(3.230.173.249) 您好!臺灣時間:2021/04/18 07:20
字體大小: 字級放大   字級縮小   預設字形  
回查詢結果

詳目顯示:::

我願授權國圖
: 
twitterline
研究生:辜昱崧
研究生(外文):Yu-Song Gu
論文名稱:具電壓驟降補償之市電併聯型太陽能單相準Z源換流器的實現
論文名稱(外文):Implementation of a Single-Phase Quasi Z-Source Inverter with Voltage Dip Mitigation for a Grid Connected PV System
指導教授:陳明堂陳明堂引用關係
指導教授(外文):Ming-Tang Chen
口試委員:陳建富蕭瑛星
口試委員(外文):Jiann-Fuh ChenTing-Shing Shiao
口試日期:2013-06-13
學位類別:碩士
校院名稱:國立高雄應用科技大學
系所名稱:電機工程系博碩士班
學門:工程學門
學類:電資工程學類
論文種類:學術論文
論文出版年:2013
畢業學年度:101
語文別:中文
論文頁數:70
中文關鍵詞:太陽光電系統準Z源換流器功率控制電壓驟降補償
外文關鍵詞:PV SystemQuasi Z-Source InverterPower ControlVoltage Dip Mitigation
相關次數:
  • 被引用被引用:1
  • 點閱點閱:270
  • 評分評分:系統版面圖檔系統版面圖檔系統版面圖檔系統版面圖檔系統版面圖檔
  • 下載下載:10
  • 收藏至我的研究室書目清單書目收藏:0
本文以單相準Z 源換流器為基礎,建構市電併聯型太陽能系統,
且透過數位訊號處理器(DSP)實現換流器之控制,將太陽能電池產生
之電能饋入市電。首先系統利用零點偵測電路及鎖相迴路之控制,使
系統與市電同相位,以便進行市電併聯;同時透過貫通模式與非貫通
模式,有效控制直流鏈與輸出電壓。此外,藉由調整系統輸出電壓之
振幅與相角,實現實功與虛功之控制;當市電電壓發生驟降時,藉由
虛功控制可達到驟降補償之功能,以維持負載上之電壓穩定。在系統
發展過程中,先透過Matlab/Simulink 建立模型,藉由模擬評估確定
其可行性。並在完成原型製作後,進行實作測試,結果證實系統可順
利運作。與市電成功並聯後,可達到實功及虛功控制目標,且可補償
市電電壓之驟降。
Based on single-phase Quasi Z-source inverter, a grid-connected PV
system was built; besides, a Digital Signal Processor (DSP) is used to
implement the power control and improve the voltage quality problem
caused by voltage dip. The zero-point detector circuit by PLL control is
used to facilitate the parallel connection of the inverter to grid; in the
meantime, the DC bus and the output voltage can be effectively regulated
by shoot-through and non-shoot-through modes. In addition, the power
angle and the voltage amplitude are used to regulate active and reactive
power injected to the utility. To verify the feasibility of the system, the
system model was built by MATLAB/Simulink, and the operation of the
system was simulated. Finally, a prototype of Quasi Z-source inverter was
tested, and the results illustrate that the parallel connection of inverter to
grid and the power control of the system can be satisfied.
