强磁场影响下金属相变传热的MHD效应实验研究*

doi:10.7523/j.ucas.2023.021

摘要/Abstract

摘要： 液态金属作为高效的热输运介质,研究磁场下金属流体相变过程中的熔化及传热特性对于聚变堆、电磁冶金及增材制造等工业过程具有重要的意义。本文通过搭建金属相变传热的综合实验系统,研究了强磁场下金属镓的熔化过程,获得了磁场作用下金属镓的熔化换热特性。采用熔化过程中加热壁面距相界面的动态平均距离代替固定特征长度,以此研究熔化过程中对流换热与导热的相对强度随傅里叶数(Fo)的变化规律,结果表明：小哈特曼数(Ha)下,熔化前期具有促进熔化效果,后期则是抑制;大哈特曼数下磁场对金属镓的熔化过程中的对流具有抑制作用,熔化过程呈现层状均匀推进;磁场能够减小熔化过程中腔体底部导热主导区的高度并且抑制熔化过程中的温度波动,使熔化过程中的温度分布趋于均匀。

关键词: 均匀磁场, 相变传热, UDV测速, 液态金属

Abstract: As a highly efficient heat transport medium, the study of the melting and heat transfer characteristics of metallic fluids in phase change processes under magnetic fields is of great importance for industrial processes such as fusion reactors, electromagnetic metallurgy, and additive manufacturing. In this paper, the melting process of metallic gallium under a strong magnetic field was studied by building a comprehensive experimental system for heat transfer through phase change of metal, and the heat transfer characteristics of metallic gallium melting under the action of a magnetic field were obtained. The dynamic average distance of the heated wall from the phase interface during melting instead of the fixed characteristic length is used to study the variation of the relative strength of convective heat transfer and thermal conductivity with Fourier number (Fo) during melting. The results show that: at a small Hartmann number (Ha), the melting has a melting-promoting effect at the early stage and is inhibited at the later stage; at a large Hartmann number the magnetic field has an inhibiting effect on the convection during the melting of gallium metal, and the melting process shows a laminar and uniform advance. The magnetic field reduces the height of the dominant zone of thermal conductivity at the bottom of the cavity during the melting process and suppresses temperature fluctuations during the melting process, resulting in a uniform temperature distribution during the melting process.

Key words: Uniform magnetic field, Melting heat transfer, UDV, Liquid metal

中图分类号:

TK124

蔡志洋, 孟旭, 张登科, 吴曦, 王增辉. 强磁场影响下金属相变传热的MHD效应实验研究^*[J]. 中国科学院大学学报, DOI: 10.7523/j.ucas.2023.021.

CAI Zhiyang, MENG Xu, ZHANG Dengke, WU Xi, WANG Zenghui. Experimental study of the MHD effect of phase change heat transfer in metals under the influence of a strong magnetic field[J]. Journal of University of Chinese Academy of Sciences, DOI: 10.7523/j.ucas.2023.021.

