Paraffin/SiC as a Novel Composite Phase-Change Material for a Lithium-Ion Battery Thermal Management System

Wei Kang; Yiqiang Zhao; Xueheng Jia; Lin Hao; Leping Dang; Hongyuan Wei

doi:10.1007/s12209-020-00270-8

Transactions of Tianjin University ›› 2021, Vol. 27 ›› Issue (1) : 55 -63. DOI: 10.1007/s12209-020-00270-8

Research Article

Paraffin/SiC as a Novel Composite Phase-Change Material for a Lithium-Ion Battery Thermal Management System

Author information +

History +

PDF

Abstract

A lithium-ion battery thermal management system has always been a hot spot in the battery industry. In this study, a novel high-thermal-conductivity composite phase-change material (CPCM) made by paraffin wax and silicon was adopted to facilitate heat transfer. Moreover, high resistance or even insulation of CPCM is capable of preventing short circuits between the cells. The heat transfer mechanism of CPCMs was determined under a scanning electron microscope. A thermogravimetric analyzer was employed to determine the thermal stability. A differential scanning calorimeter was used to explore the thermophysical properties of the composite samples. By comparing the results of the experiment, it was reported that under the silicon carbide content of 5%, the parameters were better than others. The phase-change enthalpy of CPCM was 199.4 J/g, the leakage rate of liquid was 4.6%, and the melting point was 53.6 °C. To verify the practicality of CPCM, a three-dimensional layered battery pack model was built in the COMSOL Multiphysics software. By simulating the thermal runaway inside the battery packs of various materials, it was reported that the addition of CPCM significantly narrowed the temperature range of the battery pack from 300–370 to 303–304 K. Therefore, CPCM can effectively increase the rate of heat transfer to prevent the chain of thermal runaway reactions. It also enables the battery pack to run at a stable temperature.

Keywords

Lithium-ion battery / Phase-change material / Paraffin / Silicon carbide / Thermal runaway

Cite this article

Download citation ▾

Wei Kang, Yiqiang Zhao, Xueheng Jia, Lin Hao, Leping Dang, Hongyuan Wei. Paraffin/SiC as a Novel Composite Phase-Change Material for a Lithium-Ion Battery Thermal Management System. Transactions of Tianjin University, 2021, 27(1): 55-63 DOI:10.1007/s12209-020-00270-8

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]	Oró E, de Gracia A, Castell A, et al. Review on phase change materials (PCMs) for cold thermal energy storage applications. Appl Energy, 2012, 99: 513-533.

[2]	Telkes M Thermal storage for solar heating and cooling, 1975 Charlottesville University of Virginia

[3]	Ye WB Enhanced heat transfer numerical simulation and experimental research on phase change thermal energy storage heat exchanger of heat pump, 2012 Guangzhou South China University of Technology (in Chinese)

[4]	Wu SY Enhanced heat transfer experimental and simulation research of nanocomposite phase change materials, 2010 Guangzhou South China University of Technology (in Chinese)

[5]	Du K, Calautit J, Wang ZH, et al. A review of the applications of phase change materials in cooling, heating and power generation in different temperature Ranges. Appl Energy, 2018, 220: 242-273.

[6]	Pereira da Cunha J, Eames P Thermal energy storage for low and medium temperature applications using phase change materials—a review. Appl Energy, 2016, 177: 227-238.

[7]	Cui YQ Research on development of composite phase change humidity-control material in buildings. CIESC J, 2018, 69(S1): 1-7 (in Chinese)

[8]	Sharma A, Tyagi VV, Chen CR, et al. Review on thermal energy storage with phase change materials and applications. Renew Sustain Energy Rev, 2009, 13(2): 318-345.

[9]	Saffari M, de Gracia A, Ushak S, et al. Passive cooling of buildings with phase change materials using whole-building energy simulation tools: a review. Renew Sustain Energy Rev, 2017, 80: 1239-1255.

[10]	Cui YQ Thermal properties of phase change materials (CPCM) and their concise calculations for passive storage. Energy Storage Sci Technol, 2017, 6(2): 302-306 (in Chinese)

[11]	Zhao YF, Yang WSH, Li RJ et al (2020) Analysis on development trend of pure electric vehicles in China. Auto Engineer (07):14–17 (in Chinese)

[12]	Rietmann N, Hügler B, Lieven T Forecasting the trajectory of electric vehicle sales and the consequences for worldwide CO₂ emissions. J Cleaner Prod, 2020

[13]	Hallaj SA, Selman JR A novel thermal management system for electric vehicle batteries using phase-change material. J Electrochem Soc, 2000, 147(9): 3231.

[14]	Zhang L, Shi ZK Review on energy storage systems with CPCM for temperature control. Comput Appl Chem, 2017, 34(7): 528-532 (in Chinese)

[15]	Duan X, Naterer GF Heat transfer in phase change materials for thermal management of electric vehicle battery modules. Int J Heat Mass Transf, 2010, 53(23–24): 5176-5182.

[16]	Chiba R A series solution for heat conduction problem with phase change in a finite slab. Abstr Appl Anal, 2014

[17]	Kizilel R, Sabbah R, Selman JR, et al. An alternative cooling system to enhance the safety of Li-ion battery packs. J Power Sources, 2009, 194(2): 1105-1112.

[18]	Qu ZG, Li WQ, Wang JL, et al. Passive thermal management using metal foam saturated with phase change material in a heat sink. Int Commun Heat Mass Transf, 2012, 39(10): 1546-1549.

[19]	Qu ZG, Li WQ, Tao WQ Numerical model of the passive thermal management system for high-power Lithium ion battery by using porous metal foam saturated with phase change material. Int J Hydrog Energy, 2014, 39(8): 3904-3913.

[20]	Zhao R, Zhang SJ, Gu JJ, et al. An experimental study of Lithium ion battery thermal management using flexible hydrogel films. J Power Sources, 2014, 255: 29-36.

[21]	Zhang SJ, Zhao R, Liu J, et al. Investigation on a hydrogel based passive thermal management system for Lithium ion batteries. Energy, 2014, 68: 854-861.

[22]	Wilke S, Schweitzer B, Khateeb S, et al. Preventing thermal runaway propagation in Lithium ion battery packs using a phase change composite material: an experimental study. J Power Sources, 2017, 340: 51-59.

[23]	Yin XP Preparation and properties of paraffin/foam carbon shaped phase change energy storage materials, 2017 Beijing China University of Geosciences (in Chinese)

[24]	Chen H, Liu XL, Liu YY, et al. Effect of copper foam on the exothermic performance of phase change thermal storage system. Cryogen Eng, 2019, 1: 46-50 (in Chinese)

[25]	Xu Z, Huang P, Wu EH, et al. Electrical resistivity analysis of expanded graphite/paraffin composite phase change materials. Storage Energy Sci Technol, 2019, 8(2): 317-378 (in Chinese)

[26]	Zhou LX, Xu Zh, Li JQ Preparation and characterization of titanium dioxide coated paraffin phase change microcapsules. Modernization, 2019, 39(3): 82-86.

[27]	Yin SW, Li HK, Wang L, et al. Characterization and analysis of 80 ~ # paraffin/expanded graphite shaped composite phase change materials. Chem Progress, 2019, 38(3): 1494-1500 (in Chinese)

[28]	Xu ZX Classification and application of phase change energy storage materials. China Equip Eng, 2019, 2: 116-117 (in Chinese)

[29]	Feng XN, Gao Y, Li T, et al. Car lithium ion power battery thermal runaway Induction and expansion mechanism, modeling and prevention, 2016 Beijing Tsinghua University (in Chinese)