High heat flux thermal management through liquid metal driven with electromagnetic induction pump

Chuanke LIU , Zhizhu HE

Front. Energy ›› 2022, Vol. 16 ›› Issue (3) : 460 -470.

PDF (2900KB)
Front. Energy ›› 2022, Vol. 16 ›› Issue (3) : 460 -470. DOI: 10.1007/s11708-022-0825-9
RESEARCH ARTICLE
RESEARCH ARTICLE

High heat flux thermal management through liquid metal driven with electromagnetic induction pump

Author information +
History +
PDF (2900KB)

Abstract

In this paper, a novel liquid metal-based minichannel heat dissipation method was developed for cooling electric devices with high heat flux. A high-performance electromagnetic induction pump driven by rotating permanent magnets is designed to achieve a pressure head of 160 kPa and a flow rate of 3.24 L/min, which could enable the liquid metal to remove the waste heat quickly. The liquid metal-based minichannel thermal management system was established and tested experimentally to investigate the pumping capacity and cooling performance. The results show that the liquid metal cooling system can dissipate heat flux up to 242 W/cm2 with keeping the temperature rise of the heat source below 50°C. It could remarkably enhance the cooling performance by increasing the rotating speed of permanent magnets. Moreover, thermal contact resistance has a critical importance for the heat dissipation capacity. The liquid metal thermal grease is introduced to efficiently reduce the thermal contact resistance (a decrease of about 7.77 × 10−3 °C/W). This paper provides a powerful cooling strategy for thermal management of electric devices with large heat power and high heat flux.

Graphical abstract

Keywords

high heat flux / liquid metal / electromagnetic pump / minichannel heat sink / thermal interface material

Cite this article

Download citation ▾
Chuanke LIU, Zhizhu HE. High heat flux thermal management through liquid metal driven with electromagnetic induction pump. Front. Energy, 2022, 16(3): 460-470 DOI:10.1007/s11708-022-0825-9

登录浏览全文

4963

注册一个新账户 忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within
[1]

Yang X H, Liu J. Advances in liquid metal science and technology in chip cooling and thermal management. Advances in Heat Transfer, 2018, 50 : 187– 300

[2]

Hamidnia M, Luo Y, Wang X D. Application of micro/nano technology for thermal management of high power LED packaging–a review. Applied Thermal Engineering, 2018, 145 : 637– 651

[3]

Habibi Khalaj A, Halgamuge S K A Review on efficient thermal management of air-and liquid-cooled data centers: from chip to the cooling system. Applied Energy, 2017, 205: 1165– 1188
[4]

Qian Z, Li Y, Rao Z. Thermal performance of lithium-ion battery thermal management system by using mini-channel cooling. Energy Conversion and Management, 2016, 126 : 622– 631

[5]

Lee J, Ki S, Seo D. . Liquid cooling module incorporating a metal foam and fin hybrid structure for high power insulated gate bipolar transistors (IGBTs). Applied Thermal Engineering, 2020, 173 : 115230

[6]

Liu D, Zhao F Y, Yang H X. . Thermoelectric mini cooler coupled with micro thermosiphon for CPU cooling system. Energy, 2015, 83 : 29– 36

[7]

Yeh L T. Review of heat transfer technologies in electronic equipment. Journal of Electronic Packaging, 1995, 117( 4): 333– 339

[8]

Tuckerman D B, Pease R F W. High-performance heat sinking for VLSI. IEEE Electron Device Letters, 1981, 2( 5): 126– 129

[9]

Feng Z, Li P. Fast thermal analysis on GPU for 3D ICs with integrated microchannel cooling. IEEE Transactions on Very Large Scale Integration Systems, 2012, 21( 8): 1526– 1539

[10]

Chein R, Chuang J. Experimental microchannel heat sink performance studies using nanofluids. International Journal of Thermal Sciences, 2007, 46( 1): 57– 66

[11]

Dixit T, Ghosh I. Review of micro-and mini-channel heat sinks and heat exchangers for single phase fluids. Renewable & Sustainable Energy Reviews, 2015, 41 : 1298– 1311

[12]

Mahalingam M. Thermal management in semiconductor device packaging. Proceedings of the IEEE, 1985, 73( 9): 1396– 1404

[13]

Mehendale S S, Jacobi A M, Shah R K. Fluid flow and heat transfer at micro-and meso-scales with application to heat exchanger design. Applied Mechanics Reviews, 2000, 53( 7): 175– 193

[14]

Muhammad A, Selvakumar D, Wu J. Numerical investigation of laminar flow and heat transfer in a liquid metal cooled mini-channel heat sink. International Journal of Heat and Mass Transfer, 2020, 150 : 119265

[15]

Xie X L, Liu Z J, He Y L. . Numerical study of laminar heat transfer and pressure drop characteristics in a water-cooled minichannel heat sink. Applied Thermal Engineering, 2009, 29( 1): 64– 74

[16]

Sohel M R, Khaleduzzaman S S, Saidur R. . An experimental investigation of heat transfer enhancement of a minichannel heat sink using Al2O3-H2O nanofluid. International Journal of Heat and Mass Transfer, 2014, 74 : 164– 172

[17]

Ijam A, Saidur R, Ganesan P. Cooling of minichannel heat sink using nanofluids. International Communications in Heat and Mass Transfer, 2012, 39( 8): 1188– 1194

[18]

