Modification of Diffusion Layers by Laser Shock Peening

IF 1.6 Q4 ENGINEERING, MANUFACTURING Manufacturing Technology Pub Date : 2022-12-23 DOI:10.21062/mft.2022.085

J. Procházka, J. Viliš, D. Dobrocký, P. Sperka

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引用次数: 2

Abstract

Keywords The article deals with a possibilities of an enhancement of functional properties of highly stressed components by specific combination of surface technology. Two surface technologies such as plasma nitriding and laser shock peening were selected for the experiment. Those technologies were applied upon steel 42CrMo4 frequently utilized in manufacturing of strained components. Properties obtained by applied surface technologies were tested by following experimental methods. The chemical composition was verified by optical emission spectrometer Tasman Q4 Bruker. The surface morphology was inspected by scanning electron microscope TESCAN MIRA 4. The microstructure of heat treated as well as of nitrided specimens was observed by opto-digital microscope Olympus DSX500i. The microhardness profiles were measured by microhardness tester LM247 AT LECO. The friction coefficient was tested on tribometer Bruker UMT-3 TriboLab. For an assessment of the surface wear-resistance the profilometer Talysurf CLI 1000 and Contour GT were utilized. The experimental results show that although the proposed surface technology combination manifests itself to be disadvantageous, both technology LSP, as well as plasma nitriding, applied separately,

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激光冲击喷丸对扩散层的改性

关键词本文论述了通过表面技术的特定组合来增强高应力部件功能特性的可能性。选择等离子体氮化和激光冲击喷丸两种表面处理技术进行实验。这些技术被应用于应变部件制造中经常使用的42CrMo4钢。通过以下实验方法测试通过应用表面技术获得的性能。通过Tasman Q4 Bruker的光学发射光谱仪验证了化学成分。通过扫描电子显微镜TESCAN MIRA 4检测表面形态。通过光学数字显微镜Olympus DSX500i观察了热处理和氮化试样的微观结构。用LM247 AT LECO显微硬度计测定了显微硬度分布。摩擦系数在摩擦计Bruker UMT-3 TriboLab上进行了测试。为了评估表面耐磨性，使用了Talysurf CLI 1000和Contour GT轮廓仪。实验结果表明，尽管所提出的表面技术组合本身是不利的，但LSP技术和等离子体氮化技术都是单独应用的，

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