Influence of milling interventions on the geometry of wall-shaped structures in hybrid wire-arc direct energy deposition

IF 1.9 Q3 ENGINEERING, MANUFACTURING Manufacturing Letters Pub Date : 2024-10-01 DOI:10.1016/j.mfglet.2024.09.096
Akshar Kota, Shohom Bose-Bandyopadhyay, Asif Rashid, Shreyes N. Melkote
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Abstract

The Hybrid Wire-Arc Direct Energy Deposition (Hybrid Wire-Arc DED) process integrates Wire-Arc Direct Energy Deposition (Wire-Arc DED) with machining (typically milling) interventions, offering the potential for creating intricate geometries and finished surfaces. However, if milling is employed as a hybrid intervention rather than as a final part-finishing process, the interplay between these processes remains under-investigated. This paper examines the influence of milling interventions on the geometry of a wall-shaped structure, quantified by the transverse cross-sectional width, built using a Hybrid Wire-Arc DED. Through experiments on mild steel, the underlying causes of observed wall-width variations are analyzed. Initial observations suggested that thermo-mechanical deformations from milling influence the width variations. However, evidence indicates the significant role of additional remelting cycles experienced by the milled surface layer during subsequent layer depositions. The study also reveals that the observed increase in wall width for each milling intervention occurs at approximately the same depth below the milled surface. A mechanistic explanation for this observation is given. Crucially, the findings suggest that unless milling is done at higher frequencies, like after each layer deposition, the resultant unevenness might render the Hybrid Wire-Arc DED process less efficient in terms of surface quality and dimensional accuracy than its non-hybrid counterpart.
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混合线弧直接能量沉积中铣削干预对壁状结构几何形状的影响
线-弧混合直接能量沉积(Hybrid Wire-Arc DED)工艺将线-弧直接能量沉积(Wire-Arc DED)与机加工(通常是铣削)干预集成在一起,为创造复杂的几何形状和精加工表面提供了可能性。然而,如果将铣削作为一种混合干预而不是作为最终的零件精加工工艺来使用,那么这些工艺之间的相互作用仍未得到充分研究。本文研究了铣削干预对墙形结构几何形状的影响,该几何形状由横向截面宽度量化,使用混合线弧钻铣制造。通过对低碳钢的实验,分析了观察到的壁宽变化的根本原因。初步观察表明,铣削产生的热机械变形影响了宽度变化。然而,有证据表明,铣削表面层在后续层沉积过程中经历的额外重熔循环起了重要作用。研究还发现,每次铣削过程中观察到的壁宽增加都发生在铣削表面以下大致相同的深度。研究给出了这一观察结果的机理解释。最重要的是,研究结果表明,除非以更高的频率进行铣削,例如在每层沉积后进行铣削,否则由此产生的不平整可能会使混合线-电弧 DED 工艺在表面质量和尺寸精度方面的效率低于非混合工艺。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Manufacturing Letters
Manufacturing Letters Engineering-Industrial and Manufacturing Engineering
CiteScore
4.20
自引率
5.10%
发文量
192
审稿时长
60 days
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