研究生: |
王祿融 Wang, Lu-Jung |
---|---|
論文名稱: |
創新混合燃料電池機車之系統建模與能量管理 A Study of System Modeling and Energy Management on Novel Fuel Cell Hybrid Electric Scooter |
指導教授: |
呂有豐
Lue, Yeou-Feng |
學位類別: |
碩士 Master |
系所名稱: |
工業教育學系 Department of Industrial Education |
論文出版年: | 2016 |
畢業學年度: | 104 |
語文別: | 中文 |
論文頁數: | 80 |
中文關鍵詞: | 燃料電池 、系統建模 、模糊控制 、能量管理 、電動車 |
英文關鍵詞: | Fuel cell, System modeling, fuzzy logic control, energy management, electric vehicle |
DOI URL: | https://doi.org/10.6345/NTNU202204346 |
論文種類: | 學術論文 |
相關次數: | 點閱:121 下載:10 |
分享至: |
查詢本校圖書館目錄 查詢臺灣博碩士論文知識加值系統 勘誤回報 |
本論文為達成能量管理,尤針對非線性系統如質子交換膜燃料電池、儲氫罐、鋰電池等元件加以調度運用,特以本研究者自行整合之質子交換膜燃料電池混合動力電動機車進行實測,以取得各項次系統元件操作參數,並以 MATLAB/Simulink 模擬軟體為基礎,建構四種燃料電池混合動力車系統動態模型(被動式燃料電池搭配單電池模式、被動式燃料電池搭配雙電池模式、主動式燃料電池搭配單電池模式與主動式燃料電池搭配雙電池模式)。並配合不同之控制,分別以各元件及車輛性能參數,建構各種組合之次系統模型。然後運用車輛動力學 (Vehicle Dynamics) 原理,將電源管理控制系統、馬達、1 kW之PEMFC燃料電池與960 Wh之鋰離子電池之電控系統加以整合,驅動一電動機車。
在電控系統方面,透過取得之參數,進而導入3參數輸入(系統需求功率、殘氫量、鋰電池SOC)與1輸出(燃料電池供應系統之總功率比)之27個規則的模糊邏輯控制(Fuzzy Logic Control)。因此能做平滑能量分配。在本論文研究中,係以探討最佳能源運用為目標,對四種設計之能量運用模式,透過行駛ECE-40與FTP-72行車形態與駕駛模式,比較各種條件的輸出性能以及關鍵變量、續駛距離及能耗情形。結果顯示本研究在相同初始能量下,應用模糊邏輯控制雙電池模式輸出,可達最佳之能量管理。運轉時每公里平均氫氣消耗可由單電池搭配燃料電池之0.428g/km降至0.390g/km,行駛距離可增加9.82%。
This study presents a novel energy management, especially to deal with non-linear subsystems such as proton exchange membrane fuel cells (PEMFCs), hydrogen storage tanks, lithium batteries and other components. A real fuel cell/battery hybrid electric motorcycle with preceding components was tested in this study. The retrieved parameters from the subsystems of the scooter were used to build four kinds of PEMFC hybrid vehicle system dynamic models on the Matlab/Simulink environment. They include: passive fuel cells with a single battery, passive fuel cells with dual batteries, aggressive fuel cells with a single battery, and aggressive fuel cells with dual batteries. With different control strategies and vehicle performance parameters for different structures, four modes are constructed by a different combination of subsystems models. The four kinds of established electric scooter models were developed based on the vehicle dynamics theory by combining an in-wheel motor, a 1kW PEMFC and a 960Wh lithium battery. Four types of energy management control systems were thus designed in this study.
For the electronically-controlled systems, 27 fuzzy logic rules were established which included 3 input parameters (system required power, the amount of residual hydrogen gas, and the state of charge of the primary battery, SoC) and an output parameter (the power ratio of the fuel cell supply system). Therefore, the smooth energy distribution was achieved in this study. In this paper, the goal is to discuss the best energy utilization. With the designs of four kinds of energy modes, through two driving cycle (ECE-40 and FTP-72) and driving mode, the output performance under different conditions, key variables, extended range and energy consumption were compared. The results show that under the same initial energy condition, the best energy management can be reached by using fuzzy logic rules to control the dual battery type. The hydrogen consumption can be decreased from 0.428 g/km to 0.390 g/km, and the driving range can be improved by 9.82 % compared to the baseline case.
[1] Wakefield, Ernest Henry. History of the Electric Automobile-Hybrid Electric Vehicles., Vol. 187. USA, 1998.
[2] 黃鎮江,“燃料電池” ,滄海書局,台中市,2008。
[3] Mekhilef, S., R. Saidur, and A. Safari. "Comparative study of different fuel cell technologies," Renewable and Sustainable Energy Reviews., Vol.16, no.1, pp. 981-989, 2012.
[4] J.K. Kuo, J.J. Hwang, and C.H. Lin. "Performance analysis of a stationary fuel cell thermoelectric cogeneration system." Fuel Cells., Vol.12, no.6, pp.1104-1114, 2012.
[5] Marcinkoski, Jason, John P. Kopasz, and Thomas G. Benjamin. "Progress in the US DOE fuel cell subprogram efforts in polymer electrolyte fuel cells." International Journal of Hydrogen Energy., Vol.33, no.14, pp.3894-3902, 2008.
