應用機器學習演算法設計具非等向熱傳性質電池儲能系統之熱管理策略

黃新棫; Xin-Yu Huang

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/90647

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	楊鏡堂	zh_TW
dc.contributor.advisor	Jing-Tang Yang	en
dc.contributor.author	黃新棫	zh_TW
dc.contributor.author	Xin-Yu Huang	en
dc.date.accessioned	2023-10-03T17:00:39Z	-
dc.date.available	2023-11-09	-
dc.date.copyright	2023-10-03	-
dc.date.issued	2023	-
dc.date.submitted	2023-07-25	-
dc.identifier.citation	Abada, S., Marlair, G., Lecocq, A., Petit, M., Sauvant-Moynot, V., & Huet, F. (2016). Safety focused modeling of lithium-ion batteries: A review. Journal of Power Sources, 306, 178-192. Abraham, K. M. (2015). Prospects and limits of energy storage in batteries. Journal of Physical Chemistry Letters, 6(5), 830-844. Alihosseini, A., & Shafaee, M. (2021). Experimental study and numerical simulation of a Lithium-ion battery thermal management system using a heat pipe. Journal of Energy Storage, 39, 102616. Al-Zareer, M., Dincer, I., & Rosen, M. A. (2019). A novel approach for performance improvement of liquid to vapor based battery cooling systems. Energy Conversion and Management, 187, 191-204. Charbuty, B., & Abdulazeez, A. (2021). Classification based on decision tree algorithm for machine learning. Journal of Applied Science and Technology Trends, 2(01), 20-28. Chen, F., Huang, R., Wang, C., Yu, X., Liu, H., Wu, Q., Qian, K., & Bhagat, R. (2020). Air and PCM cooling for battery thermal management considering battery cycle life. Applied Thermal Engineering, 173, 115154. Chen, K. (2013). Heat Generation Measurements of Prismatic Lithium Ion Batteries. Master's Thesis, University of Waterloo, Ontario, Canada. Chen, K., Chen, Y., Li, Z., Yuan, F., & Wang, S. (2018). Design of the cell spacings of battery pack in parallel air-cooled battery thermal management system. International Journal of Heat and Mass Transfer, 127, 393-401. Chen, R. (2022). Battery Pack Design of Cylindrical Lithium-Ion Cells and Modelling of Prismatic Lithium-Ion Battery Based on Characterization Tests. Doctoral thesis, McMaster University, Ontario, Canada. Chen, S. C., Wan, C. C., & Wang, Y. Y. (2005). Thermal analysis of lithium-ion batteries. Journal of Power Sources, 140(1), 111-124. Cho, J., Lim, T., & Kim, B. S. (2009). Measurements and predictions of the air distribution systems in high compute density (Internet) data centers. Energy and Buildings, 41(10), 1107-1115. Dincer, I., & Rosen, M. A. (2021). Thermal Energy Storage: Systems and Applications (3rd ed.) John Wiley & Sons, NJ, USA. Feng, X., Ren, D., He, X., & Ouyang, M. (2020). Mitigating thermal runaway of lithium-ion batteries. Joule, 4(4), 743-770. Guney, M. S., & Tepe, Y. (2017). Classification and assessment of energy storage systems. Renewable and Sustainable Energy Reviews, 75, 1187-1197. Gür, T. M. (2018). Review of electrical energy storage technologies, materials and systems: Challenges and prospects for large-scale grid storage. Energy & Environmental Science, 11(10), 2696-2767. Henke, M., & Hailu, G. (2020). Thermal management of stationary battery systems: A literature review. Energies, 13(6), 