Tribological Behavior of Copper Chilled Aluminum Alloy (LM-13) Reinforced with Beryl Metal Matrix Composites

J. Hemanth
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引用次数: 2

Abstract

The present investigation aims at developing copper chilled aluminum alloy (LM-13) reinforced with beryl using stir casting method. Matrix alloy was melted in a composite making furnace to a temperature of about 700°C to which preheated reinforcement particles was added (3 wt.% to 12 wt.% in steps of 3 wt.%), stirred well and finally poured in to an AFS standard mold containing copper end chills of different thickness (10, 15, 20 and 25 mm) placed judiciously for directional solidification. The resulting chilled composites were subjected to microstructural, XRD, mechanical properties (strength and hardness) and tribological behavior.Results of the microstructural and XRD analysis indicate that the chilled castings were sound with good distribution and presence of all the particles. The bonding between beryl reinforcement and Al alloy matrix (LM-13) leads to excellent isotropic properties without any shrinkage or microporosity. Mechanical characterization indicates that both strength and hardness were maximum in the case of copper chilled MMC containing 9 wt.% and 12 wt.% reinforcement respectively. Strength and hardness of chilled MMC are found to increase by 9.88% and 16.66% as compared against the matrix alloy. It is observed that because of the ceramic (beryl) reinforcement in aluminum alloy, the wear resistance of the chilled composite developed has increased with increase in reinforcement content. At lower load, chilled MMCs exhibited mild wear regime with high coefficient of friction and at higher loads they exhibited severe wear with better wear resistance compared to un-chilled composite. It is observed that the increase in mechanical properties and wear resistance are due to incorporation of beryl reinforcement, the effect of chilling that has resulted in grain refined microstructure with good bonding of the matrix and the reinforcement.
绿柱石金属基复合材料增强铜冷态铝合金(LM-13)的摩擦学性能
本研究的目的是用搅拌铸造法研制绿柱石增强铜冷铝合金(LM-13)。将基体合金在复合材料制造炉中熔化到约700°C的温度,并在其中加入预热过的增强颗粒(按3 wt.%的步骤添加3 wt.%至12 wt.%),充分搅拌,最后倒入AFS标准模具中,模具中含有不同厚度(10、15、20和25 mm)的铜端冷器,以进行定向凝固。对制备的复合材料进行了显微组织、XRD、力学性能(强度、硬度)和摩擦学性能测试。显微组织和XRD分析结果表明,冷却后的铸件质量良好,颗粒分布良好。绿柱石增强体与铝合金基体(LM-13)的结合使其具有优异的各向同性性能,且无任何收缩或微孔隙。力学性能表征表明,在含9 wt.%和12 wt.%强化量的铜冷态MMC中,强度和硬度均达到最大。与基体合金相比,冷态MMC的强度和硬度分别提高了9.88%和16.66%。结果表明,由于在铝合金中加入了陶瓷(绿柱石)增强,所研制的冷态复合材料的耐磨性随着增强量的增加而提高。在低负荷下,冷冻mmc表现出轻微的磨损,摩擦系数高;在高负荷下,与未冷冻的复合材料相比,它们表现出严重的磨损,耐磨性更好。结果表明,合金力学性能和耐磨性的提高主要是由于绿柱石增强剂的加入和冷却作用,使合金的组织细化,基体与增强剂结合良好。
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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