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This is a In Vitro Study study.

August 17, 2025

CFD-Based Performance Evaluation of Microchannel Cooling for Electric Vehicle Battery Packs

Key Points

Ethylene glycol cooling resulted in a significant temperature drop of 42°C, improving overall thermal performance in electric vehicle battery packs.
Water cooling achieved a 28°C temperature drop while maintaining lower pressure loss, highlighting its practicality for standard applications.
Simulation using ANSYS Fluent evaluated heat flux, flow velocity, and pressure drop for both coolants under high-load scenarios.
Future research should explore nanofluids and AI strategies to optimize thermal management systems in electric vehicles.

Abstract

This study presents a computational analysis of a microchannel-based liquid cooling system for cylindrical lithium-ion battery packs in electric vehicles (EVs), using ANSYS Fluent. The investigation compares water and ethylene glycol as coolants under high-load conditions, with simulations focusing on temperature distribution, wall heat flux, flow velocity, and pressure drop. Ethylene glycol achieved better thermal performance with a 42°C temperature drop and peak wall heat flux of 0.5518 W/m² but suffered from a high pressure drop (~1557.2 Pa) due to its higher viscosity. Water provided a more balanced solution, offering a 28°C temperature drop, lower pressure loss (~741.4 Pa), and superior flow uniformity, making it more practical for standard EV applications. The study underscores the trade-off between cooling efficiency and hydraulic resistance and recommends future research involving nanofluids, transient simulations, and AI-driven thermal management strategies to further enhance BTMS performance.

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CFD-Based Performance Evaluation of Microchannel Cooling for Electric Vehicle Battery Packs

Key Points

Abstract

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