THERMAL SCIENCE

International Scientific Journal

Xuefei Gao

,

Ying Zhang

,

Xingyue Wu

,

Ziyi Xie

,

Xinyi Lin

,

Jun Wang

COOLING PERFORMANCE OF A MHPA@MOF BASED HYBRID PASSIVE BATTERY THERMAL MANAGEMENT SYSTEM FOR A MODULE WITH LARGE-CAPACITY PRISMATIC LITHIUM-ION BATTERY

ABSTRACT
Metal-organic frameworks are beginning to be employed in the thermal management system of lithium-ion batteries because of its high water absorption and enthalpy of phase change. However, its cooling performance is only preliminarily explored used in small cylindrical cells or a single large cell. The effect on multiple large-capacity cells has not be verified yet. In this study, a micro heat pipe arrays@MIL-101(Cr) hybrid battery thermal management system is proposed, and its cooling performance of different number of battery modules at different discharge rates is studied. Experimental results show that MIL-101(Cr) is evenly distributed, and the water vapor adsorption capacity reached 1.65 g/g. The maximum temperature of the micro heat pipe arrays@MIL-101(Cr) group was 36.42°C in the experiment of the four-cell battery pack at 1C discharge rate, which was 12.98°C lower than that of the natural cooling group and 3.05°C lower than that of the micro heat pipe arrays group. With the increase of the number of cells, the maximum temperature of the battery pack rises from 43.12°C to 47.37°C, and the temperature difference rises from 1.53°C to 5.57°C at 2C discharge rate. As the discharge rate increases, the maximum temperature of the battery consisting of four cells rises from 36.42°C to 47.37°C, and the maximum temperature difference rises from 2.87°C to 5.57°C, which suggests that the current micro heat pipe arrays@MOF based battery thermal management system be combined with an active thermal management system to ensure temperature control in high-rate and multi-battery modules.
KEYWORDS
Lithium-ion battery, Multi-battery module, MHPA, thermal management, MIL-101(Cr)
PAPER SUBMITTED: 2024-07-06
PAPER REVISED: 2024-09-02
PAPER ACCEPTED: 2024-10-12
PUBLISHED ONLINE: 2024-10-12
DOI REFERENCE: https://doi.org/10.2298/TSCI240706226G
CITATION EXPORT: view in browser or download as text file
THERMAL SCIENCE YEAR 2024, VOLUME 28, ISSUE Issue 6, PAGES [4695 - 4707]
REFERENCES
  1. Burdyny, T., Smith,W. A., The CO2 Reduction on Gas-Diffusion Electrodes and Why Catalytic Performance Must be Assessed at Commercially-Relevant Conditions, Energy and Environmental Science, 12 (2019), 5, pp. 1442-1453
  2. Hadjipaschalis, I., et al., Overview of Current and Future Energy Storage Technologies for Electric Power Applications, Renewable and Sustainable Energy Reviews, 13 (2009), 6-7, pp. 1513-1522
  3. Hall, P.J.,E.J. Bain, Energy-storage technologies and electricity generation, Energy Policy, 36 (2008), 12, pp. 4352-4355
  4. Zhu, Z., et al., Rechargeable Batteries for Grid Scale Energy Storage, Chemical Reviews, 122 (2022), 22, pp. 16610-16751
  5. Wang, Y., et al., Challenges and Opportunities to Mitigate the Catastrophic Thermal Runaway of High‐ Energy Batteries, Advanced Energy Materials, 13 (2023), 15, 2203841
  6. Hu, S., et al., A Hybrid Cooling Method with Low Energy Consumption for Lithium-Ion Battery under Extreme Conditions, Energy Conversion and Management, 266 (2022), 115831
  7. Hasani, A. H., et al., Thermal Behavior of Lithium-Ion Battery in Microgrid Application: Impact and Management System, International Journal of Energy Research, 45 (2021), 4, pp. 4967-5005
  8. Mallick, S., Gayen, D., Thermal Behaviour and Thermal Runaway Propagation in Lithium-Ion Battery Systems - A Critical Review, Journal of Energy Storage, 62 (2023), 106894
  9. Hailu, G., et al., Stationary Battery Thermal Management: Analysis of Active Cooling Designs, Batteries, 8 (2022), 3, 23
  10. Thakur, A. K., et al., A State-Of-The Art Review On Advancing Battery Thermal Management Systems For Fast-Charging, Applied Thermal Engineering, 226 (2023), 120303
  11. Lin, J., et al., Novel Battery Thermal Management Via Scalable Dew-Point Evaporative Cooling, Energy Conversion and Management, 283 (2023), 116948
  12. Xie, N., et al., Thermal Performance and Structural Optimization of a Hybrid Thermal Management System Based on MHPA/PCM/liquid Cooling for Lithium-Ion Battery, Applied Thermal Engineering, 235 (2023), 16
  13. Zeng, W., et al., Cooling Performance and Optimization of A New Hybrid Thermal Management System of Cylindrical Battery, Applied Thermal Engineering, 217 (2022), 14
  14. Weragoda, D. M., et al., A Comprehensive Review on Heat Pipe Based Battery Thermal Management Systems, Applied Thermal Engineering, 224 (2023), 120070
  15. Faghri, A., Review and Advances in Heat Pipe Science and Technology, Journal of Heat Transfer-Transactions of the ASME, 134 (2012), 12, 18
