用于多轨道、多层零件制造的线弧定向能沉积、摩擦搅拌加工和铣削综合混合系统

IF 4.2 Q2 ENGINEERING, MANUFACTURING
Dinh Son Nguyen , Jie Song , Yao Fu , Albert C. To
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引用次数: 0

摘要

线基定向能沉积(DED)因其高生产率和大部件制造能力而成为一种广泛使用的制造方法。同时,摩擦搅拌加工(FSP)是一种固态连接工艺,可以改变微观结构并焊接轻质合金。此外,基于线材的 DED 印刷部件需要加工工艺来达到所需的尺寸精度。为了充分利用这三种工艺的优势,这项研究提出了一种集成混合系统,它将线弧 DED、FSP 和铣削工艺结合到一个独立的系统中,首次实现了以多轨道、多层次的方式制造优质材料。该集成系统无需在不同系统之间移动工件,即可进行加工,从而提高了尺寸精度和生产率。实验证明,使用线材-DED/FSP/铣削混合工艺,可以用线材原料制造出 150 × 40 × 21 mm3 的铝合金 AA5183 块。材料表征表明,混合工艺能将晶粒尺寸细化两个数量级,达到亚微米级,同时消除了 DED 工艺产生的所有孔隙和微裂纹。这些改进大大提高了机械性能,包括杨氏模量(15%)、屈服强度(161%)、极限强度(33%)和硬度(55%),同时不影响延展性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
An integrated hybrid wire-arc directed energy deposition, friction stir processing, and milling system for multi-track, multi-layer part manufacturing
Wire-based Directed Energy Deposition (DED) is a widely-used manufacturing method due to its high productivity and large part fabrication capability. Meanwhile, Friction Stir Processing (FSP) is a solid-state joining process that can modify microstructure and weld lightweight alloys. Additionally, wire-based DED printed parts need machining process to achieve the desired dimensional accuracy. To take advantage of all these three processes, this work proposes an integrated hybrid system by combining the wire-arc DED, FSP, and milling processes into a standalone system which can fabricate superior materials in a multi-track, multi-layer manner for the first time. The integrated system can improve dimensional accuracy and productivity by processing the workpiece without the need to move it between different systems. It is demonstrated that a 150 × 40 × 21 mm3 block of aluminum alloy AA5183 can be fabricated using the hybrid wire-DED/FSP/milling process from wire feedstock. Material characterization shows that the hybrid process is able to refine the grain size by two orders of magnitude to sub-micron scale, while eliminating all the pores and microcracks produced by the DED process. These enhancements result in significantly improved mechanical properties including Young's modulus (15 %), yield strength (161 %), ultimate strength (33 %), and hardness (55 %) without compromising ductility.
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来源期刊
Additive manufacturing letters
Additive manufacturing letters Materials Science (General), Industrial and Manufacturing Engineering, Mechanics of Materials
CiteScore
3.70
自引率
0.00%
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审稿时长
37 days
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