材料科学
抛光(金属)
表面粗糙度
选择性激光熔化
钛合金
机械加工
表面光洁度
残余应力
冶金
表面处理
表面改性
表面完整性
复合材料
合金
机械工程
微观结构
抛光
工程类
作者
Gyula Varga,Gergely Dezső,Ferenc Szigeti
出处
期刊:Machines
[Multidisciplinary Digital Publishing Institute]
日期:2022-05-20
卷期号:10 (5): 400-400
被引量:21
标识
DOI:10.3390/machines10050400
摘要
Selective laser melting is a frequently used, powder bed fusion additive manufacturing technology for producing metallic parts. However, appropriate surface quality cannot be achieved, so post-processing is often necessary. Subsequent machining of surfaces serves multiple objectives such as improvement of dimensional accuracy, changing surface roughness and modification of the residual stress state for higher surface hardness. Beyond its several advantageous properties, Ti6Al4V material has, as its weaknesses, low tribological behavior and wear resistance. Sliding friction burnishing is a conventional chipless and coolant-free environmentally conscious technology for surface modification that is appropriate for simultaneously decreasing surface roughness and increasing surface hardness. Until now, there has been a research gap regarding the diamond burnishing of selective laser melted Ti6Al4V parts. In this study, we investigated how the surface roughness of selective laser melted parts can be modified via sliding friction burnishing. 2D and 3D characteristics of surface roughness were measured by a chromatic roughness measuring device. Indices of surface roughness improvement were defined and studied as a function of selective laser melting parameters. Optimal manufacturing parameters of laser power—P = 280 W and scanning speed u = 1200 mm/s—for effective surface improvement via burnishing are proposed.
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