4194. Hossain, E., Faruque, H. M. R., Sunny, M. S. H., Mohammad, N., & Nawar, N. (2020). A comprehensive review on energy storage systems: Types, comparison, current scenario, applications, barriers, and potential solutions, policies, and future prospects. Energies, 13(14), 3651 Hosseinirad, E., & Khoshvaght-Aliabadi, M. (2021). Proximity effects of straight and wavy fins and their interruptions on performance of heat sinks utilized in battery thermal management. International Journal of Heat and Mass Transfer, 173, 121259. Institute of Electrical and Electronics Engineers. (2012). IEEE/ASHRAE Guide for the Ventilation and Thermal Management of Batteries for Stationary Applications, IEEE Std Guidel. IEEE, Piscataway, NJ, USA. Jaliliantabar, F., Mamat, R., & Kumarasamy, S. (2022). Prediction of lithium-ion battery temperature in different operating conditions equipped with passive battery thermal management system by artificial neural networks. Materials Today: Proceedings, 48, 1796-1804. Khan, M. R., Swierczynski, M. J., & Kær, S. K. (2017). Towards an ultimate battery thermal management system: A review. Batteries, 3(1), 3010009. Kim, J., Oh, J., & Lee, H. (2019). Review on battery thermal management system for electric vehicles. Applied Thermal Engineering, 149, 192-212. Lan, B., Lin, Y. J., Lai, Y. H., Tang, C. H., & Yang, J. T. (2022). A neural network approach to estimate transient aerodynamic properties of a flapping wing system. Drones, 6(8), 210. Lin, Y., Chen, Y. W., & Yang, J. T. (2023). Optimized thermal management of a battery energy-storage system (BESS) inspired by air-cooling inefficiency factor of data centers. International Journal of Heat and Mass Transfer, 200, 123388. Liu, G., Ouyang, M., Lu, L., Li, J., & Han, X. (2014). Analysis of the heat generation of lithium-ion battery during charging and discharging considering different influencing factors. Journal of Thermal Analysis and Calorimetry, 116(2), 1001-1010. Liu, H., Wei, Z., He, W., & Zhao, J. (2017). Thermal issues about Li-ion batteries and recent progress in battery thermal management systems: A review. Energy Conversion and Management, 150, 304-330. Li, X., He, F., & Ma, L. (2013). Thermal management of cylindrical batteries investigated using wind tunnel testing and computational fluid dynamics simulation. Journal of Power Sources, 238, 395-402. Meng, X. Z., Lu, Z., Jin, L. W., Zhang, L. Y., Hu, W. Y., Wei, L. C., & Chai, J. C. (2015). Experimental and numerical investigation on thermal management of an outdoor battery cabinet. Applied Thermal Engineering, 91, 210-224. Mitali, J., Dhinakaran, S., & Mohamad, A. A. (2022). Energy storage systems: A review. Energy Storage and Saving, 1(3), 166-216. Mohammadian, S. K., He, Y. L., & Zhang, Y. (2015). Internal cooling of a lithium-ion battery using electrolyte as coolant through microchannels embedded inside the electrodes. Journal of Power Sources, 293, 458-466. Myles, A. J., Feudale, R. N., Liu, Y., Woody, N. A., & Brown, S. D. (2004). An introduction to decision tree modeling. Journal of Chemometrics, 18(6), 275-285. Olabi, A. G., Onumaegbu, C., Wilberforce, T., Ramadan, M., Abdelkareem, M. A., & al – Alami, A. H. (2021). Critical review of energy storage systems. Energy, 214, 118987. Patankar, S. V. (2010). Airflow and cooling in a data center. Journal of Heat Transfer, 132(7). Perry, M. L., & Weber, A. Z. (2016). Advanced redox-flow batteries: A perspective. Journal of the Electrochemical Society, 163(1), A5064. Qin, P., Liao, M., Mei, W., Sun, J., & Wang, Q. (2021). The experimental and numerical investigation on a hybrid battery thermal management system based on forced-air convection and internal finned structure. Applied Thermal Engineering, 195, 117212. Rao, Z., Wang, S., Wu, M., Lin, Z., & Li, F. (2013). Experimental investigation on thermal management of electric vehicle battery with heat pipe. Energy Conversion and Management, 65, 92-97. Sarbu, I., & Sebarchievici, C. (2018). A comprehensive review of thermal energy storage. Sustainability, 10(1), 191. Schimpe, M., Naumann, M., Truong, N., Hesse, H. C., Santhanagopalan, S., Saxon, A., & Jossen, A. (2018). Energy efficiency evaluation of a stationary lithium-ion battery container storage system via electro-thermal modeling and detailed component analysis. Applied Energy, 210, 211-229. Shi, H., Xu, W., Zhu, X., Wang, J., Yang, K., Zou, Y., & Chen, Z. (2022). A thermal-optimal design of lithium-ion battery for the container storage system. Energy Science & Engineering, 10(3), 951-961. Skyllas-Kazacos, M., Chakrabarti, M. H., Hajimolana, S. A., Mjalli, F. S., & Saleem, M. (2011). Progress in flow battery research and development. Journal of the Electrochemical Society, 158(8), R55. Sola, J., & Sevilla, J. (1997). Importance of input data normalization for the application of neural networks to complex industrial problems. IEEE Transactions on Nuclear Science, 44(3), 1464-1468. Sun, H., & Dixon, R. (2014). Development of cooling strategy for an air cooled lithium-ion battery pack. Journal of Power Sources, 272, 404-414. Thomas, K. E., & Newman, J. (2003). Thermal modeling of porous insertion electrodes. Journal of the Electrochemical Society, 150(2), 1531194. Vichard, L., Steiner, N. Y., Zerhouni, N., & Hissel, D. (2021). Hybrid fuel cell system degradation modeling methods: A comprehensive review. Journal of Power Sources, 506, 230071. Vulusala G, V. S., & Madichetty, S. (2018). Application of superconducting magnetic energy storage in electrical power and energy systems: A review. International Journal of Energy Research, 42(2), 358-368. Wagner, L. (2007). Overview of Energy Storage Methods, Research Report, MORA Assoc. Ltd., California, USA. Wang, Z., Ma, J., & Zhang, L. (2017). Finite element thermal model and simulation for a cylindrical Li-Ion battery. IEEE Access, 5, 15372-15379. Wan, J., Gui, X., Kasahara, S., Zhang, Y., & Zhang, R. (2018). Air flow measurement and management for improving cooling and energy efficiency in raised-floor data centers: A survey. IEEE Access, 6, 48867-48901. Wei, L., Lu, Z., Cao, F., Zhang, L., Yang, X., Yu, X., & Jin, L. (2020). A comprehensive study on thermal conductivity of the lithium-ion battery. International Journal of Energy Research, 44(12), 