Thermal Management of Electric Vehicle Batteries Using Heat Pipe and Phase Change Materials

Amin, Muhammad; Ariantara, Bambang; Putra, Nandy; Sandi, Adjie Fahrizal; Abdullah, Nasruddin A.

doi:10.1051/e3sconf/20186703034

Cited by 16 publications

(6 citation statements)

References 13 publications

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“…Various EV thermal management systems can generally be classified into three categories based on the fluid and heat transfer mechanism, that is, passive, active, and hybrid active-passive methods (Ianniciello et al, 2017;Kim et al, 2019). The passive system relies solely on thermodynamics without any electrical power requirement, such as using a heat sink or Phase Change Materials (Amin et al, 2018;Budiman et al, 2020Budiman et al, , 2022Chen et al, 2014). Such a passive system is considerably more straightforward and economical in its design.…”

Section: Introductionmentioning

confidence: 99%

Visualization of Induced Counter-Rotating Vortices for Electric Vehicles Battery Module Thermal Management

Budiman¹,

Hasheminejad²,

Sudirja³

et al. 2022

Front. Heat Mass Transf.

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Streamwise development of counter-rotating vortices induced by three different types of chevron Vortex Generators (VGs) placed upstream an Electric Vehicles (EV) dummy battery module is experimentally visualized using a smoke-wire method. From the single chevron reference case, the mushroom-like vortices do not collapse until passing the module. When more chevrons are used in line, the vortices become more prominent. It can also be observed that the vortex sizes and shapes are significantly influenced by the spanwise base length of the chevron. The induced vortices from all three VGs suggest a potential heat transfer augmentation for the EV battery module application.

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Section: Introductionmentioning

confidence: 99%

Visualization of Induced Counter-Rotating Vortices for Electric Vehicles Battery Module Thermal Management

Budiman¹,

Hasheminejad²,

Sudirja³

et al. 2022

Front. Heat Mass Transf.

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“…This BTMS controls the temperature rise of the battery surface by less than 8 • C, even in 24 A discharge current and a high ambient temperature (40 • C). Amin et al [73] design a BTMS (see as Figure 8c) that can maintain the battery temperature below 50 • C at the maximum heat load of 50 W. Huang et al [74] designed a BTMS (see as Figure 8d), in which HP makes a huge contribution to heat transfer and thermal uniformity. Wu et al [75] designed a HP-based BTMS assisted by PCM and forced-air cooling (see as Figure 8e).…”

Section: Pcm Coupled With Hp and Active Cooling Methodsmentioning

confidence: 99%

Hybrid Battery Thermal Management System in Electrical Vehicles: A Review

et al. 2020

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The Li-ion battery is of paramount importance to electric vehicles (EVs). Propelled by the rapid growth of the EV industry, the performance of the battery is continuously improving. However, Li-ion batteries are susceptible to the working temperature and only obtain the optimal performance within an acceptable temperature range. Therefore, a battery thermal management system (BTMS) is required to ensure EVs’ safe operation. There are various basic methods for BTMS, including forced-air cooling, liquid cooling, phase change material (PCM), heat pipe (HP), thermoelectric cooling (TEC), etc. Every method has its unique application condition and characteristic. Furthermore, based on basic BTMS, more hybrid cooling methods adopting different basic methods are being designed to meet EVs’ requirements. In this work, the hybrid BTMS, as a more reliable and environmentally friendly method for the EVs, will be compared with basic BTMS to reveal its advantages and potential. By analyzing its cost, efficiency and other aspects, the evaluation criterion and design suggestions are put forward to guide the future development of BTMS.

