What question did this study set out to answer?

The aim is to enhance thermal management in lithium-ion batteries using a hybrid methodology integrating machine learning and optimization techniques.

March 5, 2026Open Access

Design of a Li-ion battery cooling system incorporating PCM, heat pipes, and liquid circuits using marine predator algorithm-enhanced ANN and multi-verse optimization

Key Points

The aim is to enhance thermal management in lithium-ion batteries using a hybrid methodology integrating machine learning and optimization techniques.
Introduced a four-phase framework for battery thermal management systems (BTMS)
Utilized GA-MLPNN and MPA-MLPNN for predictive modeling of thermal indices
Performed multi-objective optimization using MOMVO algorithm
Conducted geometric spacing analyses to ascertain effects on thermal regulation
MPA-MLPNN provided the highest precision in forecasting temperature differentials (ΔT, R > 0.9985)
GA-MLPNN excelled in predicting peak temperature (Tmax, R > 0.9986) and energy density (ED, R > 0.999)
Optimal designs reduced hotspots by adopting thicker designs (~3.8-3.9 mm; Tmax ~ 38-39 °C) while lower energy densities (~139-144 Wh/kg)
Thinner designs increased energy density (~157 Wh/kg) but degraded thermal stability
Intermediate configurations achieved balanced outcomes, confirming geometry's critical role in thermal management

Abstract

Managing heat generation in lithium-ion batteries remains a major obstacle, as excessive temperatures and non-uniform thermal distribution can significantly undermine safety, operational efficiency, and service life. To mitigate these challenges, this research introduces a structured hybrid methodology for advancing battery thermal management systems (BTMS). The approach integrates machine learning-driven forecasting, optimization techniques, and multi-criteria evaluation within a four-phase framework: preprocessing of data, predictive modeling through hybrid learning algorithms, optimization of design variables, and systematic decision analysis. Two hybrid predictive schemes were constructed, GA-MLPNN and MPA-MLPNN, to estimate critical thermal and performance indices. Comparative assessment revealed that MPA-MLPNN exhibited the highest precision in forecasting temperature differentials (ΔT, R > 0.9985), whereas GA-MLPNN delivered superior predictive reliability for peak temperature (Tmax, R > 0.9986) and energy density (ED, R > 0.999). Multi-objective optimization using the MOMVO algorithm illuminated inherent trade-offs among heat distribution, maximum temperature reduction, and energy storage capacity. For instance, adopting thicker MHPA layers (~ 3.8-3.9 mm) and taller configurations (~ 18-25 mm) effectively reduced hotspots, producing ΔT values of ~ 1.8-2.5 °C and Tmax of ~ 38-39 °C, though at the expense of lower ED (~ 139-144 Wh/kg). Conversely, thinner designs (~ 2.6-2.8 mm) elevated energy density (~ 157 Wh/kg) but impaired thermal stability. Intermediate geometries offered more balanced outcomes, with spacing analyses confirming geometry as a decisive factor in thermal regulation. Finally, multi-criteria evaluation through the CoCoSo method translated Pareto-optimal fronts into practical design recommendations, demonstrating adaptability across diverse operational priorities, including safety-focused, high-capacity, and compromise-oriented battery applications.

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Cite This Study

Ali et al. (Mon,) studied this question.

synapsesocial.com/papers/69a91cbed6127c7a504bfaf0 https://doi.org/https://doi.org/10.1038/s41598-026-41155-5

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