SCI和EI收录∣中国化工学会会刊

Chinese Journal of Chemical Engineering ›› 2017, Vol. 25 ›› Issue (12): 1714-1726.DOI: 10.1016/j.cjche.2017.05.001

• 第25届中国过程控制会议专栏 • 上一篇    下一篇

Influence of nanoparticle concentrations on flow boiling heat transfer coefficients of Al2O3/R141b in micro heat exchanger by direct metal laser sintering

Jianyang Zhou1,2, Xiaoping Luo1, Cong Deng1, Mingyu Xie1, Lin Zhang1, Di Wu1, Feng Guo1   

  1. 1. School of Mechanical and Automobile Engineering, South China University of Technology, Guangzhou 510640, China;
    2. School of Mechanical and Marine Engineering, Qinzhou University, Qinzhou 535011, China
  • 收稿日期:2016-08-31 修回日期:2017-05-04 出版日期:2017-12-28 发布日期:2018-01-18
  • 通讯作者: Xiaoping Luo,E-mail address:mmxpluo@scut.edu.cn.
  • 基金资助:

    Supported by the National Natural Science Foundation of China [21276090].

Influence of nanoparticle concentrations on flow boiling heat transfer coefficients of Al2O3/R141b in micro heat exchanger by direct metal laser sintering

Jianyang Zhou1,2, Xiaoping Luo1, Cong Deng1, Mingyu Xie1, Lin Zhang1, Di Wu1, Feng Guo1   

  1. 1. School of Mechanical and Automobile Engineering, South China University of Technology, Guangzhou 510640, China;
    2. School of Mechanical and Marine Engineering, Qinzhou University, Qinzhou 535011, China
  • Received:2016-08-31 Revised:2017-05-04 Online:2017-12-28 Published:2018-01-18
  • Contact: Xiaoping Luo,E-mail address:mmxpluo@scut.edu.cn.
  • Supported by:

    Supported by the National Natural Science Foundation of China [21276090].

摘要: Al2O3/R141b+Span-80 nanorefrigerant for 0.05 wt.% to 0.4 wt.% is prepared by ultrasonic vibration to investigate the influence of nanoparticle concentrations on flow boiling heat transfer of Al2O3/R141b+Span-80 in micro heat exchanger by direct metal laser sintering. Experimental results showthat nanoparticle concentrations have significantly impact on heat transfer coefficients by homogeneity test of variances according to mathematical statistics. The heat transfer performance of Al2O3/R141b+Span-80 nanorefrigerant is enhanced after adding nanoparticles in the pure refrigerant R141b. The heat transfer coefficients of 0.05wt.%, 0.1wt.%, 0.2wt.%, 0.3 wt.% and 0.4 wt.% Al2O3/R141b+Span-80 nanorefrigerant respectively increase by 55.0%, 72.0%, 53.0%, 42.3% and 39.9% compared with the pure refrigerant R141b. The particle fluxes from viscosity gradient, non-uniform shear rate and Brownian motion cause particles to migrate in fluid especially in the process of flow boiling. Thismigrationmotion enhances heat transfer between nanoparticles and fluid. Therefore, the heat transfer performance of nanofluid is enhanced. It is important to note that the heat transfer coefficients nonlinearly increase with nanoparticle concentrations increasing. The heat transfer coefficients reach its maximum value at the mass concentration of 0.1% and then it decreases slightly. There exists an optimal mass concentration corresponding to the best heat transfer enhancement. The reason for the above phenomenon is attributed to nanoparticles deposition on the minichannel wall by Scanning Electron Microscopy observation. The channel surface wettability increases during the flow boiling experiment in themass concentration range from 0.2 wt.% to 0.4wt.%. The channel surface with wettability increasing needsmore energy to produce a bubble. Therefore, the heat transfer coefficients decrease with nanoparticle concentrations in the range from 0.2 wt.% to 0.4 wt.%. In addition, a new correlation has been proposed by fitting the experimental data considering the influence ofmass concentrations on the heat transfer performance. The new correlation can effectively predict the heat transfer coefficient.

关键词: Nanoparticle, Concentration, Minichannel, Sintering, Flow boiling, Heat transfer coefficient

Abstract: Al2O3/R141b+Span-80 nanorefrigerant for 0.05 wt.% to 0.4 wt.% is prepared by ultrasonic vibration to investigate the influence of nanoparticle concentrations on flow boiling heat transfer of Al2O3/R141b+Span-80 in micro heat exchanger by direct metal laser sintering. Experimental results showthat nanoparticle concentrations have significantly impact on heat transfer coefficients by homogeneity test of variances according to mathematical statistics. The heat transfer performance of Al2O3/R141b+Span-80 nanorefrigerant is enhanced after adding nanoparticles in the pure refrigerant R141b. The heat transfer coefficients of 0.05wt.%, 0.1wt.%, 0.2wt.%, 0.3 wt.% and 0.4 wt.% Al2O3/R141b+Span-80 nanorefrigerant respectively increase by 55.0%, 72.0%, 53.0%, 42.3% and 39.9% compared with the pure refrigerant R141b. The particle fluxes from viscosity gradient, non-uniform shear rate and Brownian motion cause particles to migrate in fluid especially in the process of flow boiling. Thismigrationmotion enhances heat transfer between nanoparticles and fluid. Therefore, the heat transfer performance of nanofluid is enhanced. It is important to note that the heat transfer coefficients nonlinearly increase with nanoparticle concentrations increasing. The heat transfer coefficients reach its maximum value at the mass concentration of 0.1% and then it decreases slightly. There exists an optimal mass concentration corresponding to the best heat transfer enhancement. The reason for the above phenomenon is attributed to nanoparticles deposition on the minichannel wall by Scanning Electron Microscopy observation. The channel surface wettability increases during the flow boiling experiment in themass concentration range from 0.2 wt.% to 0.4wt.%. The channel surface with wettability increasing needsmore energy to produce a bubble. Therefore, the heat transfer coefficients decrease with nanoparticle concentrations in the range from 0.2 wt.% to 0.4 wt.%. In addition, a new correlation has been proposed by fitting the experimental data considering the influence ofmass concentrations on the heat transfer performance. The new correlation can effectively predict the heat transfer coefficient.

Key words: Nanoparticle, Concentration, Minichannel, Sintering, Flow boiling, Heat transfer coefficient