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“…The obtained results show that using PCM and HP cooling method; the battery module temperature can be regulated very effectively and provides some useful design parameters for optimization of BTMS. The BTMS for prismatic LIB cells was studied by Amin et al [ 143 ] under three cooling conditions: cooling without HP/PCM, cooling with HP, and cooling with HP/PCM. The input heat load to the battery cell is varied from 20 to 50W.…”

Section: Experimental Btms Analyses Using Heat Pipes (Hps) Coupled Wi...mentioning

confidence: 99%

“…Discharge cycle Peak temperature, minimum temperature and temperature difference Deionized water Paraffin composites For a discharge rate of 5C or higher, the battery temperature may exceed 45 °C. The HP PCM usage with forced convection avoids the temperature imbalance among the cells [ 142 ] Prismatic battery cell Cooling methods, Heat load on the battery Maximum Temperature Water Beeswax HPs can reduce the temperature of the battery's surface by 7.1 °C, while the combination of HP + PCM reduces it by 10 °C [ 143 ] Prismatic battery cell Room temperature, Discharging current in amperes Maximum surface temperature, temperature difference, average battery surface temperature water Hydrated salt The proposed heating and cooling strategy for BTMS increases the electric energy output from 39.5 to 62.5% Even at high discharging rates, 2.6 °C can suppress the peak temperature difference in a battery cell [ 144 ] Cylindrical batteries Discharge rate, Cooling methods Maximum temperature, temperature difference Water Mixture of paraffin and graphite In combination with liquid-assisted PCM, heat pipes are a better choice for controlling the battery temperature within 44 °C for an extended time run. The temperature difference between batteries can be limited to 3 °C.…”

Section: Experimental Btms Analyses Using Heat Pipes (Hps) Coupled Wi...mentioning

confidence: 99%

A critical review on renewable battery thermal management system using heat pipes

Afzal

Razak

Samee

et al. 2023

J Therm Anal Calorim

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The critical review presented here exclusively covers the studies on battery thermal management systems (BTMSs), which utilize heat pipes of different structural designs and operating parameters as a cooling medium. The review paper is divided into five major parts, and each part addresses the role of heat pipes in BTMS categorically. Experimental studies, numerical analyses, combined experimental and numerical investigations, optimum utilization of a phase-change material (PCM) with a heat pipe (HP), oscillating heat pipe (OHP), and micro heat pipes combined with PCM for Li-ion BTMS using heat pipes are presented. The usage of HP’s and PCM can keep the temperature of the battery system in the desirable limit for a longer duration compared to other traditional and passive methods. More emphasis is made on how one can achieve a suitable cooling system design and structure, which may tend to enhance the energy density of the batteries, improve thermal performance at maximum and minimum temperature range. Arrangement of battery cells in a pack or module, type of cooling fluid used, heat pipe configuration, type of PCM used, working fluid in a heat pipe, and surrounding environmental conditions are reviewed. According to the study, the battery's effectiveness is significantly influenced by temperature. The usage of flat HPs and heat sink proves to be the best cooling method for keeping the battery working temperature below 50 °C and reduces the heat sink thermal resistance by 30%. With an intake temperature of 25 °C and a discharge rate of 1 L per minute, an HP that uses water as a coolant is also effective at regulating battery cell temperature and maintaining it below the permissible 55 °C range. Using beeswax as a PCM in HPs reduces the temperature of BTMS by up to 26.62 °C, while the usage of RT44 in HPs reduces the temperature of BTMS by 33.42 °C. The use of fins along with copper spreaders drastically decreases the temperature capability of HPTMS by 11 °C. MHPA shows excellent performance in controlling the battery temperature within 40 °C. The effective thermal management can be done by incorporating heat pipe alone or by coupling with liquid cooling or metal plate. However, extensive and extended research is required to improve thermal management to safely and effectively use the battery for day-to-day applications.

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Thermal Management of Electric Vehicle Batteries Using Heat Pipe and Phase Change Materials

Cited by 16 publications

References 13 publications

Visualization of Induced Counter-Rotating Vortices for Electric Vehicles Battery Module Thermal Management

Visualization of Induced Counter-Rotating Vortices for Electric Vehicles Battery Module Thermal Management

Hybrid Battery Thermal Management System in Electrical Vehicles: A Review

A critical review on renewable battery thermal management system using heat pipes

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