9466-9478. Wilke, S., Schweitzer, B., Khateeb, S., & Al-Hallaj, S. (2017). Preventing thermal runaway propagation in lithium ion battery packs using a phase change composite material: An experimental study. Journal of Power Sources, 340, 51-59. Wu, C., Zhu, C., Ge, Y., & Zhao, Y. (2015). A review on fault mechanism and diagnosis approach for Li-ion batteries. Journal of Nanomaterials, 2015, 631263. Wu, W., Wu, W., & Wang, S. (2018). Thermal management optimization of a prismatic battery with shape-stabilized phase change material. International Journal of Heat and Mass Transfer, 121, 967-977. Xia, B., Liu, F., Xu, C., Liu, Y., Lai, Y., Zheng, W., & Wang, W. (2020). Experimental and simulation modal analysis of a prismatic battery module. Energies, 13(8), 2046. Xu, S., Wan, T., Zha, F., He, Z., Huang, H., & Zhou, T. (2022). Numerical simulation and optimal design of air cooling heat dissipation of lithium-ion battery energy storage cabin. Journal of Physics: Conference Series, 2166(1), 12023. Xu, X. M., & He, R. (2013). Research on the heat dissipation performance of battery pack based on forced air cooling. Journal of Power Sources, 240, 33-41. Yang, N., Zhang, X., Li, G., & Hua, D. (2015). Assessment of the forced air-cooling performance for cylindrical lithium-ion battery packs: A comparative analysis between aligned and staggered cell arrangements. Applied Thermal Engineering, 80, 55-65. Yin, L., Björneklett, A., Söderlund, E., & Brandell, D. (2021). Analyzing and mitigating battery ageing by self-heating through a coupled thermal-electrochemical model of cylindrical Li-ion cells. Journal of Energy Storage, 39, 102648. Zhang, J., Wu, B., Li, Z., & Huang, J. (2014). Simultaneous estimation of thermal parameters for large-format laminated lithium-ion batteries. Journal of Power Sources, 259, 106-116. Zhang, J., Wu, X., Chen, K., Zhou, D., & Song, M. (2021). Experimental and numerical studies on an efficient transient heat transfer model for air-cooled battery thermal management systems. Journal of Power Sources, 490, 229539. Zhang, X., Li, Z., Luo, L., Fan, Y., & Du, Z. (2022). A review on thermal management of lithium-ion batteries for electric vehicles. Energy, 238, 121652. Zhu, S., Zhao, N., & Sha, J. (2019). Predicting battery life with early cyclic data by machine learning. Energy Storage, 1(6), e98. 陳怡妏. (2022). 改善電池儲能系統溫度分布之進風口控制策略. 國立台灣大學機械工程研究所. 廣州智光電器技術有限公司. 集裝箱式儲能系統. 中國專利：CN202021017733.3[U], 2020.	-
dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/90647	-
dc.description.abstract	本研究探討電池模組的非等向熱傳導性質對充放電過程中電池溫度分布之影響。設定體發熱模擬方法，將電池模組視為均勻的非等向性材料，計算貨櫃型電池儲能系統的電池溫度分布。提出平行吹拂式冷卻系統之創新設計，強化電池容易散熱表面的散熱強度，使散熱效果評斷參數大幅增加76.8 %。利用機器學習演算法，建立冷卻氣體控制策略及電池溫度預測模型，降低電池最高溫度及最大溫差；且電池溫度預測誤差僅0.16 %，顯著提升儲能貨櫃熱管理系統的安全性能及商業價值。商用電池儲能貨櫃所使用的電池模組多為大型層壓式鋰離子電池，內部熱傳性質各方向相異，需合併分析各層材料的熱傳現象來模擬溫度變化過程。若不考慮電池內部熱傳，熱能無法由內部傳遞至外界，表面溫度受冷卻氣體流場主導，產生顯著溫差。本文提出體發熱模擬方法，將電池視為均勻的非等向熱傳材料。結果顯示，電池溫度受內部熱傳性質影響顯著，高溫區主要出現在熱傳導係數高方向的表面。若增加流經此方向表面的冷卻氣體，可有效提升散熱效果。第二部份考量具非等向熱傳性質的電池模組，設計平行吹拂式冷卻系統，調整內裝配置，使冷卻氣體可均勻流經電池熱傳導係數高方向的表面，並讓迴流氣體加強主要熱點的散熱。結果顯示，平行吹拂式冷卻系統在冷卻氣體流量為6 m3/s、溫度為25 ℃的情況下，與FS-CR冷卻系統相比，最高溫度和最大溫差分別下降11.3 %和28.7 %，評斷參數Ind提升76.8 %，儲能貨櫃的散熱效果大幅提升。第三部份運用機器學習演算法，最佳化電池儲能系統熱管理策略。使用決策樹演算法，分析冷卻氣體條件對電池溫度分布之影響。結果得知，降低冷卻氣體溫度和提升流量，可分別有效改善電池模組的最高溫度和最大溫差。也建立人工神經網絡模型，預測電池在不同冷卻氣體條件下的溫度。經驗證誤差僅0.16 %，預測時間僅14秒，節省99.9 %分析時間，大幅提升電池儲能系統熱管理策略的商業價值。	zh_TW
