Low-Defect AM of High Strength Aluminium Alloy by LMD

Chemical Engineering (Engineering) eJournal Pub Date : 2021-02-15 DOI:10.2139/ssrn.3785871

Anika Langebeck, A. Bohlen, R. Rentsch, F. Vollertsen

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Abstract

A manifold variety of additive manufacturing techniques has a significant positive impact on many industry sectors. Large components are often manufactured via laser metal deposition (LMD) instead of using powder bed based processes. The advantages of LMD process are a high build-up rate with values up to 300 cm³/h and a nearly limitless build-up volume. In combination with the lightweight material aluminium it is possible to manufacture large lightweight components with geometries adapted to customer requirements in small batches. This contributes the pursuit of higher efficiency of machines through lightweight materials as well as lightweight design. A low-defect additive manufacturing of high strength aluminium EN AW-7075 powder via LMD is an important challenge to concern. During the process a considerable proportion of pores can build which weakens the mechanical properties. Additionally, the heat input affects the hardness of the manufactured part. A significant reduction of pore volume can be achieved by a higher laser power and an improved shielding gas flow. Therefore, a shielding gas shroud was developed to keep atmospheric hydrogen away from the process zone. The combination of the improved shielding gas flow with a high laser power led to a decrease of pore volume from over 7% to lower than 1.5%.

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低缺陷高强度铝合金的LMD增材制造

各种各样的增材制造技术对许多工业部门产生了重大的积极影响。大型部件通常通过激光金属沉积(LMD)制造，而不是使用基于粉末床的工艺。LMD工艺的优点是积累速率高，可达300 cm³/h，积累体积几乎无限。与轻质材料铝相结合，可以小批量生产具有适合客户要求的几何形状的大型轻质部件。这有助于通过轻量化材料和轻量化设计追求更高的机器效率。利用LMD技术制备低缺陷的高强度EN AW-7075铝粉是目前研究的重要课题。在此过程中，会形成相当比例的孔隙，从而削弱其力学性能。另外，热输入影响制造零件的硬度。通过提高激光功率和改善保护气体流量，可以显著减小孔隙体积。因此，开发了一种保护气体罩，以防止大气中的氢气进入工艺区。改善的保护气体流量和高激光功率的结合使孔隙体积从7%以上降低到1.5%以下。

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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Chemical Engineering (Engineering) eJournal

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