Thermal management in high-power lithium-ion Batteries: Synergistic effects of phase change material thickness, graphene enhancers, and active cooling systems

Thermal management in high-power lithium-ion Batteries: Synergistic effects of phase change material thickness, graphene enhancers, and active cooling systems

Effective thermal management is critical to mitigating thermal runaway risks, optimizing performance, and extending the operational lifespan of lithium-ion batteries (LIBs) in high-rate applications. This study systematically evaluates four thermal management strategies for a 14.6 Ah LIB under aggre...

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Bibliographic Details
Main Authors: Saeed Rahmanian, Hossein Rahmanian-Koushkaki, Khashayar Hosseinzadeh
Format: Article
Language:English
Published: Elsevier 2025-10-01
Series:Case Studies in Thermal Engineering
Subjects:
Lithium battery
Battery thermal management
Phase change materials
Heat pipe
Model NTGK
Online Access:http://www.sciencedirect.com/science/article/pii/S2214157X25010317
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Summary:Effective thermal management is critical to mitigating thermal runaway risks, optimizing performance, and extending the operational lifespan of lithium-ion batteries (LIBs) in high-rate applications. This study systematically evaluates four thermal management strategies for a 14.6 Ah LIB under aggressive discharge currents (1C, 3C, 5C): (1) baseline (no thermal control), (2) phase change material (PCM) with thickness variations, (3) hybrid PCM-K-enhancer (copper foam, graphene, metal plates) systems, and (4) active cooling (heat pipes + forced air convection). High-fidelity 3D simulations in ANSYS Fluent V22 quantified temperature uniformity, peak temperature suppression, and transient phase change behavior.At 5C discharge, baseline tests revealed unsafe peak temperatures of 84.03 °C. PCM thickness optimization demonstrated a nonlinear cooling effect: 1 mm PCM reduced peak temperature to 66.91 °C, while 3 mm PCM achieved 55.38 °C, underscoring the role of latent heat capacity scaling. Graphene-based K-enhancers outperformed copper foam and metal plates, synergizing with PCM to limit temperatures to 47.82 °C through thermal bridging. Synergistic integration of optimized PCM thickness (2 mm), graphene-enhanced thermal bridges, and heat-pipe cooling achieved a 53.3 % temperature reduction vs. baseline (39.23 °C).The study introduces a hierarchical thermal management framework, demonstrating that hybrid systems integrating optimized PCM thickness, graphene-enhanced interfacial conductivity, and active cooling achieve superior thermal equilibrium. These findings advance the design of multi-scale thermal regulation strategies for high-power LIB packs in electric vehicles.
ISSN:2214-157X

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