铸铝基复合材料多次重熔后的摩擦学行为

IF 0.4 Q4 ENGINEERING, MULTIDISCIPLINARY
Evgeny Prusov, Artemiy Aborkin, Vladislav Deev, Dmitriy Bokaryov, Dmitriy Babin
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引用次数: 0

摘要

限制铝合金铸件在许多高科技行业中应用的因素之一是其摩擦学性能水平不够,特别是在干磨损和磨料磨损条件下。用硬陶瓷颗粒增强铝合金,即过渡到铝基复合材料,可以显着增加其抗干滑动摩擦,磨损和在宽温度和力操作间隔下的卡住的能力。在铸铝基复合材料工业实施的诸多问题中,铸铝基复合材料的回收利用问题占有重要地位。本工作旨在确定重熔过程中冶金工艺对铸造Al-Si-B4C铝基复合材料摩擦学性能变化的影响。为此,在干摩擦条件下,根据球盘方案进行了摩擦学试验。与未增强的AlSi12基合金相比,B4C颗粒增强AlSi12基合金在铸态时的复合摩擦系数和质量磨损均有所降低。在重熔过程中,铝基复合材料的摩擦学性能没有下降。重复重熔导致颗粒分布均匀性改善,在基体/颗粒界面处形成Al3BC相,强化B4C颗粒在循环热载荷作用下破碎,孔隙率增加。重熔过程中结构相组成的变化直接影响摩擦磨损性能的高低。通过对未增强基体合金磨损轨迹的扫描电镜分析,揭示了干摩擦的典型影响,如基体材料的塑性变形和粘接-内聚断裂区域的形成,表明磨损。对于复合材料,这些影响的表现程度要小得多。无论重熔迭代如何,所有复合材料样品都观察到定性相似的滑动磨损行为。研究表明,铝基复合材料在干滑动摩擦过程中可能会形成过渡摩擦层,从而降低摩擦系数。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Tribological Behavior of Cast Aluminum Matrix Composites After Multiple Remelting
One of the limiting factors for expanding the applications of aluminum alloy castings in many high-tech industries is the insufficient level of tribological properties, especially under conditions of dry and abrasive wear. Reinforcing of aluminum alloys with hard ceramic particles, i.e., transition to aluminum matrix composites, allows significantly increasing their resistance against dry sliding friction, scuffing, and seizure in wide temperature and force intervals of operation. Among the numerous problems related to the industrial implementation of cast aluminum matrix composites, the problem of their recycling takes the important place. This work is aimed at establishing the influence of metallurgical processes during remelting on the change in tribological properties of cast Al-Si-B4C aluminum matrix composites. For this purpose, tribological tests in conditions of dry friction according to the ball-on-disc scheme were used. Reinforcing of an AlSi12 matrix alloy with B4C particles leads to a decrease in the composite friction coefficient and the mass wear in the as-cast state in comparison with an unreinforced matrix alloy. During remelting, the tribological properties of the aluminum matrix composites do not deteriorate. Repeated remelting leads to the improvement in particle distribution uniformity, formation of the Al3BC phase at the matrix/particle interfaces, fragmentation of reinforcing B4C particles due to cyclic thermal loads as well as an increase in the porosity fraction. The changes in the structural-phase composition during remelting have a direct influence on the level of tribological properties. Typical effects associated with dry friction, such as plastic deformation of the matrix material and the formation of areas of adhesion-cohesive fracture, indicative of scuffing, were revealed by SEM analysis of the wear tracks of an unreinforced matrix alloy. For the composite material, these effects manifested to a much lesser extent. A qualitatively similar sliding wear behavior was observed for all composite samples, regardless of the remelting iteration. The study suggests that the formation of a transitional tribolayer may occur during dry sliding friction of aluminum matrix composites, which can reduce the friction coefficient.
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来源期刊
Journal of Materials and Engineering Structures
Journal of Materials and Engineering Structures ENGINEERING, MULTIDISCIPLINARY-
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