具電壓驟降補償之市電併聯型太陽能單相
準Z 源換流器的實現
Implementation of a Single-Phase Quasi Z-Source
Inverter with Voltage Dip Mitigation for a Grid
Connected PV System
目錄
中文摘要
英文摘要
致謝
目錄
表目錄
圖目錄
第一章 緒論
1.1 研究背景與動機
1.2 國內外研究概況
1.3 研究方法與貢獻
1.4 論文內容概要
第二章 太陽光電系統
2.1 太陽光電系統簡介
2.2 .太陽能電池
2.3 最大功率點追蹤演算法
2.4 遮蔽效應
第三章 換流器
3.1 換流器簡介
3.2 Z 源換流器
3.3 準Z 源換流器
第四章 系統設計
4.1 系統硬體架構
4.1.1 主電路設計
4.1.2 輸出濾波器設計
4.1.3 周邊電路設計
4.2 數位控制器
4.3 系統控制架構
4.3.1 換流器之直流側控制
4.3.2 換流器之交流側控制
4.4 驟降補償控制
4.4.1 功率控制設計
4.4.2 驟降補償原理
第五章 模擬與實驗結果
5.1 系統模擬結果
5.2 系統實驗結果
5.3 實驗分析與檢討
第六章 結論與未來研究方向
6.1 結論
6.2 未來研究建議
參考文獻
參考文獻
[1]鄭婉真,“太陽能產業潛力產品Micro inverter的發展機會與挑戰” 電力電子雙月刊,第9期,第6卷,2011年11月,pp.122-129。
[2]黃孟嬌,“綠建築產業全球市場回顧與展望” 電力電子雙月刊,第10期,第4卷,2012 年 7 月,pp.89-96。
[3]康志堅,“2012年全球風力發電產業回顧與展望” 電力電子雙月刊,第10期,第3卷,2012 年 3 月,pp.100-105。
[4]傅家麟,鄭儀誠,徐振凱,陳志堅,“太陽能出力預測技術現況分析,” 電力電子雙月刊,第7期,第4卷,2009 年 7 月,pp.46-53。
[5]楊翔如,“2011年上半年台灣太陽光電產業回顧與展望” 電力電子雙月刊,第9期,第5卷,2011 年 9 月,pp.88-92。
[6]王孟傑,“由動盪中求回穩的2012年太陽光電產業全球市場回顧與展望,” 電力電子雙月刊,第10期,第5卷,2012 年 9 月,pp.107-113。
[7]張宏展,林佑星,黃勁元,黃李堅,陳政傳,“家用型太陽能發電系統之研製,” 電力電子雙月刊,第7期,第6卷,2009 年 11 月,pp.91-99。
[8]S. J. Liu, Q. F. Jing, and H. Z. Yang, “Study of Control Strategy on Small Power Photovoltaic Grid-Connected Generation System,” Proceedings of 2010 International Conference on Intelligent Computing and Cognitive Informatics, June 2010, pp.271-274.
[9]H. Taheri, Z. Salam, K. Ishaque, and Syafaruddin, “A Novel Maximum Power Point Tracking Control of Photovoltaic System Under Partial and Rapidly Fluctuating Shadow Conditions Using Differential Evolution,” Proceedings of 2010 IEEE Symposium on Industrial Electronics & Applications , Oct. 2010, pp.82-87.
[10]S. Jiang, J.G. Cintron-Rivera, and F. Z. Peng, “Modeling and Control of Quasi-Z-Source Inverter for Distributed Generation Applications,” IEEE Transactions on Industrial Electronics , Vol.60, Issue 4,Apr. 2013, pp.1532-1541.
[11]A. Joel and F. Z. Peng, “Four Quasi-Z-Source Inverters,” Proceedings of Power Electronics Specialists Conference, Jun. 2008, pp.2743-2749.
[12]F. Z. Peng, J.G. Cintron-Rivera, and S. Jiang, “Controller design for quasi-Z-source inverter in photovoltaic systems,” Proceedings of Energy Conversion Congress and Exposition, Sep. 2010, pp.3187-3194.
[13]T.W. Chum, H.H Lee, H.G. Kim, and E.C.Nho, “Power control for a PV generation system using a single-phase grid-connected quasi Z-source inverter,” Proceedings of Power Electronics and ECCE Asia, Jun. 2011, pp.889-893.
[14]K. Beer and B. Piepenbreier, “Properties and advantages of the quasi-Z-source inverter for DC-AC conversion for electric vehicle applications,” Proceedings of Emobility - Electrical Power Train, Nov. 2010, pp.1-6.
[15]R.A. Mastromauro, M. Liserre, T. Kerekes, and A. Dell'Aquila, “A Single-Phase Voltage-Controlled Grid-Connected Photovoltaic System with Power Quality Conditioner Functionality,” IEEE Transactions on Industrial Electronics, Nov. 2009, Vol. 56, Issue 11, pp.4436-4444.
