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    周霞

    • 教授     博士生导师   硕士生导师
    • 性别:女
    • 毕业院校:大连理工大学
    • 学位:博士
    • 所在单位:力学与航空航天学院
    • 学科:工程力学. 生物与纳米力学. 计算力学
    • 联系方式:Tel: 0411-84706782
    • 电子邮箱:zhouxia@dlut.edu.cn

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    Numerical simulation and experimental validation of SIC nanoparticle distribution in magnesium melts during ultrasonic cavitation based processing of magnesium matrix nanocomposites

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    论文类型:期刊论文

    发表时间:2015-05-01

    发表刊物:ULTRASONICS SONOCHEMISTRY

    收录刊物:SCIE、EI、PubMed

    卷号:24

    页面范围:43-54

    ISSN号:1350-4177

    关键字:Magnesium matrix nanocomposite; Ultrasonic cavitation; Microstructure; Nanoparticle distribution; Finite difference method; Experiment

    摘要:A two-dimensional coupled model of the temperature field, flow field and pressure field of SiC nanopartides reinforced AZ91D magnesium composite slurries fabricated by high-intensity ultrasonic stirring method is established. The multiphase flow mixture model is used to simulate the temperature field, flow field and pressure field of the semi-solid slurries. The effects of ultrasonic stirring parameters on the distribution of SiC nanoparticles in AZ91D magnesium alloy melt are simulated by using finite difference method. The simulation results show that the distribution uniformity of SiC nanoparticles in Mg melts is influenced by ultrasonic power and frequency as well as the ultrasonic processing time and depth of ultrasonic probe dipped into the melts, but the ultrasonic power and frequency have greater influence on particle distribution. In the present work, the magnesium matrix composite with uniform dispersion of SiC nanoparticles can be obtained when the ultrasonic power, the ultrasonic frequency, the depth of ultrasonic probe dipped into the melts and ultrasonic processing time are 2 kW, 20 kHz, 20-30 mm and 120 s, respectively. It has been proven that the similar uniform dispersion could be achieved under the optimal ultrasonic processing conditions although SiC particle sizes in the agglomerated SiC-nanopartides varied between 30 nm and 300 nm in diameter. Moreover, the microstructure and mechanical properties of the SiC nanoparticles reinforced AZ91D magnesium alloy based composites obtained experimentally are improved significantly by using the optimized ultrasonic processing parameters based on numerical simulation. (C) 2014 Elsevier B.V. All rights reserved.