@inproceedings{10d794adb6f448b980f956f48202d4e4,
title = "Analysis of a Battery Thermal Management System for Electric Vehicles using Heat Pipe Technology",
abstract = "This paper presents an analysis of the performance of a heat pipe assisted battery thermal management system (BTMS) as a means of passive heat dissipation from EV batteries to minimise required pumping power. A BTMS incorporating both standard heat pipes and multi-branched heat pipes (MBHPs) is analysed. The standard heat pipe configuration is analysed experimentally using a custom-built test rig and numerically using thermal equivalent circuit (TEC) models developed using MATLAB{\textquoteright}s Simscape software. The MBHP setup is analysed numerically having validated the TEC models using the experimental data from the standard configuration. Experimental results showed that the standard heat pipe BTMS provided sufficient cooling at heat loads of <40W. However, at heat loads of 40W the maximum battery temperature marginally exceeded the maximum temperature criteria with a maximum battery block temperature of 42.9oC and temperature difference between battery blocks of 4.3oC recorded. Due to an increase in heat transfer coefficient with increasing coolant flow rate, the battery block temperature and temperature difference decrease. This decrease in temperature is counteracted by a decrease in the coefficient of performance of the cold plate by approximately 70% as pumping power increases due to increased pressure drop across the cold plate. This showed there are marginal gains to increasing flow rate in the BTMS. Numerical analysis of both setups shows a similar temperature response of the simulated batteries to the experimental setup with analytical results being within 15% the of experimental values. Therefore, a TEC can be used to predict battery temperatures. Numerical results show increased battery temperature for an MBHP setup but kept within the operating range for heat loads of <20W suggesting MBHP{\textquoteright}s can perform sufficiently for normal battery discharge rates.",
keywords = "BMTS for Elective Vehicles, Heat Pipes, Simulink, Thermal Management",
author = "Eoin Guinan and Joseph Mooney and Johnathan Ottman and Jeff Punch and Vanessa Egan",
note = "Publisher Copyright: {\textcopyright} 2022, Avestia Publishing. All rights reserved.; 8th World Congress on Mechanical, Chemical, and Material Engineering, MCM 2022 ; Conference date: 31-07-2022 Through 02-08-2022",
year = "2022",
doi = "10.11159/htff22.161",
language = "English",
isbn = "9781990800108",
series = "Proceedings of the World Congress on Mechanical, Chemical, and Material Engineering",
publisher = "Avestia Publishing",
editor = "Huihe Qiu and Yuwen Zhang and Marcello Iasiello",
booktitle = "Proceedings of the 8th World Congress on Mechanical, Chemical, and Material Engineering, MCM 2022",
}