Corrosion Performance of Different Aluminum Alloy Deposits Fabricated by Lateral Friction Surfacing

William Relue, Ebrahim Seidi, L. Hihara, Scott F. Miller
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Abstract

Friction surfacing technique is a thermo-mechanical approach for metallic deposition, suitable for a broad range of materials and applications. Friction surfacing can be employed for various industrial purposes such as coating, welding, repairing defective parts, surface hardening, and improving corrosion performance. In this technique, frictional heat generated at the interface of the consumable tool and substrate results in a severe plastic deformation at the end of the rod, enabling the deposition of a consumable material on the substrate surface. In this investigation, a novel method in friction surfacing, lateral friction surfacing, is employed to deposit the aluminum coatings. In this novel approach, the side of the consumable tool is pressed against the surface of the substrate, and the material transfer happens from the lateral surface of the tool. This technique provides extremely thin and smooth deposits, which are more consistent compared to the conventional approach of friction surfacing. Moreover, this technique enables fabricating of deposits in lower temperatures, lessening the thermal impacts on the microstructures and mechanical properties of the deposits. In this investigation plates of 1018 mild steel were partially coated with various aluminum alloys and corroded in an accelerated corrosion test chamber. The corrosion performance of the partially coated sample was evaluated by mass loss measurement. It was found that AA5086 offered the most corrosion protection. After 13 cycles of GM9540P test, equivalent to approximately 3½ years exposure at a mild/moderate marine site in Hawaii, almost all of the deposited aluminum was corroded off.
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不同侧面摩擦堆焊铝合金镀层的腐蚀性能
摩擦堆焊技术是一种热机械的金属沉积方法,适用于广泛的材料和应用。摩擦堆焊可用于各种工业用途,如涂覆、焊接、修复缺陷零件、表面硬化和改善腐蚀性能。在这种技术中,在消耗性工具和基材的界面处产生的摩擦热导致杆端发生严重的塑性变形,从而使消耗性材料沉积在基材表面。在本研究中,采用一种新的摩擦堆焊方法——侧向摩擦堆焊来沉积铝涂层。在这种新颖的方法中,消耗性工具的一侧被压在基材的表面上,材料从工具的侧面转移。这种技术提供了非常薄和光滑的沉积物,与传统的摩擦表面方法相比,它们更加一致。此外,该技术可以在较低的温度下制造沉积层,减少对沉积层微观结构和机械性能的热影响。在这项研究中,1018低碳钢板部分涂上各种铝合金,并在加速腐蚀试验箱中腐蚀。通过质量损失测量来评价部分涂覆试样的腐蚀性能。结果表明,AA5086的防腐性能最好。经过13轮GM9540P测试,相当于在夏威夷的一个轻度/中度海洋站点暴露大约3年半,几乎所有沉积的铝都被腐蚀掉了。
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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