摘要
ABSTRACT
誌謝
目錄
表目錄
圖目錄
第一章 緒論
1-1 研究背景
1-2 研究動機與目的
1-3 研究架構
第二章 文獻回顧
2-1 全釩液流電池介紹
2-2 電池流道框板設計
2-3 計算流體力學介紹
2-4 電池黏著接合研究
第三章 實驗流程與方法
3-1 流場模擬分析
3-2 黏著接合方法
3-3 液流電池測試方式
3-4 實驗儀器設備
第四章 結果與討論
4-1 電極幾何模型對電解液分布影響
4-1-1 不同面積大小
4-1-2 不同多邊形幾何形狀
4-1-3 不同斜率流道角度
4-1-4 電極幾何模型設計
4-2 導電膠塗佈方式對界面電阻影響
4-2-1 界面電阻量測及結構分析
4-2-2 導電塗層於新型單電池之性能比較
4-2-3 導電塗層於新型電池系統之性能測試
4-3 新型設計電池與傳統設計電池性能比較
4-3-1 單電池性能比較
4-3-2 兩串聯電池性能比較
第五章 結論與未來展望
參考文獻

1.Bouckaert, S., et al., Net zero by 2050: A roadmap for the global energy sector. 2021.
2.Administration, U.E.I., International Energy Outlook 2019 with projections to 2050. 2019, US Energy Information Administration Washington, DC, USA.
3.Alhamali, A., et al. Review of energy storage systems in electric grid and their potential in distribution networks. in 2016 Eighteenth International Middle East Power Systems Conference (MEPCON). 2016. IEEE.
4.Hernández, J., I. Gyuk, and C. Christensen. DOE global energy storage database—A platform for large scale data analytics and system performance metrics. in 2016 IEEE International Conference on Power System Technology (POWERCON). 2016. IEEE.
5.Thaller, L.H., Electrically rechargeable redox flow cell. 1976, Google Patents.
6.Chalamala, B.R., et al., Redox flow batteries: an engineering perspective. Proceedings of the IEEE, 2014. 102(6): p. 976-999.
7.Parasuraman, A., et al., Review of material research and development for vanadium redox flow battery applications. Electrochimica Acta, 2013. 101: p. 27-40.
8.Doetsch, C. and J. Burfeind, Vanadium redox flow batteries, in Storing energy. 2022, Elsevier. p. 363-381.
9.Kim, B.-R., et al., A study on flow characteristics and flow uniformity for the efficient design of a flow frame in a redox flow battery. Applied Sciences, 2020. 10(3): p. 929.
10.Park, J.-Y., D.-Y. Sohn, and Y.-H. Choi, A numerical study on the flow characteristics and flow uniformity of vanadium redox flow battery flow frame. Applied Sciences, 2020. 10(23): p. 8427.
11.Jung, S., et al., Computational study of effects of contact resistance on a large‐scale vanadium redox flow battery stack. International Journal of Energy Research, 2019. 43(6): p. 2343-2360.
12.Skyllas-Kazacos, M. and J. McCann, Vanadium redox flow batteries (VRBs) for medium-and large-scale energy storage, in Advances in batteries for medium and large-scale energy storage. 2015, Elsevier. p. 329-386.
13.Wang, W., et al., Electrochemical cells for medium-and large-scale energy storage: fundamentals, in Advances in batteries for medium and large-scale energy storage. 2015, Elsevier. p. 3-28.
14.CANZI, P., Analysis of flow field design in vanadium redox flow batteries through the development and validation of CFD codes. 2017.
15.Vinco, J.H., et al., Unfolding the Vanadium Redox Flow Batteries: An indeep perspective on its components and current operation challenges. Journal of Energy Storage, 2021. 43: p. 103180.
16.Yang, Z., et al., Electrochemical energy storage for green grid. Chemical reviews, 2011. 111(5): p. 3577-3613.
17.Ertugrul, T.Y., et al., In-situ current distribution and mass transport analysis via strip cell architecture for a vanadium redox flow battery. Journal of Power Sources, 2019. 437: p. 226920.
