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作 者:张萍[1] 王文芳[1] 吴玉程[1] 邓书山[1]
出 处:《机械工程材料》2009年第7期61-63,共3页Materials For Mechanical Engineering
基 金:安徽省"十五"二期科技攻关项目(040020392);合肥市重点科技攻关项目(20051044)
摘 要:首先采用合金化法制备了铜-铬基体合金粉,然后向其中加入质量分数为10%的石墨粉和不同含量的纳米AlN粉,制备了不同含量纳米AlN颗粒增强的石墨/铜-0.6%铬复合材料,研究了纳米AlN含量对复合材料密度、电阻率、硬度、抗弯强度及磨擦磨损性能的影响。结果表明:随着纳米AlN含量的增加,复合材料的抗弯强度及硬度逐渐增加,密度和导电性逐渐降低,磨损量逐渐减少,摩擦因数变化不大;当纳米AlN质量分数为0.5%时,可在保证不过多降低导电性的前提下,有效提高复合材料的抗弯强度和耐磨性。First Cu-Cr alloy powders were prepared by alloying method, and then nano-AlN particles strengthened graphite/Cu-0. 6%Cr composites were gained by adding 10% graphite particles and different content of AlN particles into the Cu-Cr alloy. The influence of nano-AiN content on the density, conductivity, hardness, bending strength, wear and friction properties of the composites was studied. The results show that with the increase of nano-A1N content, the hardness and bending strength increased, the density, conductivity and wear mass loss decreased, and friction coefficient changed little. When the nano-AlN content was 0. 5%, the bending strength and wear resisting property of the composite could be improved effectively in the premise of not reducing the electrical conductivity too much.
分 类 号:TB331[一般工业技术—材料科学与工程] TB333
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