[6] Wipke, Keith, et al. Controlled Hydrogen Fleet Infrastructure Demonstration and Validation Project. National Renewable Energy Laboratory Report NREL/TR-560–45451, slide CDP 38, 2009.
[7] Wipke, Keith, et al. "Entering a new stage of learning from the US fuel cell electric vehicle demonstration project." 25th World battery, hybrid, and fuel cell electric vehicle symposium & Exhibition, Shenzhen, China, Nov. 2010.
[8] J.J. Hwang, et al. "Development of fuel-cell-powered electric bicycle." Journal of Power Sources., Vol.133, no.2, pp. 223-228, 2004.
[9] Tolj, Ivan, et al. "Fuel cell-battery hybrid powered light electric vehicle (golf cart): influence of fuel cell on the driving performance." international journal of hydrogen energy., Vol.38, no.25, pp.10630-10639, 2013.
[10] F.C. Wang and C.H. Peng. "The development of an exchangeable PEMFC power module for electric vehicles." International journal of hydrogen energy., Vol.39, no.8, pp.3855-3867, 2014.
[11] Barelli, Linda, Gianni Bidini, and Andrea Ottaviano. "Optimization of a PEMFC/battery pack power system for a bus application." Applied energy., Vol.97, pp.777-784, 2012.
[12] Li, Mingqiang, and Keith Scott. "A polymer electrolyte membrane for high temperature fuel cells to fit vehicle applications." Electrochimica Acta., Vol.55, no.6 , pp.2123-2128, 2010.
[13] V. Paladini, T. Donateo, A. de Risi, and D. Laforgia, "Control Strategy Optimization of a Fuel-Cell Electric Vehicle," Journal of Fuel Cell Science and Technology., vol. 5, pp. 21004, 2008.
[14] Wang, Xin, et al. "Durability investigation of carbon nanotube as catalyst support for proton exchange membrane fuel cell." Journal of Power Sources., vol.158, no.1, pp. 154-159, 2006.
[15] Tremblay, Olivier, Louis-A. Dessaint, and Abdel-Illah Dekkiche. "A generic battery model for the dynamic simulation of hybrid electric vehicles." 2007 IEEE Vehicle Power and Propulsion Conference. IEEE, 2007.
[16] Simmons, Kyle, Yann Guezennec, and Simona Onori. "Modeling and energy management control design for a fuel cell hybrid passenger bus." Journal of Power Sources., vol. 246, pp. 736-746, 2014.
[17] Candusso, Denis, et al. "Fuel cell operation under degraded working modes and study of diode by-pass circuit dedicated to multi-stack association." Energy Conversion and Management., vol.49, no.4, pp. 880-895, 2008.
[18] Pan, Ching-Tsai, and Ching-Ming Lai. "A high-efficiency high step-up converter with low switch voltage stress for fuel-cell system applications." IEEE Transactions on Industrial Electronics., vol.57, no.6, pp.1998-2006, 2010.
[19] Hung, Yi-Hsuan, Yu-Ming Tung, and Hong-Wei Li. "A real-time model of an automotive air propulsion system." Applied Energy., vol.129, pp.287-298, 2014.
[20] Schupbach, R. M., and J. C. Balda. "A versatile laboratory test bench for developing powertrains of electric vehicles."in Proc. IEEE 56th. ehicular Technology Conference., Vancouver, Canada, Sep. 2002, pp.1667-1670.
[21] Hwang, Jenn-Jiang, Yu-Jie Chen, and Jenn-Kun Kuo. "The study on the power management system in a fuel cell hybrid vehicle." International journal of hydrogen energy., vol.37, no.5, pp. 4476-4489, 2012.
[22] Li, Q., Chen, W., Li, Y., Liu, S., & Huang, J. “Energy management strategy for fuel cell/battery/ultracapacitor hybrid vehicle based on fuzzy logic.” International Journal of Electrical Power & Energy Systems., vol.43, no.1, pp.514-525, 2012.
[23] Zhang, C., Liu, Z., Zhou, W., Chan, S. H., & Wang, Y. (2015). “Dynamic performance of a high-temperature PEM fuel cell–An experimental study.” Energy., vol.90, pp.1949-1955, 2015.
[24] Zhang, Caizhi, et al. "Dynamic performance of a high-temperature PEM (proton exchange membrane) fuel cell–Modelling and fuzzy control of purging process."Energy., vol.95, pp. 425-432, 2016.
[25] Kisacikoglu, M. C., M. Uzunoglu, and M. S. Alam. "Load sharing using fuzzy logic control in a fuel cell/ultracapacitor hybrid vehicle." International journal of hydrogen energy., vol.34, no.3, pp.1497-1507, 2009.
[26] Sulaiman, N., et al. "A review on energy management system for fuel cell hybrid electric vehicle: Issues and challenges." Renewable and Sustainable Energy Reviews., vol.52, pp.802-814, 2015.
[27] Nasrallah, S. Ben, and A. Jemni. "Heat and mass transfer models in metal-hydrogen reactor." International Journal of Hydrogen Energy., vol.22, no.1, pp. 67-76, 1997.