。为此,我们重新评估了以前对经高频强化处理的母材和焊接试样的研究数据。研究表明,压缩残余应力在达到应用动能的临界值(50 到 100 焦耳/毫米)后仅会出现轻微变化。这种基于能量的处理强度量化方法也被用于对经过不同处理强度(2 J/mm 和 7 J/mm)的 PIT 和 HiFIT 处理的横向加强筋进行案例研究。结果表明,处理强度对残余应力状态的影响很大。
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来源期刊
Welding in the World
Welding in the World METALLURGY & METALLURGICAL ENGINEERING-
CiteScore
4.20
自引率
14.30%
发文量
181
审稿时长
6-12 weeks
期刊介绍: The journal Welding in the World publishes authoritative papers on every aspect of materials joining, including welding, brazing, soldering, cutting, thermal spraying and allied joining and fabrication techniques.
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