Experimental Analysis of Metal Inert Gas Based Wire Arc Additive Manufacturing of Aluminum Nanocomposite AA7075

M. Darnell, D. Harwig, Xun Liu
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引用次数: 1

Abstract

This work studies Metal Inert Gas (MIG) based Wire Arc Additive Manufacturing (WAAM) for nanoparticle enhanced AA7075. MIG WAAM is important for production and large structures due to its high deposition rates compared to Tungsten Inert Gas (TIG) or powder-based AM processes. Both MIG and TIG take advantage of wire feedstock, which is more readily available than powdered metals since the welding technology has been established for decades. Powder based processes allow for more complicated geometries but take significantly more time to produce and can suffer from voids which lead to non-uniform part density. TIG is normally used in welding of aluminum because it results in fewer defects, but the TiC/TiB2 nanoparticles eliminate solidification cracking normally associated with high strength aluminum alloys during welding. Porosity is another problem faced when welding aluminum, which can be affected by many things including deposition parameters, atmosphere and even the welding equipment used. Effects of different deposition parameters have been comprehensively studied including the deposition geometry and metallurgical properties. The process is also monitored with current/voltage measurement and high-speed imaging to understand the droplet transfer mode and molten pool development. The results are used to optimize process parameters to achieve the fewest defects possible while comparing different metal transfer modes. Multi-scale characterizations will be performed to examine the porosity distribution, solidification mode and grain size through optical microscopy. Future works will explore the distribution of secondary phases, precipitates, and nanoparticles through scanning electron microscopy (SEM) as well as conducting some mechanical testing of the as built structures such as hardness mapping and tensile tests.
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金属惰性气体基电弧增材制备纳米铝复合材料AA7075的实验分析
本文研究了基于金属惰性气体(MIG)的线弧增材制造(WAAM)纳米粒子增强AA7075。与钨惰性气体(TIG)或粉末基AM工艺相比,MIG WAAM具有较高的沉积速率,因此对于生产和大型结构非常重要。MIG和TIG都利用了线材原料,这比粉末金属更容易获得,因为焊接技术已经建立了几十年。基于粉末的工艺允许更复杂的几何形状,但需要更多的时间来生产,并且可能受到导致零件密度不均匀的空洞的影响。TIG通常用于铝的焊接,因为它产生的缺陷较少,但TiC/TiB2纳米颗粒消除了焊接过程中通常与高强度铝合金相关的凝固裂纹。多孔性是焊接铝时面临的另一个问题,它会受到许多因素的影响,包括沉积参数、气氛甚至所使用的焊接设备。研究了不同沉积参数对镀层几何形貌和冶金性能的影响。该过程还通过电流/电压测量和高速成像来监测,以了解液滴传递模式和熔池的发展情况。结果用于优化工艺参数,以实现尽可能少的缺陷,同时比较不同的金属转移模式。将通过光学显微镜进行多尺度表征,以检查孔隙率分布,凝固模式和晶粒尺寸。未来的工作将通过扫描电子显微镜(SEM)探索二次相、沉淀和纳米颗粒的分布,并对建造的结构进行一些力学测试,如硬度图和拉伸测试。
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