  16. Wang, S. S., et al., Performance Simulation of L-Shaped Heat Pipe and Air Coupled Cooling Process for Ternary Lithium Battery Module, Engineering Applications of Computational Fluid Mechanics, 18 (2024), 1, 18
  17. Dan, D., et al., Dynamic Thermal Behavior of Micro Heat Pipe Array-Air Cooling Battery Thermal Management System Based on Thermal Network Model, Applied Thermal Engineering, 162 (2019), 114183
  18. Luo, J., et al., Battery Thermal Management Systems (BTM) Based on Phase Change Material (PCM): A Comprehensive Review, Chemical Engineering Journal, 430 (2022), 132741
  19. Ma, C. Y., et al., A Copper Nanoparticle Enhanced Phase Change Material with High Thermal Conductivity and Latent Heat for Battery Thermal Management, Journal of Loss Prevention in the Process Industries, 78 (2022), 9
  20. Liu, Y., et al., High Latent Heat Phase Change Materials (PCM) with Low Melting Temperature for Thermal Management and Storage of Electronic Devices and Power Batteries: Critical Review, Renewable and Sustainable Energy Reviews, 168 (2022), 112783
  21. Huang, Q., et al., Thermal Management of Lithium-Ion Battery Pack through the Application of Flexible Form-Stable Composite Phase Change Materials, Applied Thermal Engineering, 183 (2021), 116151
  22. Akbarzadeh, M., et al., A Novel Liquid Cooling Plate Concept for Thermal Management of Lithium-Ion Batteries in Electric Vehicles, Energy Conversion and Management, 231 (2021), 113862
  23. Cai, G., et al., Metal-Organic Framework-Based Hierarchically Porous Materials: Synthesis and Applications, Chemical Reviews, 121 (2021), 20, pp. 12278-12326
  24. Zhao, T., et al., Lattice Oxygen-Mediated Co-O-Fe Formation in Co-MOF Via Fe Doping and Ligand Design for Efficient Oxygen Evolution, Journal of Materials Science and Technology, 189 (2024), Aug., pp. 183-190
  25. Li, W., et al., Rational Design and General Synthesis of Multimetallic Metal-Organic Framework Nano‐Octahedra for Enhanced Li-S Battery, Advanced Materials, 33 (2021), 45, 2105163
  26. Nabi, S., et al., Metal-Organic Framework Functionalized Sulphur Doped Graphene: A Promising Platform for Selective and Sensitive Electrochemical Sensing of Acetaminophen, Dopamine and H2O2, New Journal of Chemistry, 46 (2022), 4, pp. 1588-1600
  27. Li, W. Y., et al., A Novel Ni/Co Metal-Organic Framework with a Porous Organic Polymer Material as a Ligand for a High-Performance Supercapacitor and a Glucose Sensor, New Journal of Chemistry, 46 (2022), 47, pp. 22849-22861
  28. Rani, P., Srivastava, R., Tailoring the Catalytic Activity of Metal Organic Frameworks by Tuning the Metal Center and Basic Functional Sites, New Journal of Chemistry, 41 (2017), 16, pp. 8166-8177
  29. Rim, G., et al., Sub-Ambient Temperature Direct Air Capture of CO2 Using Amine-Impregnated MIL-101(Cr) Enables Ambient Temperature CO2 Recovery, JACS Au, 2 (2022), 2, pp. 380-393
  30. Wang, C., et al., A Thermal Management Strategy for Electronic Devices Based on Moisture Sorption-Desorption Processes, Joule, 4 (2020), 2, pp. 435-447
  31. Xu, J., et al., Near-Zero-Energy Smart Battery Thermal Management Enabled by Sorption Energy Harvesting from Air, ACS Central Science, 6 (2020), 9, pp. 1542-1554
  32. Tao, Y., et al., High-Performance and Long-Term Thermal Management Material of MIL-101Cr@ GO, Materials Today Physics, 22 (2022), 100572
  33. Yue, Q., et al., A Passive Thermal Management System with Thermally Enhanced Water Adsorbents for Lithium-Ion Batteries Powering Electric Vehicles, Applied Thermal Engineering, 207 (2022), 118156
  34. Hu, S., et al., Efficient Purification of Metal-Organic Framework and Its Trigger Strategy in Battery Thermal Management System, Energy Conversion and Management, 292 (2023), 117416
  35. Liu, X., et al., Hierarchically Porous Composite Fabrics with Ultrahigh Metal-Organic Framework Loading For Zero-Energy-Consumption Heat Dissipation, Science Bulletin, 67 (2022), 19, pp. 1991-2000
  36. Yoo, D. K., et al., Polyaniline-Loaded Metal-Organic Framework MIL-101(Cr): Promising Adsorbent for CO2 Capture with Increased Capacity and Selectivity by Polyaniline Introduction, Journal of CO2 Utilization, 28 (2018), Dec., pp. 319-325
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Cooling performance of a MHPA@MOF based hybrid passive battery thermal management system for a module with large-capacity prismatic lithium-ion battery

© 2024 Society of Thermal Engineers of Serbia. Published by the Vinča Institute of Nuclear Sciences, National Institute of the Republic of Serbia, Belgrade, Serbia. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution-NonCommercial-NoDerivs 4.0 International licence