한국해양대학교

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A Study on Thermal Management of Lithium Ion Battery Pack

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dc.contributor.advisor Jong-Rae Cho -
dc.contributor.author LI QUANYI -
dc.date.accessioned 2022-06-23T08:57:45Z -
dc.date.available 2022-06-23T08:57:45Z -
dc.date.created 20220308093447 -
dc.date.issued 2022 -
dc.identifier.uri http://repository.kmou.ac.kr/handle/2014.oak/12849 -
dc.identifier.uri http://kmou.dcollection.net/common/orgView/200000603129 -
dc.description.abstract In the face of global energy shortage and environment pollution, the development of new energy has become the direction of scientific research in recent years. The Lithiumion battery has attracted much attention for its good safety, specific energy, specific capacity, cycle life and other advantages. Temperature has a significant effect on battery performance during battery operation. If the temperature is too high or too low, or the temperature distribution is uneven, the battery capacity decreases. The use of efficient battery thermal management system is very important to ensure battery performance. During charging and discharging, most of the battery's capacity is used to drive the load, and a small portion of the energy forms parasitic power in the form of heat. This part of the heat if not dissipated in time, will directly threaten the safety of the battery system.-ixTherefore, it is necessary to optimize the thermal management system of battery system to improve its heat dissipation performance. In this paper, it was the target that the maximum temperature and temperature difference were decreased to ensure the optimal working temperature range for lithium ion battery under different cooling system using different methods. The structure optimization of air cooling, liquid cooling, phase change materials and the coupling between liquid cooling and phase change materials was carried out according to the power battery of different application scenarios. In phase change materials, the influence of melting temperature on the cooling performance of phase change materials was simulated. Specific work to be carried out includes the following aspects: It was to decrease the heat generation inside battery as the starting point. As for air cooling, the place between electrode terminal and battery body was optimized by adding the material that conduct electricity better. It was to find the appropriate thickness to decrease the maximum temperature. Meanwhile, the space and tilt angle between batteries were adjusted to achieve the optimal working temperature. When the space was 3.5 mm and the tilt angle was 2.5°, the results was best for air cooling in this case. The liquid cooling is used to high power situation. The reasonable layout of cooling pipe can effectively reduce the number of pipes. Meanwhile, the suitable flow rate of liquid can improve the cooling efficiency of liquid to decrease the extra energy consumption, so the 0.9 m/s was selected. By the way, the circle shape was selected as the section of cooling pipe. The phase change material can help batteries temperature more uniform. So, the thickness and layout of phase change material were studied to make the better plan to-xdecrease the temperature difference. The coupling cooling system of liquid cooling and phase change material was designed according to the reasonable layout of phase change material. The melting temperature of phase change material was researched in coupling cooling system. When the melting temperature was 302.6 K, the temperature distribution of battery pack was more uniform. It can be found that the maximum temperature and temperature difference were reduced at the end of discharge in different cooling system by the optimization results. First, the structure of single battery was optimized to decrease heat generation. The amount of heat generation can be decreased effectively by the suitable thickness of added material and reasonable layout of tab terminal. Then, the structure for battery pack and some parameters were adjusted to enhance cooling performance. The appropriate spacing “d” and pitch “θ” between batteries can improve cooling performance under air cooling method. The reasonable selection of cooling pipe section, flow rate of coolant and position of cooling pipe can decrease maximum temperature to improve cooling performance in liquid cooling method. At the last, the PCM was adopted to improve temperature uniformity in coupling cooling method. The reasonable melting temperature can helpfully boost temperature uniformity. The optimization result was shown as followed: The maximum temperature was 311.6 K in 1P7S battery pack under air-cooling system. When the flow rate of cooling liquid was 0.09 m/s, the maximum temperature was 307.18 K, and the maximum temperature difference between batteries was 8.51 K in 1P7S battery pack under liquid-cooling system. The maximum temperature and maximum temperature difference were 305.54 K and 5.65 K, respectively in coupling cooling system which was based on liquid cooling system -
dc.description.tableofcontents Chapter 1 Introduction 1 1.1 Background 1 1.2 Ways of battery pack cooling 5 1.3 Development status of battery pack cooling 7 1.4 Objective of study and road map of research 10 Chapter 2 Theoretical basis of simulation experiment 14 2.1 Work principle and heat generation mechanism of LIB 14 2.2 Effect of temperature on battery capacity 17 2.3 Models of battery 21 2.3.1 Heat generation model 22 2.3.2 Heat transfer model of LIB 24 2.3.3 Simplification of LIB model 25 2.3.4 Governing equations of calculation 26 2.4 Software and property of material28 2.4.1 Simulation software 28 2.4.2 Property of material 28 2.4.3 Simulation of model single battery and module 30 2.4.4 Thermal load and battery boundary conditions 31 2.4.5 Grid independence and FLUENT simulation 31 Chapter 3 Optimal analysis based on air cooling system for LIB pack 34 3.1 Effects of structure on battery heat generation 34 3.2 Analysis of simulation for optimization 35 3.3 Results and discussion 38 3.3.1 LIB performance indices 38 3.3.2 Thermal analysis with added material 39 3.3.3 Influence of LIB spacing 43 3.3.4 Thermal analysis of optimized internal structure 45 3.4 Chapter summary 48 Chapter 4 Optimization structure of liquid cooling system for LIB pack 49 4.1 Status of liquid cooling 49 4.2 System description 50 4.3 Results and discussion 53 4.3.1 Effects of terminal for heat generation 53 4.3.2 Effects of flow rate of coolant 55 4.3.3 Effects of section and position of cooling pipe 59 4.4 Chapter summary 61 Chapter 5 Combination of PCM and liquid cooling method 62 5.1 Application of PCM 62 5.1.1 PCM application in cooling field of lithium ion battery pack 62 5.1.2 Category of PCM 63 5.1.3 Compound temperature control strategy 65 5.2 Optimal design and simulation for coupling PCM and liquid cooling 67 5.3 Results and discussion 70 5.3.1 Effects of PCM thickness for single battery 70 5.3.2 Effects of PCM layout 72 5.3.3 Effect of PCM property 75 5.4 Chapter summary 79 Chapter 6 Conclusions 81 Acknowledgements 83 References 84 Appendix: UDF Program Code for PCM Properties 90 -
dc.language eng -
dc.publisher 한국해양대학교 대학원 -
dc.rights 한국해양대학교 논문은 저작권에 의해 보호받습니다. -
dc.title A Study on Thermal Management of Lithium Ion Battery Pack -
dc.type Dissertation -
dc.date.awarded 2022. 2 -
dc.embargo.liftdate 2022-03-08 -
dc.contributor.department 대학원 기계공학과 -
dc.description.degree Doctor -
dc.identifier.bibliographicCitation [1]LI QUANYI, “A Study on Thermal Management of Lithium Ion Battery Pack,” 한국해양대학교 대학원, 2022. -
dc.identifier.holdings 000000001979▲200000002763▲200000603129▲ -
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