Published January 30, 2023 | Version CC BY-NC-ND 4.0
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Battery Thermal Management System for Electric Vehicles

Authors/Creators

  • 1. Assistant Professor, Department of Electronics and Communication, BMS College of Engineering, Bangalore (Karnataka), India.
  • 2. PG student, Department of Electronics and Communication, BMS College of Engineering, Bangalore (Karnataka), India.

Contributors

Contact person:

  • 1. Assistant Professor, Department of Electronics and Communication, BMS College of Engineering, Bangalore (Karnataka), India.

Description

Abstract: Electrical vehicles (EVs) as a result of their rapid evolution and growing popularity, zero-emission, and high tank-to-wheelefficiency. Though, some features, particularly those relating to battery performance, cost, lifetime, and protection, restrict the development of the electrical car. In order to operate at peak efficiency under various circumstances, battery management is therefore required. The BTMS is essential for controlling the thermal performance of the battery. The BTMS technologies include heating, air conditioning, liquid cooling, direct refrigerant cooling, phase change material (PCM) cooling, and thermoelectric cooling. Performance, weight, size, cost, dependability, safety, and energy consumption are trade-offs analyzed for these systems. According tothe analysis the system ismade up of two coolant loops, one refrigeration loop, and one cabin HVAC loop. The batteries, drivetrain, and cabin all contribute to the thermal burden. The model of these system is been built in the software MATLAB/SIMULINK. Based on the outcomes of the simulation, BTMS is crucial for regulating battery thermal behavior. Through the integration of thesimulation model with battery thermal and ML models, next research might be more thorough and precise.

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Published By: Lattice Science Publication (LSP) © Copyright: All rights reserved.

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Journal article: 2582-8339 (ISSN)

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Subjects

ISSN
2582-8339
Retrieval Number
100.1/ijsepm.A9017013123
Journal Website
https://www.ijsepm.latticescipub.com/