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Influence of pack orientation and fin design on hybrid PCM–liquid cooled Li-ion battery systems

Hamid‐Reza Bahrami

2025Energy Reports6 citationsDOIOpen Access PDF

Abstract

Effective thermal management is critical for lithium-ion battery safety and longevity in electric vehicles, particularly under high-discharge conditions. This study investigates a novel hybrid battery thermal management system (BTMS) integrating phase change material (PCM) RT35, liquid cooling, and aluminum fins, assessing the enhancement effects of adding cell-to-cell and cell-to-channel fins alongside pack orientation (θ = 0°, 30°, 60°, 90°). Using computational fluid dynamics (CFD), this study models a cylindrical cell array (18650-type, 3 C/5 C discharge) embedded in PCM, flanked by water-cooling channels. The model varies inclination angles and coolant velocities (0–0.5 m/s) to evaluate buoyancy-driven convection effects on maximum temperature (Tmax) and liquid fraction. Results show that, in the no-fin case, θ = 30° reduces Tmax by ∼6.7 K at 5 C compared to horizontal/vertical setups, driven by enhanced PCM recirculation. Moderate coolant velocities (0.05–0.2 m/s) optimize latent heat utilization, while higher velocities increase parasitic pumping power (∼100 ×) without thermal gains. Cell-to-channel fins reduce Tmax by 9.4 K at θ= 30°, outperforming cell-to-cell fins (as with the maximum 0.4 K reduction at θ=90°), enhancing conduction and convection in a hybrid PCM-liquid BTMS. Unlike prior studies isolating PCM or fixing orientation, this work couples fin enhancements, inclination, and flow, providing design maps for energy-efficient BTMS, guiding next-generation EV battery designs.

Topics & Concepts

CoolantFinMaterials scienceBattery (electricity)Thermal conductionPhase-change materialThermalBattery packConvectionWork (physics)Power (physics)Heat sinkHeat transferComputer coolingMechanical engineeringMechanicsConstructal lawOrientation (vector space)Reduction (mathematics)Hybrid systemForced convectionOptimal designThermal resistanceComputational fluid dynamicsEnhanced heat transferHeat transfer enhancementThermal management of electronic devices and systemsAluminiumPhase (matter)Convective heat transferAnnular finLatent heatNuclear engineeringAdvanced Battery Technologies ResearchPhase Change Materials ResearchAdvanced Battery Materials and Technologies
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