Cooling effectiveness enhancement of parallel air-cooled battery system through integration with multi-phase change materials
This work presents a numerical investigation of the integration of conventional parallel air-cooling battery system with multi-phase change materials (PCMs) to improve the cooling effectiveness at low power consumption (Pc) rate. The study considers various cells partitioning of the PCMs on nine dif...
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2025
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my.uniten.dspace-365552025-03-03T15:43:03Z Cooling effectiveness enhancement of parallel air-cooled battery system through integration with multi-phase change materials Mohammed A.G. Hasini H. Elfeky K.E. Wang Q. Hajara M.A. Om N.I. 57219281767 6507435998 56979298200 55521034600 58961819400 42162023000 Air Air intakes Battery Pack Cooling Cooling systems Inlet flow Phase change materials Thermal management (electronics) Air cooling Battery systems Cell partitioning Cell shapes Cooling effectiveness Inlet velocity Low-power consumption Multi phase change material Numerical investigations Parallel air cooling Lithium-ion batteries This work presents a numerical investigation of the integration of conventional parallel air-cooling battery system with multi-phase change materials (PCMs) to improve the cooling effectiveness at low power consumption (Pc) rate. The study considers various cells partitioning of the PCMs on nine different parallel air-cooled battery packs. The impact of PCMs pattern schemes, inclination angle of the manifold, and air inlet velocity are analysed by employing finite volume technique coupled with an enthalpy-porosity method. Compared with a typical parallel air-cooling system, despite 90% reduction in the air inlet velocity, the integrated system successfully lowers the maximum temperature (Tmax) by 12.0 K and improves uniformity of temperature distribution based on standard deviation (SDV) of temperature field by 43.9%. Subsequently, inclining the air inlet manifold to an angle close to vertical leads to a poor cooling performance. Also, a proper pattern of PCMs cells partitioning having a trapezoidal cell shape at the top and bottom, and a parallelogram cell shape at the midsection exhibits a better heat dissipation performance. Moreover, compared to the module with highest inlet velocity of 1.5 m/s, reducing the inlet velocity by 66.7% still controls Tmax at 313.13 K which is well below the critical limit, and decreases the Pc by 65.8%. ? 2024 Elsevier Masson SAS Final 2025-03-03T07:43:03Z 2025-03-03T07:43:03Z 2024 Article 10.1016/j.ijthermalsci.2024.109030 2-s2.0-85189022508 https://www.scopus.com/inward/record.uri?eid=2-s2.0-85189022508&doi=10.1016%2fj.ijthermalsci.2024.109030&partnerID=40&md5=dcfbf0237690ddbb625b298560c222a0 https://irepository.uniten.edu.my/handle/123456789/36555 201 109030 Elsevier Masson s.r.l. Scopus |
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Air Air intakes Battery Pack Cooling Cooling systems Inlet flow Phase change materials Thermal management (electronics) Air cooling Battery systems Cell partitioning Cell shapes Cooling effectiveness Inlet velocity Low-power consumption Multi phase change material Numerical investigations Parallel air cooling Lithium-ion batteries |
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Air Air intakes Battery Pack Cooling Cooling systems Inlet flow Phase change materials Thermal management (electronics) Air cooling Battery systems Cell partitioning Cell shapes Cooling effectiveness Inlet velocity Low-power consumption Multi phase change material Numerical investigations Parallel air cooling Lithium-ion batteries Mohammed A.G. Hasini H. Elfeky K.E. Wang Q. Hajara M.A. Om N.I. Cooling effectiveness enhancement of parallel air-cooled battery system through integration with multi-phase change materials |
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This work presents a numerical investigation of the integration of conventional parallel air-cooling battery system with multi-phase change materials (PCMs) to improve the cooling effectiveness at low power consumption (Pc) rate. The study considers various cells partitioning of the PCMs on nine different parallel air-cooled battery packs. The impact of PCMs pattern schemes, inclination angle of the manifold, and air inlet velocity are analysed by employing finite volume technique coupled with an enthalpy-porosity method. Compared with a typical parallel air-cooling system, despite 90% reduction in the air inlet velocity, the integrated system successfully lowers the maximum temperature (Tmax) by 12.0 K and improves uniformity of temperature distribution based on standard deviation (SDV) of temperature field by 43.9%. Subsequently, inclining the air inlet manifold to an angle close to vertical leads to a poor cooling performance. Also, a proper pattern of PCMs cells partitioning having a trapezoidal cell shape at the top and bottom, and a parallelogram cell shape at the midsection exhibits a better heat dissipation performance. Moreover, compared to the module with highest inlet velocity of 1.5 m/s, reducing the inlet velocity by 66.7% still controls Tmax at 313.13 K which is well below the critical limit, and decreases the Pc by 65.8%. ? 2024 Elsevier Masson SAS |
| author2 |
57219281767 |
| author_facet |
57219281767 Mohammed A.G. Hasini H. Elfeky K.E. Wang Q. Hajara M.A. Om N.I. |
| format |
Article |
| author |
Mohammed A.G. Hasini H. Elfeky K.E. Wang Q. Hajara M.A. Om N.I. |
| author_sort |
Mohammed A.G. |
| title |
Cooling effectiveness enhancement of parallel air-cooled battery system through integration with multi-phase change materials |
| title_short |
Cooling effectiveness enhancement of parallel air-cooled battery system through integration with multi-phase change materials |
| title_full |
Cooling effectiveness enhancement of parallel air-cooled battery system through integration with multi-phase change materials |
| title_fullStr |
Cooling effectiveness enhancement of parallel air-cooled battery system through integration with multi-phase change materials |
| title_full_unstemmed |
Cooling effectiveness enhancement of parallel air-cooled battery system through integration with multi-phase change materials |
| title_sort |
cooling effectiveness enhancement of parallel air-cooled battery system through integration with multi-phase change materials |
| publisher |
Elsevier Masson s.r.l. |
| publishDate |
2025 |
| _version_ |
1825816276726972416 |
| score |
13.244109 |