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用于制造具有微纹理表面的电火花加工电极的电铸设备的改进设计

Improved Design of Electroforming Equipment for the Manufacture of Sinker Electrical Discharge Machining Electrodes with Microtextured Surfaces.

作者信息

Hernández-Pérez Mariana, Hernández-Castellano Pedro M, Salguero-Gómez Jorge, Sánchez-Morales Carlos J

机构信息

Integrated and Advanced Manufacturing Research Group, University of Las Palmas de Gran Canaria, Canary Island, 35001 Las Palmas, Spain.

Materials and Manufacturing Engineering and Technology Research Group, University of Cádiz, 11519 Puerto Real, Spain.

出版信息

Materials (Basel). 2025 Apr 26;18(9):1972. doi: 10.3390/ma18091972.

DOI:10.3390/ma18091972
PMID:40363476
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC12072343/
Abstract

The development of microtextures has had a transformative impact on surface design in engineering, leading to substantial advancements in the performance, efficiency, and functionality of components and tools. This study presents an innovative methodology for fabricating SEDM electrodes. The methodology combines additive manufacturing by mask stereolithography with an optimized electroforming process to obtain high-precision copper shells. A key aspect of the study involved redesigning the electroforming equipment, enabling the independent examination of critical variables such as anode-cathode distance and electrolyte recirculation. This approach allowed precise analysis of their impact on metal deposition. This redesign enabled the assessment of the impact of electrolyte recirculation on the quality of the shells obtained. The findings indicate that continuous recirculation at 60% power effectively reduced thickness deviation by up to 32.5% compared to the worst-case scenario, achieving average thicknesses within the functional zone of approximately 110 µm. In contrast, the absence of flow or excessive turbulence did not generate defects such as unfilled zones or non-uniform thicknesses. The shells obtained were validated as functional tools in SEDM, demonstrating their viability for the generation of textures with high geometric fidelity. This approach optimizes the manufacturing of textured electrodes and opens new opportunities for their application in advanced industrial processes, providing a more efficient and sustainable alternative to conventional methods.

摘要

微纹理的发展对工程领域的表面设计产生了变革性影响,推动了部件和工具在性能、效率及功能方面的显著进步。本研究提出了一种制造电火花加工(SEDM)电极的创新方法。该方法将掩膜立体光刻增材制造与优化的电铸工艺相结合,以获得高精度的铜壳。该研究的一个关键方面是重新设计电铸设备,从而能够独立研究诸如阳极 - 阴极距离和电解液再循环等关键变量。这种方法能够精确分析它们对金属沉积的影响。这种重新设计使得能够评估电解液再循环对所获得铜壳质量的影响。研究结果表明,与最坏情况相比,在60%功率下持续再循环可有效将厚度偏差降低多达32.5%,在约110 µm的功能区内实现平均厚度。相比之下,无流动或过度湍流不会产生诸如未填充区域或厚度不均匀等缺陷。所获得的铜壳被验证为电火花加工中的功能性工具,证明了它们在生成具有高几何保真度纹理方面的可行性。这种方法优化了纹理电极的制造,并为其在先进工业工艺中的应用开辟了新机会,为传统方法提供了一种更高效、可持续的替代方案。

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