[16]R.I. Bojoi, L.R. Limongi, D. Roiu, and A. Tenconi, “Enhanced Power Quality Control Strategy for Single-Phase Inverters in Distributed Generation Systems,” IEEE Transactions on Power Electronics, March 2011, Vol. 26, Issue 3, pp.798-806.
[17]Y. Xu, F. X. Li, D.T. Rizy, and J.D. Kueck, “Active Power and Nonactive Power Control of Distributed Energy Resources,” Proceedings of the 40th North American Power Symposium, Sept. 2008, pp.1-7.
[18]S. Y. Park, C. L. Chen, and J. S. Lai, “A Wide-Range Active and Reactive Power Flow Controller for a Solid Oxide Fuel Cell Power Conditioning System,” IEEE Transactions on Power Electronics, Nov. 2008, Vol.23, Issue 6, pp.2703-2709.
[19]S. J. Peng, A. Luo, Z. P. Lv, J. B. Wu, and L. Yu, “Power Control for Single-Phase Microgrid Based on the PQ Thoery,” Proceedings of the 6th IEEE Conference on Industrial Electronics and Applications, Jun. 2011, pp.1274-1277.
[20]L.Liming, Z. Yan, and L. Hui, “Coordinated active and reactive power management implementation based on dual-stage PLL method for grid-connected PV system with battery,” Proceedings of Energy Conversion Congress and Exposition, Sep. 2010, pp.328-335.
[21]P. Esslinger and R. Witzmann, “Increasing grid transmission capacity and power quality by a new solar inverter concept and inbuilt data communication,” Proceedings of Innovative Smart Grid Technologies Conference Europe, Oct. 2010, pp.1-8.
[22]E. Paal, Z. Weitzl, and C.S. Choi, “Grid management functions built in PV inverters for distributed power generation,” Proceedings of Power Electronics and ECCE Asia, Jun. 2011, pp.2637-2644.
[23]X. Yong, J. Deng, and M. Shuangbao, “Power flow control of a distributed generation unit in micro-grid,” Proceedings of Power Electronics and Motion Control Conference, May. 2009, pp.2122-2125.
[24]W. L. Yu, T. P. Lee, G. H. Wu, Q. S. Chen, H. J. Chiu, Y. K. Lo, and F. Shih, “A DSP-Based Single-Stage Maximum Power Point Tracking PV Inverter,” Proceedings of the Twenty-Fifth Annual IEEE Conference and Exposition on Applied Power Electronics, Feb. 2010, pp.948-952.
[25]A.S. Masoum, F. Padovan, and M.A.S. Masoum, “Impact of Partial Shading on Voltage- and Current-Based Maximum Power Point Tracking of Solar Modules,” Proceedings of 2010 IEEE Power and Energy Society General Meeting, July 2010, pp.1-5.
[26]R. Kadri, J. P. Gaubert, and G. Champenois, “An Improved Maximum Power Point Tracking for Photovoltaic Grid-Connected Inverter Based on Voltage-Oriented Control,” IEEE Transactions on Industrial Electronics, Jan. 2011, Vol. 58, Issue 1, pp.66-75.
[27]林明立,基於DSP控制單級最大功率追蹤換流器與市電並聯技術,國立臺灣科技大學電子工程系碩士論文,2010 年 3 月。
[28]盧晉賢,具功率控制之市電併聯型系統單相Z源換流器的實現,國立高雄應用科技大學電機系碩士論文,2012 年 7 月。
[29]J. D. Li, Q. Wu, Z. W. Sun, and P. Xu, “A Switching-Inverter Power Controller Based on Fuzzy Adaptive PID,” Proceedings of the 6th International Forum on Strategic Technology, Aug. 2011, Vol. 2, pp.695-699.
[30]T. Kerekes, R. Teodorescu, P. Rodríguez, G. Vázquez, and E. Aldabas, “A New High-Efficiency Single-Phase Transformerless PV Inverter Topology,” IEEE Transactions on Industrial Electronics, Jan. 2011, Vol. 58, Issue 1, pp.184-191.
