Framework for rapid design and optimisation of immersive battery cooling system

Framework for rapid design and optimisation of immersive battery cooling system

<p dir="ltr">Effective battery thermal management system (BTMS) is critical for lithium-ion battery (LIB) safety and performance in electric vehicles. This study presents a CFD-driven optimisation framework for an immersion cooling BTMS using sustainable palm biodiesel as coolant. Th...

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Bibliographic Details
Main Author: Ali Almshahy (23544823) (author)
Other Authors: Z. Khatir (23356891) (author), K. J. Kubiak (23643670) (author), Mansour Al Qubeissi (20931869) (author)
Published: 2025
Subjects:
Engineering
Electrical engineering
Environmental engineering
Fluid mechanics and thermal engineering
Information and computing sciences
Artificial intelligence
Machine learning
Battery thermal management
Biodiesel coolant
Hybrid electric vehicles
Immersion cooling
Optimisation
Surrogate modelling
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Summary:<p dir="ltr">Effective battery thermal management system (BTMS) is critical for lithium-ion battery (LIB) safety and performance in electric vehicles. This study presents a CFD-driven optimisation framework for an immersion cooling BTMS using sustainable palm biodiesel as coolant. The Multi-scale Multi-Domain (NTGK) framework is conducted to effectively capture the complex interactions among various physicochemical processes. The Electrochemical-thermal Model (ECM) is applied using the Newman, Tiedeman, Gu, and Kim (NTGK) model. A conjugate heat transfer model for a 3S2P pouch cell module (20 Ah LiFePO₄) is developed and validated against experimental data (< 2% error). The CFD model of a battery module is developed to train an ultra-fast metamodel for battery geometry optimisation. Two key parameters are optimised, namely: battery gap spacing (3–10 mm) and inlet/outlet width (5–15 mm), via Optimal Latin Hypercube Sampling, Support Vector Regression, and GDE3 algorithm. Palm biodiesel is used as a dielectric coolant in the proposed system to preserve LIB temperature within 20–40°C, preventing thermal runaway and ensuring a lightweight BTMS design. Compared to a conventional 3M-Novec, the palm biodiesel achieved system lightweight by 43%. The findings can establish biofuel immersion cooling as an eco-friendly BTMS solution, achieving Pareto-optimal figures: T<sub>max</sub> < 29.9°C, ΔT < 5°C, and ΔP < 145.275 Pa (at 5C and 0.05 m/s).</p><h2 dir="ltr">Other Information</h2><p dir="ltr">Published in: Engineering with Computers<br>License: <a href="https://creativecommons.org/licenses/by/4.0" target="_blank">https://creativecommons.org/licenses/by/4.0</a><br>See article on publisher's website: <a href="https://dx.doi.org/10.1007/s00366-025-02228-7" target="_blank">https://dx.doi.org/10.1007/s00366-025-02228-7</a></p>

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