Enhancing the Shape Complexity in Direct Energy Deposition with Phased Deformation

Int. J. Autom. Technol. Pub Date : 2022-09-05 DOI:10.20965/ijat.2022.p0642

Srinath Gudur, S. Simhambhatla, N. Reddy

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Abstract

Wire-based direct energy deposition (W-DED) techniques in metal additive manufacturing allow part-fabrication at higher deposition rates and lower costs. Given the lack of any support mechanism, these processes face challenges in fabricating overhanging features. The inherent overhang capability of weld-beads and higher-order kinematics can help realize certain complex geometries. However, significant challenges like non-uniform slicing, constrained deposition-torch accessibility, etc., limit the efficacy of these approaches. The present work describes a deformation-aided deposition process designed to overcome some of these limitations and to manufacture complex metallic components. It is based on a sequential combination of deposition and bending processes: a shape fabricated through W-DED deposition is bent to form the required shape. The cycle of deposition and bending is repeated until the final desired geometry is realized. The anisotropic and deterministic behaviors of the deposited components are analyzed in terms of springback and the punch force. Finally, the benefit of current hybrid process is demonstrated through a few illustrative geometries.

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提高相变形直接能量沉积的形状复杂度

金属增材制造中基于线的直接能量沉积(W-DED)技术允许以更高的沉积速率和更低的成本制造零件。由于缺乏任何支撑机制，这些工艺在制造悬垂特征方面面临挑战。焊珠固有的悬垂性能和高阶运动学特性可以帮助实现某些复杂的几何形状。然而，诸如不均匀切片、受限的沉积火炬可及性等重大挑战限制了这些方法的有效性。目前的工作描述了一种变形辅助沉积工艺，旨在克服这些限制，并制造复杂的金属部件。它基于沉积和弯曲工艺的顺序组合:通过W-DED沉积制造的形状被弯曲以形成所需的形状。重复沉积和弯曲的循环，直到最终所需的几何形状实现。从回弹和冲孔力的角度分析了沉积构件的各向异性和确定性行为。最后，通过几个几何图形说明了当前混合工艺的优点。

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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Int. J. Autom. Technol.

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