[31]Y. Li, J. Anderson, F.Z. Peng, and Dichen Liu, “Quasi-Z-Source Inverter for Photovoltaic Power Generation Systems,” Proceeding of the Twenty-Fourth Annual IEEE Applied Power Electronics Conference and Exposition, Feb. 2009, pp.918-924.
[32]N. Vidhyarubini and G. Rohini, “Z-source Inverter-Based Photo- voltaic Power Generation System,” Proceedings of 2011 International Conference on Emerging Trends in Electrical and Computer Technology, May 2011, pp.29-34.
[33]Y. Huang, M. S. Shen, F. Z. Peng, and J. Wang, “Z-Source Inverter for Residential Photovoltaic Systems,” IEEE Transactions on Power Electronics, Vol.21, Issue 6, Nov. 2006, pp.1776-1782.
[34]B. Yang, W.Li, Y. Zhao, and X. He, “Design and Analysis of a Grid-Connected Photovoltaic Power System,” IEEE Transactions on Power Electronics, Vol.25, Issue 4, Nov. 2010, pp.992-1000.
[35]L.R. Limongi, R.bojoi, A. Tenconi, and L. Clotea, “Single-phase inverter with power quality features for distributed generation systems,” Proceedings of Optimization of Electrical and Electronic Equipment, May. 2008, pp.313-318.
[36]沈家民,周宏亮,“市電併聯型電壓控制是主動是電力轉換器,” 電力電子雙月刊,Vol.10 No.3,2012年 3月,pp. 18-28。
[37]林運昇,楊志合,陳偉倫,“市電並聯型單相電流源型變流器之有效功率及無效功率控制,”第十屆中華民國電力電子研討會論文集,2011年 9月,pp. 811-816。
[38]Q. N. Trinh, H. H. Lee, and T. W. Chun, “A New Z-source Inverter Topology to Improve Voltage Boost Ability,” Proceeding of IEEE 8th International Conference on Power Electronics and ECCE Asia, June 2011, pp.1981-1986.
[39]謝宏燦,基於DSP控制之獨立型太陽能供電系統,國立台灣科技大學電子工程系碩士學位論文,2008 年 6 月。
[40]Y. H. Ji, D. Y. Jung, C. Y. Won, B. K. Lee, and J. W. Kim, “Maximum Power Point Tracking Method for PV Array under Partially Shaded Condition,” Proceedings of Energy Conversion Congress and Exposition, Sep. 2009, pp.307-312.
[41]黃崇倫,太陽光電能市電併聯轉換器之研製,國立雲林科技大學電機工程系碩士論文,2008 年 6 月。
[42]傅家麟,鄭儀誠,徐振凱,陳志堅,“太陽能出力預測技術現況分析,” 電力電子雙月刊,第7期,第4卷,2009 年 7 月,pp.46-53。
[43]賴威甫,梁從主,陳世明,王辰羽,“太陽能模組換流器之研製,” 電力電子雙月刊,第10期,第1卷,2012 年 1 月,pp.63-69。
[44]張宏展,林佑星,黃勁元,黃李堅,陳政傳,“家用型太陽能發電系統之研製,” 電力電子雙月刊,第7期,第6卷,2009 年 11 月,pp.91-99。
[45]吳財福、陳裕愷、張健軒,太陽光電能供電與照明系統綜論,全華圖書,2007 年 3 月。
[46]G. Lijun, C. Boeing, W. Seattle, R.A. Douqal, S. Liu, and A.P. Iotova, “Parallel-Connected Solar PV System to Address Partial and Rapidly Fluctuating Shadow Conditions,” IEEE Transactions on Industrial Electronics, Vol.26, Issue 5, May. 2009, pp.1548-1556.
[47]H. Taheri, Z. Salam, K. Ishague, and Syafaruddin, “A novel Maximum Power Point tracking control of photovoltaic system under partial and rapidly fluctuating shadow conditions using Differential Evolution,” Proceedings of Industrial Electronics & Applications, Oct. 2010, pp.82-87.
