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研究生: 王慶榆
Wang, Ching-Yui
論文名稱: 具有高彈性化之無線充電感應線圈設計
Inductive Coil Design for Wireless Power Transfer with High Flexibility
指導教授: 黃世杰
Huang, Shyh-Jier
學位類別: 碩士
Master
系所名稱: 電機資訊學院 - 電機工程學系
Department of Electrical Engineering
論文出版年: 2014
畢業學年度: 103
語文別: 中文
論文頁數: 97
中文關鍵詞: 無線電能感應線圈設計
外文關鍵詞: wireless power transfer, inductive coil design
相關次數: 點閱:112下載:5
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    • 本文提出一套具有高彈性化之無線電能感應線圈設計,此研究乃因目前相關領域著重探討補償電容與感應鐵芯結構,對於感應線圈之參數計算上之研究較為有限,因此本文即致力於提出線圈設計方法,並可依系統所需規格進行感應線圈之參數値設計,其中本文利用互感等效模型與阻抗匹配,同時分析非接觸電能輸出特性與諧振增益,且在選定適合之補償架構後,同時模擬線圈磁場強度及耦合係數,並彙整為一套可彈性適用於多種應用場合之感應線圈設計流程。至為驗證本文所提方法之可行性,本文已完成硬體電路實作,並由測試結果得知系統於既定系統規格條件下,確可符合電能傳輸需求,輔以佐證本論文所提之設計方法具有實際應用價值。

    This thesis proposes an inductive coil design with high flexibility. Previous studies were mainly focused on the compensation capacitor and coupling structure design. Yet, for the magnetic windings design, the investigation was relatively limited. Therefore, this thesis is aimed to propose a coil design method which can be flexibly adjusted to correspond to system specification. By using the mutual inductance model and impedance matching along with the analysis of contactless power output and resonance features, the method is capable of choosing the appropriate compensation structure, and then combined to be a magnetic windings design flowchart coming high flexibility for applying to different scenarios. To validate the feasibility of this approach, a hardware prototype is completed and experimental results show that this designated circuit achieves a satisfactory efficiency in correspondence to system specifications. These test results support the practical value of the proposed method.

    中文摘要 I 英文摘要 II 誌謝 V 目錄 VI 表目錄 IX 圖目錄 X 符號說明 XV 第一章 緒論 1 1-1 研究動機 1 1-2 研究方法與目的 2 1-3 內容大鋼 3 第二章非接觸式變壓器等效模型與換流器諧振電路分析 5 2-1簡介 5 2-2 非接觸感應線圈之等效電路模型分析 6 2-3 補償諧振電路分析 8 2-3-1 SS補償架構輸出特性 11 2-3-2 SP補償架構輸出特性 15 2-4 換流器與整流濾波器之電路分析 19 2-4-1 各式換流器架構分析 20 2-4-2 全橋相移調變理論 22 2-4-3 整流濾波電路分析 24 2-4-4 換流器與諧振補償電路之時序分析 27 第三章 系統軟硬體電路設計 34 3-1 前言 34 3-2 控制與驅動電路 35 3-2-1 微控制器簡介 35 3-2-2 控制訊號產生電路 36 3-2-3 光耦合隔離驅動電路 37 3-3 感應線圈結構模擬與分析 41 3-4 感應線圈平台之參數設計 48 3-5 感應線圈平台之硬體電路圖 60 第四章 系統實驗結果 63 4-1 簡介 63 4-2 非接觸式電能傳輸系統之變動負載測試 63 4-3 感應線圈平台之電路特性測試 68 4-3-1 SP補償電容諧振電路實測分析 68 4-3-2 整流器之電路測試 79 4-4 全橋式換流器之柔性切換特性測試 83 4-5 非接觸系統效率實測 89 第五章  結論與未來研究方向 91 5-1 結論 91 5-2 未來研究方向 92 參考文獻 93

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