参考文献

[1] Stefan J. Ueber Die Theorie der Eisbildung, insbesondere über Die Eisbildung im Polarmeere[J]. Annalen Der Physik, 1891, 278(2): 269-286. DOI:10.1002/andp.18912780206.
[2] Shokouhmand H, Kamkari B.Experimental investigation on melting heat transfer characteristics of lauric acid in a rectangular thermal storage unit[J]. Experimental Thermal and Fluid Science, 2013, 50: 201-212. DOI:10.1016/j.expthermflusci.2013.06.010.
[3] Al Omari S A B, Ghazal A M, Elnajjar E, et al. Vibration-enhanced direct contact heat exchange using gallium as a solid phase change material[J]. International Communications in Heat and Mass Transfer, 2021, 120: 104990. DOI:10.1016/j.icheatmasstransfer.2020.104990.
[4] 颜晓虹, 胡学功, 赵耀华. 微槽群相变式微冷系统的换热特性实验[J]. 中国科学院研究生院学报, 2006, 23(3): 313-316. DOI:10.3969/j.issn.1002-1175.2006.03.005.
[5] Coenen J W, Philipps V, Brezinsek S, et al.Analysis of tungsten melt-layer motion and splashing under tokamak conditions at TEXTOR[J]. Nuclear Fusion, 2011, 51(8): 083008. DOI:10.1088/0029-5515/51/8/083008.
[6] Jany P, Bejan A.Scaling theory of melting with natural convection in an enclosure[J]. International Journal of Heat and Mass Transfer, 1988, 31(6): 1221-1235. DOI:10.1016/0017-9310(88)90065-8.
[7] Gau C, Viskanta R.Effect of natural convection on solidification from above and melting from below of a pure metal[J]. International Journal of Heat and Mass Transfer, 1985, 28(3): 573-587. DOI:10.1016/0017-9310(85)90180-2.
[8] Gau C, Viskanta R.Melting and solidification of a pure metal on a vertical wall[J]. Journal of Heat Transfer, 1986, 108(1): 174-181. DOI:10.1115/1.3246884.
[9] Kumar L, Manjunath B S, Patel R J, et al.Experimental investigations on melting of lead in a cuboid with constant heat flux boundary condition using thermal neutron radiography[J]. International Journal of Thermal Sciences, 2012, 61: 15-27. DOI:10.1016/j.ijthermalsci.2012.06.014.
[10] Zhang H, Charmchi M, Veilleux D, et al.Numerical and experimental investigation of melting in the presence of a magnetic field: Simulation of low-gravity environment[J]. Journal of Heat Transfer, 2007, 129: 568-576. DOI:10.1115/1.2709961.
[11] Wang Z H, Meng X, Ni M J.Liquid metal buoyancy driven convection heat transfer in a rectangular enclosure in the presence of a transverse magnetic field[J]. International Journal of Heat and Mass Transfer, 2017, 113: 514-523. DOI:10.1016/j.ijheatmasstransfer.2017.05.121.
[12] Okada K, Ozoe H.Experimental heat transfer rates of natural convection of molten Gallium suppressed under an external magnetic field in either the X, Y, or Z direction[J]. Journal of Heat Transfer, 1992, 114(1): 107-114. DOI:10.1115/1.2911234.
[13] Ghalambaz M, Doostanidezfuli A, Zargartalebi H, et al.MHD phase change heat transfer in an inclined enclosure: Effect of a magnetic field and cavity inclination[J]. Numerical Heat Transfer, Part A: Applications, 2017, 71(1): 91-109. DOI:10.1080/10407782.2016.1244397.
[14] Feng Y C, Li H X, Li L X, et al.Investigation of the effect of magnetic field on melting of solid gallium in a bottom-heated rectangular cavity using the lattice Boltzmann method[J]. Numerical Heat Transfer, Part A: Applications, 2016, 69(11): 1263-1279. DOI:10.1080/10407782.2015.1127732.
[15] Haddad Z, Iachachene F, Zidouni F, et al.Magnetic field effects on melting and solidification of PCMs in an isosceles triangular cavity[J]. Journal of Thermal Analysis and Calorimetry, 2022, 147(7): 4697-4709. DOI:10.1007/s10973-021-10857-5.
[16] Saha S K.Dynamics of phase change of gallium under magnetic field and thermocapillary effects under variable gravity conditions[J]. Thermal Science and Engineering Progress, 2022, 29: 101234. DOI:10.1016/j.tsep.2022.101234.
[17] Yamanaka Y, Kakimoto K, Ozoe H, et al.Rayleigh-Benard oscillatory natural convection of liquid gallium heated from below[J]. Chemical Engineering Journal, 1998, 71(3): 201-205. DOI:10.1016/S1385-8947(98)00100-4.
[18] 孙思睿, 张杰, 倪明玖. 横向磁场下侧壁加热方腔熔化的数值模拟研究[J]. 力学学报, 2022, 54(9): 2377-2386. DOI: 10.6052/0459-1879-22-155.
[19] Li M, Jiao Z J, Jia P.Melting processes of phase change materials in a horizontally placed rectangular cavity[J]. Journal of Fluid Mechanics, 2022, 950: A34. DOI:10.1017/jfm.2022.751.
[20] Okabe T, Miyanishi T, Miyagawa T, et al.Spatio-temporal measurement of natural convective heat transfer on melting process using infrared thermography[J]. International Journal of Heat and Mass Transfer, 2021, 181: 121882. DOI:10.1016/j.ijheatmasstransfer.2021.121882.
[21] Parsazadeh M, Malik M, Duan X L, et al.Numerical study on melting of phase change material in an enclosure subject to Neumann boundary condition in the presence of Rayleigh-Bénard convection[J]. International Journal of Heat and Mass Transfer, 2021, 171: 121103. DOI:10.1016/j.ijheatmasstransfer.2021.121103.