18.Vafiadis, H. and M. Skyllas-Kazacos, Evaluation of membranes for the novel vanadium bromine redox flow cell. Journal of Membrane Science, 2006. 279(1-2): p. 394-402.
19.Duan, Z., et al., Review of bipolar plate in redox flow batteries: Materials, structures, and manufacturing. Electrochemical Energy Reviews, 2021. 4(4): p. 718-756.
20.Hickmann, T., et al., Key Components in the Redox-Flow Battery: Bipolar Plates and Gaskets–Different Materials and Processing Methods for Their Usage, in Energy Storage Battery Systems-Fundamentals and Applications. 2021, IntechOpen.
21.Ke, X., et al., Rechargeable redox flow batteries: flow fields, stacks and design considerations. Chemical Society Reviews, 2018. 47(23): p. 8721-8743.
22.Newman, J. and W. Tiedemann, Porous‐electrode theory with battery applications. AIChE Journal, 1975. 21(1): p. 25-41.
23.Li, X., et al., Ion exchange membranes for vanadium redox flow battery (VRB) applications. Energy & Environmental Science, 2011. 4(4): p. 1147-1160.
24.Huang, Z., et al., Vanadium redox flow batteries: Flow field design and flow rate optimization. Journal of Energy Storage, 2022. 45: p. 103526.
25.Park, D.-J., et al., Performance of the all-vanadium redox flow battery stack. Journal of Industrial and Engineering Chemistry, 2017. 45: p. 387-390.
26.Kuwabara, M., et al., Redox flow battery frame body, redox flow battery, and cell stack. 2019.
27.Kanno, T., T. Yamana, and K. Motoi, Frame body, cell frame for redox flow battery, and redox flow battery. 2018.
28.Coad, N., Internal header flow divider for uniform electrolyte distribution. 2017.
29.S.Q. Zhuang., et al., Flow frame of flow battery which is achievable for stabilizing the flow field distribution and the uniformity of the flow rate of the electrolyte. 2022.
30.Chaurasia, A.S., Computational Fluid Dynamics and Comsol Multiphysics: A Step-by-Step Approach for Chemical Engineers. 2021: CRC Press.
31.Zimmerman, W.B., Multiphysics modeling with finite element methods. Vol. 18. 2006: World Scientific Publishing Company.
32.Cervantes-Alcalá, R. and M. Miranda-Hernández, Flow distribution and mass transport analysis in cell geometries for redox flow batteries through computational fluid dynamics. Journal of applied electrochemistry, 2018. 48: p. 1243-1254.
33.Martinsen, K., S. Hu, and B. Carlson, Joining of dissimilar materials. Cirp Annals, 2015. 64(2): p. 679-699.
34.Tempelman, E., H. Shercliff, and B.N. van Eyben, Chapter 12-Joining and Assembly. Manufacturing and Design Journal, 2014: p. 201-226.
35.Ebnesajjad, S., Introduction and adhesion theories, in Handbook of Adhesives and Surface Preparation. 2011, Elsevier. p. 3-13.
36.Gonçalves, F.A., et al., Influence of fillers on epoxy resins properties: A review. Journal of Materials Science, 2022. 57(32): p. 15183-15212.
37.Qian, P., et al., A novel electrode-bipolar plate assembly for vanadium redox flow battery applications. Journal of Power Sources, 2008. 175(1): p. 613-620.
38.Kim, M.-Y., et al., Energy Efficiency Improvement of Vanadium Redox Flow Battery by Integrating Electrode and Bipolar Plate. Journal of Electrochemical Science and Technology, 2021. 12(3): p. 330-338.
39.You, D., H. Zhang, and J. Chen, A simple model for the vanadium redox battery. Electrochimica Acta, 2009. 54(27): p. 6827-6836.
40.Mengyao, Q., et al., Numerical simulation of a novel radial all-vanadium flow battery cell. Energy Storage Science and Technology, 2022. 11(10): p. 3209.
41.You, D., et al., Simulation study on flow field optimization of flow battery based on flow frame design. CIESC Journal, 2019, 70(11): p. 4437-4448.