許源浴臺灣大學:電機工程學研究所丁瑞霖Ting, Jui-LinJui-LinTing2010-07-012018-07-062010-07-012018-07-062008U0001-2006200816320900http://ntur.lib.ntu.edu.tw//handle/246246/187958隨著環保意識的抬頭與發電燃料成本價格的上漲，再生能源逐漸受到重視，風力發電即為其中一種方式。三相感應發電機為風力發電系統的電力來源，但由於感應機本身有電壓調整能力不佳的缺點，兼之風力的來源並不穩定，故需要額外的控制器。本論文應用一靜態同步補償器，提供系統無效電力，用來調整系統電壓，以及改善電壓品質。 靜態同步補償器，在架構上是由一直流電容器來提供電壓來源，並使用脈波寬度調變技術以調節三相電壓源型變流器的輸出電壓。 在模擬方面使用Matlab/Simulink軟體來評估系統的補償效果，實驗方面採以個人電腦為基礎，配合研華科技公司PCL-1800資料擷取卡，透過C語言來達成電壓補償控制，最後由模擬及實驗結果來驗證靜態同步補償器應用於感應機併聯電力系統，確實可以有效維持系統電壓的穩定性。As the issue of environmental protection receives increasing attention and the price of fuel increases, renewable energy source, such as wind turbine generator system, is getting more and more important. Three phase induction generators are the main source of the power. Induction machines have unsatisfactory voltage regulation and the wind speed is variable. Hence, in this thesis, a static synchronous compensator is applied to supply reactive power for the system, to regulate bus voltage, and to achieve better voltage profile on the customer side. The static synchronous compensator employs a direct current capacitor to offer voltage source and use the pulse-width modulation technique to adjust the output voltage of the three phase voltage source inverter.he effectiveness of the STATCOM is investigated by simulations using the MATLAB/Simulink software and experiments. In the experiments, the controller of the STATCOM is based on a personal computer with Adventec PCL-1800 data acquisition cards. Digital control is implemented using C language. Finally, it is concluded from results of simulations and experiments the load bus voltage in a grid-connected induction generator can be effectively regulated by the STATCOM.致謝......................................................i要.....................................................iibstract................................................iii錄.....................................................iv目錄.................................................viii目錄..................................................xii一章 緒論..............................................1 1.1研究背景.............................................1 1.2文獻回顧.............................................1 1.3研究方法與目的.......................................5 1.4論文內容介紹.........................................6二章 感應發電機之特性分析與參數量測....................7 2.1前言.................................................7 2.2感應發電機的優缺點...................................7 2.3感應發電機併聯電力系統...............................8 2.4感應電機參數量測.....................................9 2.4.1定子電阻值之量測試驗.............................9 2.4.2堵住轉子試驗....................................10 2.4.3同步轉速試驗....................................12三章 靜態同步補償器簡介...............................14 3.1前言................................................14 3.2並聯補償器基本工作原理..............................14 3.2.1 STATCOM基本架構................................15 3.3靜態同步補償器對系統的影響..........................16 3.3.1電壓穩定度......................................16 3.3.2暫態穩定度......................................18 3.3.3功因改善........................................19 3.3.4電壓支撐........................................20 3.3.5線路傳輸功率....................................21 3.4補償器特性分析......................................23 3.5元件參數之決定......................................24 3.5.1電容器電壓與電容值設計..........................24 3.5.2補償器濾波電感器的設計..........................25 3.5.3補償器容量的計算................................26 3.6脈衝寬度調變(PWM)切換技術...........................26 3.6.1 PWM電壓控制器..................................26 3.6.2 變流器切換頻率之分析...........................28四章 演算法分析.......................................30 4.1前言................................................30 4.2演算法分析..........................................30 4.2.1同步旋轉座標轉換法..............................31 4.2.2靜態同步補償器之數學模型建立....................32 4.2.3解耦合電流控制..................................35五章 模擬結果與分析...................................37 5.1前言................................................37 5.2強健系統(Strong System)(電源阻抗較小)...............37 5.2.1轉速變動........................................37 5.2.2負載變動........................................41 5.3弱系統(Weak System)(電源阻抗較大) ..................44 5.3.1轉速變動........................................44 5.3.2負載變動........................................46六章 靜態同步補償器之實體製作.........................49 6.1前言................................................49 6.2硬體電路製作........................................49 6.2.1實作電路之系統架構..............................50 6.2.2研華PCL-1800資料擷取卡之簡介與設定..............51 6.2.3電力電路之製作..................................55 6.2.4驅動與互鎖電路之製作............................58 6.2.5同步控制電路及鎖相電路之製作....................61 6.2.6電壓、電流感測器之製作..........................66 6.2.7其他相關硬體之製作..............................68 6.3軟體程式規劃........................................69 6.3.1軟體簡介........................................69 6.3.2軟體程式之規劃設計..............................69 6.3.3類比訊號輸入控制流程............................71 6.3.4補償信號控制流程................................71七章 實驗結果與分析...................................72 7.1前言................................................72 7.2強健系統(Strong System)(電源阻抗較小)...............72 7.2.1轉速變動........................................72 7.2.2負載變動........................................76 7.3弱系統(Weak System)(電源阻抗較大) ..................79 7.3.1轉速變動........................................79 7.3.2負載變動........................................82八章 結論.............................................86 8.1結論................................................86 8.2未來研究方向........................................86考文獻.................................................872696310 bytesapplication/pdfen-US風力發電感應發電機電壓調整靜態同步補償器wind energy generationinduction generatorvoltage regulationstatic synchronous compensator[SDGs]SDG7thesishttp://ntur.lib.ntu.edu.tw/bitstream/246246/187958/1/ntu-97-R95921076-1.pdf