强磁场影响下金属相变传热的MHD效应实验研究^*

Experimental study of the MHD effect of phase change heat transfer in metals under the influence of a strong magnetic field

PDF (PC)

可视化

摘要/Abstract

引用本文

使用本文

参考文献

相关文章 14

编辑推荐

Metrics

本文评价

访问统计

联系我们

[1]	程有基, 陈新元, 阳倦成, 倪明玖. 液态金属热对流典型流动结构实验研究[J]. 中国科学院大学学报, 2023, 40(2): 155-164.
[2]	董泉润, 阳倦成, 倪明玖. 水平磁场作用下液态金属自由射流破碎特性的实验研究[J]. 中国科学院大学学报, 2022, 39(5): 577-585.
[3]	卓琦皓, 潘君华, 倪明玖. 磁场和自由界面热流下二维液态锡膜流的传热模拟[J]. 中国科学院大学学报, 2021, 38(6): 741-749.
[4]	雷天扬, 孟旭, 王增辉, 倪明玖. 强磁场下液态金属微槽道流动与换热实验研究[J]. 中国科学院大学学报, 2021, 38(4): 459-466.
[5]	任东伟, 阳倦成, 倪明玖. 水平磁场作用下金属液滴撞击电解质液池表面的实验研究[J]. 中国科学院大学学报, 2021, 38(4): 442-449.
[6]	周仲凯, 王增辉, 陈然. 强磁场下液态金属在竖直平板外的自由对流换热[J]. 中国科学院大学学报, 2020, 37(1): 13-19.
[7]	于星星, 张杰, 倪明玖. 水平磁场中液态金属射流的三维数值研究[J]. 中国科学院大学学报, 2019, 36(4): 481-486.
[8]	齐天煜, 阳倦成, 倪明玖. 展向磁场作用下液态金属GaInSn多层膜流实验研究[J]. 中国科学院大学学报, 2019, 36(3): 320-325.
[9]	陈然, 王增辉, 倪明玖. 强磁场对导电流体热毛细流动和换热影响的实验研究[J]. 中国科学院大学学报, 2019, 36(1): 25-30.
[10]	李粲, 王增辉, 贾潇, 倪明玖. 强磁场和电场作用下的液态金属飞溅抑制的实验研究[J]. 中国科学院大学学报, 2018, 35(4): 444-450.
[11]	贾潇, 王增辉. 等离子体与液态金属相互作用的不稳定现象分析[J]. 中国科学院大学学报, 2016, 33(1): 50-56.
[12]	王进进, 张杰, 倪明玖. 均匀磁场中初始静止的液态金属在电流作用下三维运动的数值研究[J]. 中国科学院大学学报, 2015, 32(2): 166-171.
[13]	张龙艳, 王增辉. 液态金属热输运过程的分子动力学模拟[J]. 中国科学院大学学报, 2015, 32(1): 25-30.
[14]	汪世栋, 王增辉, 倪明玖. 液态金属中气泡上升的超声波测速实验研究与数值模拟[J]. 中国科学院大学学报, 2013, 30(5): 598-602.