• Home
  • Current congress
  • Public Website
  • My papers
  • root
  • browse
  • IAC-20
  • A2
  • 4
  • paper

    • Study on the migration and interaction of axisymmetric two drops with the same phase

    Paper number

    IAC-20,A2,4,3,x57636

    Author

    Prof. Li DUAN, China, National Microgravity Laboratory, Institute of Mechanics, Chinese Academy of Sciences.

    Coauthor

    Dr. Shuo-Ting Zhang, China, Institute of Mechanics, Chinese Academy of Sciences

    Coauthor

    Prof. Qi Kang, China, National Microgravity Laboratory, Institute of Mechanics, Chinese Academy of Sciences.

    Year

    2020

    Abstract
    Droplets are widely found in industrial production process, such as multiphase separation, chemical pharmaceutical and so on. Under microgravity conditions, the study on drop behavior in movement and interaction has great application for the space material sciences, space management of fluid and so on. When the gravity effect is greatly reduced, the interfacial phenomenon becomes important. The motion of drops driven by temperature gradients is related to the thermocapillary Marangoni convection. The Marangoni effect is caused by changes in interfacial tension, which typically decreases with the increase of temperature. Under different conditions, The Marangoni effects can cause a drop to move in the opposite direction of temperatures gradient.
The migration and interaction of axisymmetric two drops in a vertical temperature gradient is investigated experimentally on the ground. A silicon oil is used as the continuous phase, and a water-ethanol mixture is used as the drop phase, respectively. The migration and interaction of two drops, under the combined effects of buoyancy and thermocapillary, is recorded by a digital holographic interferometry measurement in the experiment to analyse the velocities and temperature distribution of the drops. As a result, when two drops migrate together, the drop affects the other drop by perturbing the temperature field around itself. For the leading drop, the velocity is faster than the one of the isolated drop, and the maximum of the interfacial temperature distribution is larger than the one of the isolated drop. For the trailing drop, the velocity is slower than the one of the isolated drop, and the maximum of the interfacial temperature distribution is less than the one of the isolated drop. The influence of the dimensionless initial distance between the drop centres to the drop migration is discussed in detail in this study.

{\bf Keywords:}Interfacial tension; Thermocapillary migration; Drop; Interaction
    Abstract document

    IAC-20,A2,4,3,x57636.brief.pdf

    Manuscript document

    (absent)