Experimental study on multilayer liquid GaInSn film flow under horizontal magnetic field

doi:10.7523/j.issn.2095-6134.2019.03.004

Abstract

Abstract: In this work, the flow characteristics of the liquid GaInSn film in the multilayer channel in the organic glass cavity under the spanwise magnetic field are studied. Three laser level instruments are used to simultaneously capture the liquid 2D contour changes at three positions, and measure the thickness of film. The experimental results show that the surface fluctuation of the liquid film increases obviously with Reynolds number in the organic glass channel. The magnetic field effectively inhibits the surface fluctuation along the magnetic lines, but has little influence on the surface fluctuation along the streamwise direction. The thickness of the film decreases with the increase of the magnetic field at small Reynolds numbers, the thickness decreases first and then increases at the medium Reynolds numbers, and the thickness of film increases monotonically when Reynolds numbers are large. The larger Reynolds number is, the more obvious the effect of magnetic field's obstruction of the flow is. The results illustrate that the multilayer film flow device effectively improves the spreading of film flow and makes the spreading easier.

Key words: magnetic field, liquid metal, film flow, multilayer channel

CLC Number:

O361.3

QI Tianyu, YANG Juancheng, NI Mingjiu. Experimental study on multilayer liquid GaInSn film flow under horizontal magnetic field[J]. , 2019, 36(3): 320-325.

References

[1] Narula M, Ying A, Abdou M A. A study of liquid metal film flow, under fusion relevant magnetic fields[J]. Fusion Science & Technology, 2005, 47(3):564-568.
[2] Morley N B, Burris J, Cadwallader L C, et al. GaInSn usage in the research laboratory[J]. Review of Scientific Instruments, 2008, 79(5):112-192.
[3] Morley N B, Burris J. The MTOR LM-MHD flow facility, and preliminary experimental investigation of thin layer, liquid metal flow in a 1/R toroidal magnetic field[J]. Fusion Science & Technology, 2003, 44(1):74-78.
[4] Hsieh D. Stability of a conducting fluid flowing down an inclined plane in a magnetic field[J]. Physics of Fluids, 1964, 8(10):1785-1791.
[5] Ladikov Y P. Flow stability of a conducting liquid flowing down an inclined plane in the presence of a magnetic field[J]. Fluid Dynamics, 1966, 1(1):1-4.
[6] Li F C, Serizawa A. Experimental study on flow characteristics of a vertically falling film flow of liquid metal NaK in a transverse magnetic field[J]. Fusion Engineering & Design, 2004, 70(2):185-199.
[7] Li F C, Kunugi T, Serizawa A. MHD effect on flow structures and heat transfer characteristics of liquid metal-gas annular flow in a vertical pipe[J]. International Journal of Heat & Mass Transfer, 2005, 48(12):2571-2581.
[8] Yang J C, Qi T Y, Ni M J, et al. Flow patterns of GaInSn liquid on inclined stainless steel plate under a range of magnetic field[J]. Fusion Engineering & Design, 2016, s109-111:861-865.
[9] 阳倦成,齐天煜,刘佰奇,等. 磁场作用下液态金属膜流铺展特性的实验研究[J]. 工程热物理学报, 2017(9):1917-1922.
[10] Xu Z Y, Pan C J, Kang W S, et al. Experimental investigation on MHD instabilities of free surface jet and film flow for liquid metal Divertor/Limiter options[J]. Nuclear Fusion & Plasma Physics, 2006(1):152-153.
[11] Zhang X J, Pan C J, Xu Z Y. MHD stability analysis and flow controls of liquid metal free surface film flows as fusion reactor PFCs[J]. Plasma Science and Technology, 2016, 18(12):1204-1214.
[12] 倪明玖, 阳倦成, 张杰. 一种强磁场下的连续金属液膜生成装置及方法:中国,CN104078084A[P/OL]. (2014-10-01)[2018-02-10].http://www.wanfangdata.com.cn/details/detail.do?_type=patent&id=CN201410345383.6.

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