[48]G. Sivu, T.M. Walsh, A.G. Aberle, and M. Peters, “Analysing partial shading of PV modules by circuit modelling,” Proceedings of Photovoltaic Specialists Conference, Jun. 2012, pp.2957-2960.
[49]江炫樟,電力電子學,全華圖書股份有限公司,2010 年 6 月。
[50]江錫津,應用空間相量脈寬調變技術之數位是高功因單相/三相電力轉換器,國立雲林科技大學電機工程系碩士班,2003 年 6 月。
[51]L. Tang and G.J. Su, “Boost mode test of a current-source-inverter-fed permanent magnet synchronous motor drive for automotive applications,” Proceedings of Control and Modeling for Power Electronics, Jun. 2010, pp.1-8.
[52]F. Z. Peng, “Z-Source Inverter,” IEEE Transactions on Industry Applications, Vol.39, Issue 2, March 2003, pp.504-510.
[53]Y. Huang, M. S. Shen, F. Z. Peng, and J. Wang, “Z-Source Inverter for Residential Photovoltaic Systems,” IEEE Transactions on Power Electronics, Vol.21, Issue 6, Nov. 2006, pp.1776-1782.
[54]N. Vidhyarubini and G. Rohini, “Z-source Inverter-Based Photo- voltaic Power Generation System,” Proceedings of 2011 International Conference on Emerging Trends in Electrical and Computer Technology, May 2011, pp.29-34.
[55]M. Hanif, M. Basu, and K. Gaughan, “Understanding the ope
of a Z-source inverter for photovoltaic application with a design example,” IET Power Electronics, March 2011, pp.278-287.
[56]游欣璋,用於市電併聯型太陽光電系統之單相Z源換流器的數位模糊控制,國立高雄應用科技大學電機系碩士論文,2011 年 7 月。
[57]李豐林,基於Quasi-Z源逆變器的光伏發電系統,北京交通大學碩士學位論文,2011 年 6 月。
[58]H..J..Cha and.T..K..Vu,.“Comparative Analysis of low-Pass output filter for Single-Phase Grid-Connected Photovoltaic Inverter,” Proceedings of the 25 Annual IEEE Conference and Exposition on Applied Power Electronics, Feb. 2010, pp.1659-1665
[59]X..Wei,.L..Xiao,.Z..L..Yao, and.C..Y..Gong,.“Design of LCL Filter for Wind Power Inverter,”.Proceedings of 2010 IEEE Conference on World Non-Grid-Connected Wind Power and Energy, Nov. 2010, pp.1-6.
[60]廖國安,結合太陽能系統於不斷電系統並聯運轉之設計與研究,國立雲林科技大學電機工程系碩士班,2001 年 6 月。
[61]R. Chokhawala and S. Sobhani,.“Switching voltage transient protection schemes for high current IGBT modules,” Proceedings of Applied Power Electronics Conference and Exposition, Feb. 1994, pp.459-468
[62]IEEE Standard 1159-2010, IEEE Recommended Practice for Monitoring Electric Power Quality, IEEE, New York, June 2010.
[63]R.A. Mastromauro, M. Liserre, and A. Dell'Aquila, “Single-phase grid-connected photovoltaic systems with power quality conditioner functionality,” Proceedings of 2007 European Conference on Power Electronics and Applications, pp.1-11.
[64]李杰,Quasi-Z源逆變器的分析與設計,北京交通大學電氣工程,2009年6月
[65]李政勳,小型太陽光電能能源轉換系統之研製,國立中山大學電機工程學系碩士學位論文,2002 年 6 月。
[66]J.M. Guerrero, J. Matas, L.G. de Vicuña, and M. Castilla, “Wireless-Control Strategy for Parallel Operation of Distributed-Generation Inverters,” IEEE Transactions on Industrial Electronics, Vol.53, Issue 5, Oct. 2006, pp. 1461 - 1470.

QRCODE
 
 
 
 
 
                                                                                                                                                                                                                                                                                                                                                                                                               
第一頁 上一頁 下一頁 最後一頁 top
系統版面圖檔 系統版面圖檔