dc.description.abstract	In this study, we investigate the influence of the anisotropic thermal properties on the temperature distribution within container-type battery energy storage systems (BESS). The volumetric heating method is employed for simulating the heating process, under the assumption that the battery modules are consisting of single materials with anisotropic thermal parameters. Based on the findings, an innovative design of the parallel-cooling system is introduced for the battery thermal management system (BTMS). The system enhances the cooling airflow around the surfaces in the directions with higher thermal conductivity. With the implement of the parallel-cooling system, the performance index of the thermal management system can be significantly increased by 76.8 %. In addition, with the utilization of two machine learning algorithms, decision tree and artificial neural network, we proposed the thermal management strategies and the temperature predictive model for the BESS. The predictive model achieves an impressive error of only 0.16 %, significantly improving the safety and the commercial profitability of the BTMS. Commercial BESS predominantly use large-format laminated lithium-ion batteries with anisotropic thermal conductivities. The internal thermal properties of these batteries are various with the directions. In this study, the volumetric heating method is applied, simulating the heat transfer process within the BESS by treating the battery as a homogenous material with anisotropic thermal conductivities. The results reveal that the temperature distribution is mainly influenced by the internal anisotropic thermal properties, while the hot spots primarily occurs on the surfaces with high thermal conductivity. By enhancing the cooling airflow around these specific surfaces, the cooling performance of the BTMS can be effectively improved. Considering the temperature distribution of the batteries with anisotropic thermal properties, the parallel-cooling system is proposed. In the system, batteries are arranged in series and cooling air flows parallelly to them. This configuration intensifies cooling air flow through the surfaces with high thermal conductivities. In addition, the recirculating cooling air enhances the heat dissipation of the hotspots in the BESS. With the parallel cooling system, the highest temperature and the temperature difference across the entire BESS are reduced by 11.3 % and 28.7 %, respectively. The performance index of the BTMS is effectively increased by 76.8 %, resulting in a significant improvement in the safety of the BESS. Two machine learning algorithms are implemented to establish the thermal management of BESS. The decision tree algorithm clarifies the relationship between the cooling air conditions and the battery temperature distributions. Based on the results, we introduced the cooling strategy that the highest temperature and the maximum temperature difference of the batteries can be effectively decreased