选择性激光熔化对CuSn10样品孵化距离的影响

Jinwu Kang, Xiang Wang, Chengyang Deng, Yunlong Feng, T. Feng, Y Jihao, Pengyue Wu
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引用次数: 2

摘要

选择性激光熔化(SLM)是一种很有前途的增材制造方法,特别是对于精密零件。它可以逐层生成复杂的三维形状。主要应用于钛合金、镍合金和钢中。1-3锡青铜因其良好的摩擦和磨损性能而广泛用作轴承材料。CuSn10粉末烧结通常采用粉末冶金(PM)、机械球磨(MBM)和铸造。孔隙度和几何精度是最受关注的问题。增材制造为锡青铜零件的制造提供了新的途径。然而,铜的物理性质与钛、镍合金和钢不同,因此有必要对锡青铜粉的选择性激光烧结原理进行研究。SLM的主要参数是激光功率、扫描速度、层厚和舱口距离。Scudino等人,9通过SLM获得了与铸态性能相对应的CuSn10试样的更好的力学性能。Deng等人(10)利用激光激光扫描显微镜(SLM)研究了激光能量密度对锡青铜件微观组织和力学性能的影响,发现激光能量密度是气孔形成和力学性能的主要因素。在相同的激光能量密度下,对锡青铜(CuSn10)粉末进行了激光扫描,研究了扫描速度和孵育距离对显微组织和力学性能的影响。
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Effect of hatch distance on CuSn10 specimens by selective laser melting
Selective laser melting (SLM) is one of promising additive manufacturing methods, especially for precision parts. It can produce complicated three-dimensional shapes in a layer by-layer style. It has been mainly applied into titanium alloys, nickel alloys and steels.1–3 Tin bronze is widely used as bearing materials for its good friction and wear behaviors. Powders metallurgy (PM), and mechanical ball milling (MBM), and casting are usually used for CuSn10 powder sintering.4–8 The porosity and geometry precision are the most concern problems. Additive manufacturing provides a new way to make tin bronze parts. However, the physical properties of copper are different from titanium, nickel alloys and steels, therefore, it is necessary to investigate the principles of selective laser sintering of tin bronze powder. The main parameters of SLM are laser power, scanning speed, layer thickness and hatch distance. Scudino et al.,9 achieved far better mechanical properties of CuSn10 specimens by SLM corresponding to as-cast properties. Deng et al.,10 studied the effect of laser energy density on the microstructure, mechanical properties of Tin bronze parts by SLM and found the laser energy density is the main factor for porosity formation and the mechanical properties. In this paper, The SLM of tin bronze (CuSn10) powder was performed with same laser energy density to investigate the effect of scanning speed and hatch distance on microstructure and mechanical properties.
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