Liu X, Yu J. Numerical study on performances of mini-channel heat sinks with non-uniform inlets. Applied Thermal Engineering, 2016, 93 : 856– 864

[19]

Hung T C, Yan W M, Li W P. Analysis of heat transfer characteristics of double-layered microchannel heat sink. International Journal of Heat and Mass Transfer, 2012, 55( 11−12): 3090– 3099

[20]

Yang X H, Tan S C, Ding Y J. . Flow and thermal modeling and optimization of micro/mini-channel heat sink. Applied Thermal Engineering, 2017, 117 : 289– 296

[21]

Wang H, Chen Z, Gao J. Influence of geometric parameters on flow and heat transfer performance of micro-channel heat sinks. Applied Thermal Engineering, 2016, 107 : 870– 879

[22]

Lee J, Mudawar I. Assessment of the effectiveness of nanofluids for single-phase and two-phase heat transfer in micro-channels. International Journal of Heat and Mass Transfer, 2007, 50( 3−4): 452– 463

[23]

Wang Q, Yu Y, Liu J. Preparations, characteristics and applications of the functional liquid metal materials. Advanced Engineering Materials, 2018, 20( 5): 1700781

[24]

Cao L X, Yin T, Jin M X. . Flexible circulated-cooling liquid metal coil for induction heating. Applied Thermal Engineering, 2019, 162 : 114260

[25]

de Castro I A, Chrimes A F, Zavabeti A. . A gallium-based magnetocaloric liquid metal ferrofluid. Nano Letters, 2017, 17( 12): 7831– 7838

[26]

Gu J, She J, Yue Y. Micro/nanoscale thermal characterization based on spectroscopy techniques. ES Energy & Environment, 2020, 9( 2): 15– 27

[27]

Zhang X D, Zhou Y X, Liu J. A novel layered stack electromagnetic pump towards circulating metal fluid: design, fabrication and test. Applied Thermal Engineering, 2020, 179 : 115610

[28]

Tawk M, Avenas Y, Kedous-Lebouc A. . Numerical and experimental investigations of the thermal management of power electronics with liquid metal mini-channel coolers. IEEE Transactions on Industry Applications, 2013, 49( 3): 1421– 1429

[29]

Sun P, Zhang H, Jiang F C. . Self-driven liquid metal cooling connector for direct current high power charging to electric vehicle. eTransportation, 2021, 10 : 100132

[30]

Zhang X D, Yang X H, Zhou Y X. . Experimental investigation of galinstan based minichannel cooling for high heat flux and large heat power thermal management. Energy Conversion and Management, 2019, 185 : 248– 258

[31]

Zhou X, Gao M, Gui L. A liquid-metal based spiral magnetohydrodynamic micropump. Micromachines, 2017, 8( 12): 365

[32]

Wang Y, Zhang P, Tan S. . Experimental and numerical analysis on a compact liquid metal blade heat dissipator with twin stage electromagnetic pumps. International Communications in Heat and Mass Transfer, 2019, 104 : 15– 22

[33]

Bucenieks I E. Perspectives of using rotating permanent magnets in the design of electromagnetic induction pumps. Magnetohydrodynamics, 2000, 151– 156
[34]

Wang X, Kolesnikov Y. A numerical visualization of physical fields in an electromagnetic pump with rotating permanent magnets. Magnetohydrodynamics, 2014, 50( 2): 139– 156

[35]

Koroteeva E, Ščepanskis M, Bucenieks I. . Numerical modeling and design of a disk-type rotating permanent magnet induction pump. Fusion Engineering and Design, 2016, 106 : 85– 92

[36]

Bucenieks I E. High pressure and high flowrate induction pumps with permanent magnets. Magnetohydrodynamics, 2003, 39( 4): 411– 418

[37]

Hvasta M G, Nollet W K, Anderson M H. Designing moving magnet pumps for high-temperature, liquid-metal systems. Nuclear Engineering and Design, 2018, 327 : 228– 237

[38]

Mirhoseini S M H, Diaz-Pacheco R R, Volpe F A. Passive and active electromagnetic stabilization of free-surface liquid metal flows. Magnetohydrodynamics, 2017, 53( 1): 45– 54

[39]

Bojarevics A, Beinerts T, Gelfgat Y. . Permanent magnet centrifugal pump for liquid aluminium stirring. International Journal of Cast Metals Research, 2016, 29( 3): 154– 157

[40]

Miner A, Ghoshal U. Cooling of high-power-density microdevices using liquid metal coolants. Applied Physics Letters, 2004, 85( 3): 506– 508

[41]

Bergman T L Incropera F P DeWitt D P. Fundamentals of Heat and Mass Transfer. New York: John Wiley & Sons, 2011
[42]

Liu D, Garimella S V. Analysis and optimization of the thermal performance of microchannel heat sinks. International Journal of Numerical Methods for Heat & Fluid Flow, 2005, 15( 1): 7– 26

[43]

Harms T M, Kazmierczak M J, Gerner F M. Developing convective heat transfer in deep rectangular microchannels. International Journal of Heat and Fluid Flow, 1999, 20( 2): 149– 157

[44]

Holman J P Gajda W J. Experimental Methods for Engineers. 5th ed. New York: McGraw-Hill, 1989

RIGHTS & PERMISSIONS

Higher Education Press

AI Summary AI Mindmap
PDF (2900KB)

7310

Accesses

0

Citation

Detail
Sections
Recommended

AI思维导图

/