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研究生:蔣宗祐
研究生(外文):JIANG, ZONG-YOU
論文名稱:串並聯電力轉換器之整合控制與應用
論文名稱(外文):Integrated Control and Application of Series-Parallel Power Converters
指導教授:馬肇聰
指導教授(外文):MA.TSAO-TSUNG
口試委員:梁瑞勳陳榮堅
口試委員(外文):LIANG, RUI-XUNCHEN, RONG-JIAN
口試日期:2020-03-18
學位類別:碩士
校院名稱:國立聯合大學
系所名稱:電機工程學系碩士班
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:2020
畢業學年度:108
語文別:中文
論文頁數:184
中文關鍵詞:再生能源電力品質主動式電力濾波器
外文關鍵詞:renewable energypower qualityactive power filters
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近年來,為了減緩全球暖化的速度,世界各國皆積極發展以再生能源為基礎之發電系統,但再生能源深受天候條件的影響,本質上存在不可控性與間歇性的問題,併網後將對電網產生負面影響。此外,因應工業4.0的產業升級,生產端使用了大量自動化設備,此類設備操作時所產生的電力品質問題將增加對電網的干擾程度,也可能造成電力供應端與用戶端額外的經濟損失。針對上述問題本文將探討一種整合串、並聯主動式電力濾波器、電池儲能單元與再生能源單元的電力控制方案並提出相關控制策略。本文首先描述了所提系統各種可能的操作模式,接著探討各個電力轉換器的硬體架構以及控制演算法。為提高系統運作時的動態響應以及電力品質的改善效果,本研究嘗試將類神經網路結合PI控制器。接著,依照所提系統各種可能的操作模式配合常見電壓與電流品質問題規劃各式控制案例,利用Psim軟體進行模擬與分析。最後再以TI DSP TMS320F28335數位處理器做為各轉換器的控制核心,並配合實驗室的硬體設備與相關介面電路建構一小容量的硬體實驗平台,進行實作測試。由模擬與實驗結果可以證明所提之控制架構與演算法具有正確性及有效性。
In recent years, in order to decrease the rate of global warming, countries around the world are actively developing renewable energy-based power generation systems. However, renewable energy is strongly affected by weather conditions. There are essentially existing uncontrollable and intermittent problems having negative impacts on the grid. In addition, in response to the development of Industry 4.0, a large number of automation equipment is used in various industrial sectors. The power quality problems caused by such devices have increased the degree of interference to the power grid, and have also caused additional economic losses to both the power supply and the user ends. Aiming at the above problems, this thesis investigates a power control scheme that integrates series and parallel active power filters, battery energy storage units and renewable energy units, and proposes related control strategies. In this thesis, various possible operating modes of the proposed power control mechanism are firstly described, and then the hardware architecture and control algorithms for each power converter are discussed. To improve the system dynamic response and the level of power quality improvement, this study attempts to combine a neural network with a PI controller. Finally, the TI DSP TMS320F28335 digital signal processor is used as the control kernel of each converter, and a small-scale hardware experimental platform is constructed with the laboratory equipment and related interface circuits for practical tests. Both simulation and experimental results are presented to prove the correctness and effectiveness of the proposed control schemes and algorithms.
致謝 I
摘要 II
Abstract III
目錄 IV
圖目錄 VI
表目錄 XIX
符號索引 XXI
第一章 緒論 1
1.1 研究背景 1
1.2 文獻回顧 7
1.3 研究目的 10
1.4 論文架構 12
第二章 UPCESS系統與操作模式介紹 13
2.1 UPCESS系統的硬體電路架構 13
2.2 UPCESS系統的操作模式 14
第三章 UPCESS系統控制器規劃與設計 22
3.1 UPCESS電力轉換器主要電路元件設計 22
3.2 並聯換流器之控制器規劃 27
3.3 串聯換流器之控制器規劃 40
3.4 升降壓轉換器之控制器規劃 48
3.5 鎖相迴路 52
3.6 類神經網路控制器 54
第四章 案例模擬與分析 59
4.1 案例一 61
4.2 案例二 67
4.3 案例三 71
4.4 案例四 82
4.5 案例五 93
4.6 案例六 100
第五章 硬體實作與測試結果 113
5.1硬體架構 113
5.2 案例一 116
5.3 案例二 119
5.4 案例三 121
5.5 案例四 130
5.6 案例五 138
5.7 案例六 144
第六章 結論與未來研究方向 153
6.1 結論 153
6.2 未來研究方向 153
參考文獻 155

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