by reducing the temperature and increasing the flow rate of the cooling air, respectively. Furthermore, the artificial neural network is utilized to forecast battery temperatures under various cooling air conditions. The model demonstrates an impressive error of only 0.16 %, accurately predicting the battery temperatures. Moreover, regardless of the amount of data, the prediction time takes just 14 seconds, significantly reducing the analysis time by 99.9 %. These advancements remarkably enhance the commercial value of the BTMS.	en
dc.description.provenance	Submitted by admin ntu (admin@lib.ntu.edu.tw) on 2023-10-03T17:00:39Z No. of bitstreams: 0	en
dc.description.provenance	Made available in DSpace on 2023-10-03T17:00:39Z (GMT). No. of bitstreams: 0	en
dc.description.tableofcontents	論文口試委員審定書 i 致謝 ii 摘要 iii Abstract iv 目錄 vi 表目錄 ix 圖目錄 x 符號表 xv 第一章前言 1 1-1. 研究背景 1 1-2. 研究動機 1 第二章文獻回顧 3 2-1. 儲能系統簡介 4 2-1.1. 各式儲能系統 4 2-1.2. 電化學儲能 6 2-2. 鋰離子電池發熱及溫度議題 9 2-2.1. 鋰離子電池發熱現象 10 2-2.2. 電池安全工作溫度 11 2-2.3. 熱失控 13 2-3. 電池儲能系統熱管理方法 14 2-3.1. 電池組散熱 14 2-3.2. 電池儲能貨櫃散熱 18 2-3.3. 資料中心散熱 23 2-3.4. 熱管理系統散熱效果評斷 26 2-3.5. 機器學習演算法 27 2-4. 計算流體力學 29 2-4.1. 紊流模型 30 第三章研究方法 33 3-1. 物理模型 33 3-1.1. 電池儲能貨櫃及內裝配置 33 3-1.2. 電池工作狀態及熱傳性質 37 3-2. 數值模擬與電池發熱模型 39 3-2.1. 數值計算求解器 39 3-2.2. 統御方程式 39 3-2.3. 紊流模型 40 3-2.4. 電池發熱量模型 40 3-3. 邊界條件及網格設定與驗證 43 3-3.1. 邊界條件設定 43 3-3.2. 網格設定 43 3-3.3. 獨立性驗證 45 3-4. 機器學習演算法 48 3-4.1. 決策樹演算法 48 3-4.2. 人工神經網絡演算法 51 3-5. 冷卻系統效果評斷 53 3-5.1. 冷卻系統功耗計算 54 3-5.2. 散熱效果評斷參數 55 第四章結果與討論 56 4-1. 電池發熱模型 56 4-1.1. 體發熱模擬方法設定 57 4-1.2. 體發熱模擬方法驗證 62 4-1.3. 電池非等向熱傳性質 63 4-2. 冷卻系統配置 67 4-2.1. 平行吹拂式冷卻系統 67 4-2.2. 電池排列間距對散熱效果之影響 70 4-2.3. 開放式機櫃對散熱效果之影響 72 4-3. 電池儲能系統熱管理策略 78 4-3.1. 決策樹分析冷卻氣體影響力 78 4-3.2. 人工神經網絡建立溫度預測模型 82 第五章結論與未來展望 88 5-1. 結論 88 5-2. 未來展望 89 5-3. 甘特圖 90 參考文獻 91	-
dc.language.iso	zh_TW	-
dc.subject	熱管理策略	zh_TW
dc.subject	貨櫃型電池儲能系統	zh_TW
dc.subject	非等向熱傳性質	zh_TW
dc.subject	平行吹拂式冷卻系統	zh_TW
dc.subject	機器學習演算法	zh_TW
dc.subject	parallelly cooling system	en
dc.subject	anisotropic thermal conductivity	en
dc.subject	container-type battery energy storage system	en
dc.subject	machine learning algorithm	en
dc.subject	thermal management	en
dc.title	應用機器學習演算法設計具非等向熱傳性質電池儲能系統之熱管理策略	zh_TW
dc.title	Thermal Management via Machine Learning Algorithm for Battery Energy-storage System (BESS) with Anisotropic Thermal Conductivity	en
dc.type	Thesis	-
dc.date.schoolyear	111-2	-
dc.description.degree	碩士	-
dc.contributor.oralexamcommittee	陳志臣;王安邦;陳志鴻	zh_TW
dc.contributor.oralexamcommittee	Jyh-Chen Chen;An-Bang Wang;Chih-Hung Chen	en
dc.subject.keyword	貨櫃型電池儲能系統,非等向熱傳性質,平行吹拂式冷卻系統,熱管理策略,機器學習演算法,	zh_TW
dc.subject.keyword	container-type battery energy storage system,anisotropic thermal conductivity,parallelly cooling system,thermal management,machine learning algorithm,	en
dc.relation.page	97	-
dc.identifier.doi	10.6342/NTU202301759	-
dc.rights.note	同意授權(全球公開)	-
dc.date.accepted	2023-07-27	-
dc.contributor.author-college	工學院	-
dc.contributor.author-dept	機械工程學系	-
dc.date.embargo-lift	2028-07-25	-
顯示於系所單位：	機械工程學系

文件中的檔案：

檔案	大小	格式
ntu-111-2.pdf 此日期後於網路公開 2028-07-25	14.87 MB	Adobe PDF

顯示文件簡單紀錄

系統中的文件，除了特別指名其著作權條款之外，均受到著作權保護，並且保留所有的權利。