Considerations on the construction of a Powder Bed Fusion platform for Additive Manufacturing

Physics Procedia Pub Date : 2017-01-01 DOI:10.1016/j.phpro.2017.08.004

Sebastian Aagaard Andersen, Karl-Emil Nielsen, David Bue Pedersen, Jakob Skov Nielsen

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引用次数: 2

Abstract

As the demand for moulds and other tools becomes increasingly specific and complex, an additive manufacturing approach to production is making its way to the industry through laser based consolidation of metal powder particles by a method known as powder bed fusion. This paper concerns a variety of design choices facilitating the development of an experimental powder bed fusion machine tool, capable of manufacturing metal parts with strength matching that of conventional manufactured parts and a complexity surpassing that of subtractive processes. To understand the different mechanisms acting within such an experimental machine tool, a fully open and customizable rig is constructed. Emphasizing modularity in the rig, allows alternation of lasers, scanner systems, optical elements, powder deposition, layer height, temperature, atmosphere, and powder type. Through a custom-made software platform, control of the process is achieved, which extends into a graphical user interface, easing adjustment of process parameters and the job file generation.

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构建增材制造粉末床融合平台的思考

随着对模具和其他工具的需求变得越来越具体和复杂，一种增材制造的生产方法正在进入工业领域，通过一种被称为粉末床熔化的方法，通过激光巩固金属粉末颗粒。本文讨论了促进实验性粉末床熔合机床开发的各种设计选择，该机床能够制造强度与传统制造零件相匹配的金属零件，其复杂性超过减法工艺。为了了解在这样的实验机床中作用的不同机制，构建了一个完全开放和可定制的钻机。在钻机中强调模块化，允许更换激光器、扫描仪系统、光学元件、粉末沉积、层高、温度、气氛和粉末类型。通过定制的软件平台，实现了对工艺的控制，并扩展为图形用户界面，简化了工艺参数的调整和作业文件的生成。

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Physics Procedia

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