感應式無刷解角器與解碼設計及分析__國立清華大學博碩士論文全文影像系統

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作者(中文):	徐家偉
論文名稱(中文):	感應式無刷解角器與解碼設計及分析
論文名稱(外文):	Design and Analysis of Inductive Brushless Resolver and R/D Converter
指導教授(中文):	王培仁
口試委員(中文):	茆尚勳曹哲之
學位類別:	碩士
校院名稱:	國立清華大學
系所名稱:	動力機械工程學系
學號:	101033545
出版年(民國):	103
畢業學年度:	102
語文別:	中文
論文頁數:	78
中文關鍵詞:	旋轉變壓解角器、協同分析、角度檢測
外文關鍵詞:	Rotary Transformer Resolver、Co-simulation、Angle Detection
相關次數:	推薦:0 點閱:120 評分: 下載:0 收藏:0

控制用微型電機中旋轉變壓解角器，因具有高性價比及耐候性之特性徵，或因解析及準確度比高階光學式編碼器略差，卻仍應用於航太、軍事及工業產品，尤其此型式解角器被廣泛應用於現今工業控制伺服系統。本論文研究目的為建立旋轉變壓解角器之設計流程及各項設計參數於輸出訊號之建模分析，並藉已知數位解碼器模型進行多重領域協同分析，以達到提昇產品性能與解碼器精度之目標。
本論文之研究過程首先選用一市售感應式無刷解角器，以電腦輔助設計系統建立解角器之幾何參數，再轉檔建模於電磁場工程分析系統與設定激勵條件，經由參數設計功能優化輸出訊號之品質後，針對旋轉變壓器進行簡化之電路建模與分析；續以動態系統模擬程式建立解碼器數位模型，先進行理想條件下之動態響應分析，在理想弦波封包測試模型得出動態解析度；最終結合電磁工程分析系統與數位解碼器模型進行多重領域系統協同分析，完成輸出訊號之驗證。本研究建立旋轉變壓解角器之基本設計參數與整體數值驗證過程，提供未來產品開發與研製所需要之基本設計參考數據。

目錄
摘要 I
ABSTRACT II
目錄 III
表目錄 V
圖目錄 VI
第一章緒論 1
1-1 研究背景 1
1-2 研究目的 2
1-3 文獻回顧 3
1-3-1 電氣結構 3
1-3-2 電腦輔助工程分析 5
1-3-3 訊號分析 5
1-3-4 變壓器分析 7
第二章理論介紹 10
2-1 解角器簡介 10
2-2 解角器原理 12
2-3 解角器至數位訊號轉換器介紹 14
2-4 電磁場及磁路理論 15
2-5 磁性材料與磁滯 18
第三章建模及靜磁分析 29
3-1 電磁場及系統分析軟體介紹 29
3-2 分析用解角器 30
3-3 解碼器 AD2S1210 31
3-4 解角器模型建構與分析 32
第四章模擬結果與分析 45
4-1 旋轉變壓器 45
4-2 解角器 2D/3D 暫態分析 47
4-3 解碼器分析 50
4-4 電磁場、電路、解碼器協同模擬 51
第五章結果與討論 73
5-1 結論 73
5-2 未來工作 75
參考文獻 76

參考文獻
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[14] J. Wan, X. Li, and H. Guo, "The Analysis and Design of High-speed Brushless Resolver plus RD Converter Shaft-angle Measurement system", Electrical Machines and Systems. ICEMS 2001. Proc. of the 5th Int. Conf. 2001. Shenyang.
[15] V. D. Aksenenko and S. I. Matveyev, "Digital Angle Sensor Self-Calibration: Two Approaches to Accuracy Increasing", Instrumentation and Measurement Technology Conference. 2005: Ottawa, Canada. p. 543 - 547.
[16] D. Arab-Khaburi, F. Tootoonchian, and Z. Nasiri-Gheidari, "Dynamic Performance Prediction of Brushless Resolver", Iranian Journal of Electrical and Electronic Engineering, 2008, pp.94-103
[17] T. A. Stuart, R. J. King, and H. Shamseddin, "Rotary Transformer Design with Fixed Magnetizing and/or Leakage Inductances", IEEE Trans. Aero. and Electr. Syst., 1986. AES-22(5): pp. 565 - 572.
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[19] B. Dominik, F. Lukas, L. Andreas, and K. J. W, "Analysis of Rotary Transformer Concepts for High-speed Applications", Appl. Power Electr. Conf. and Expo. (APEC), 28th Annual IEEE. 2013: Long Beach, CA. pp. 3262 - 3269.
[20] 游超智, 徐錦衍, 許騌譁, 激磁與感應電壓於車輛非接觸式轉角感測器之應用, 中國機械工程學會第二十九屆全國學術研討會. 2012: 國立中山大學.
[21] Bulletin, Brushless Resolvers Based on a Novel Automatic Winding Method, 2011, Tamagawa Trading Co.,LTD., Japan.

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