Review of the Formation Mechanisms and Control Methods of Geometrical Defects in Laser Deposition Manufacturing

Lanyun Qin , Kun Wang , Xiaodan Li , Siyu Zhou , Guang Yang
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引用次数: 6

Abstract

Laser deposition manufacturing (LDM) is a revolutionary integrated manufacturing technology that expands numerous possibilities for producing large-scale parts in the aerospace and other industries. However, geometrical defects can severely affect the forming accuracy of parts and restrict the progress of LDM technology to large-scale components. This study summarizes the main types of geometrical defects and classifies them into four categories: flatness defects, melting collapse, distortion, cracking, and delamination. To overcome this challenge, one approach that has received considerable attention is process monitoring accompanied by mitigation strategies to improve the forming accuracy and repeatability. This study outlines the current understanding of the formation mechanism of common geometrical defects and discusses techniques to monitor the process and mitigate defects. Further, it discusses approaches for monitoring and controlling the LDM process while emphasizing the monitored melt pool, surface topography, temperature, and distortion. Next, the study focuses on procedures, including optimizing process parameters, thermal control methods, prediction, and compensation, to mitigate geometrical defects. Finally, the aim of the study is to provide a reference for researchers in this field. However, many future research hotpots for LDM precision control that require further investigation are still present.

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激光沉积制造中几何缺陷的形成机理及控制方法综述
激光沉积制造(LDM)是一种革命性的集成制造技术,它为航空航天和其他行业生产大型零件提供了许多可能性。然而,几何缺陷严重影响了零件的成形精度,制约了LDM技术向大型零件的发展。本研究总结了几何缺陷的主要类型,并将其分为四类:平直缺陷、熔化塌陷缺陷、变形缺陷、开裂缺陷和分层缺陷。为了克服这一挑战,一种受到相当关注的方法是过程监控,并辅以缓解策略,以提高成形精度和可重复性。本研究概述了目前对常见几何缺陷形成机制的理解,并讨论了监控过程和减轻缺陷的技术。此外,它还讨论了监测和控制LDM过程的方法,同时强调了监测的熔池、表面形貌、温度和变形。接下来,研究的重点是流程,包括优化工艺参数,热控制方法,预测和补偿,以减轻几何缺陷。最后,本研究的目的是为该领域的研究者提供参考。然而,对于LDM精度控制,仍有许多有待深入研究的研究热点。
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