跳到主要內容

臺灣博碩士論文加值系統

(100.28.227.63) 您好!臺灣時間:2024/06/15 01:02
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:陳慶源
研究生(外文):Cing-yuan Chen
論文名稱:線性啟動永磁同步電動機分析與模擬
論文名稱(外文):Analysis and Simulation in Line-start Permanent Magnet Synchronous Motor
指導教授:郭見隆郭見隆引用關係
指導教授(外文):Jian-Long Kuo
學位類別:碩士
校院名稱:國立高雄第一科技大學
系所名稱:機械與自動化工程所
學門:工程學門
學類:機械工程學類
論文種類:學術論文
論文出版年:2008
畢業學年度:96
語文別:中文
論文頁數:111
中文關鍵詞:直接啟動永磁同步電動機短路阻尼棒180度正弦驅動有限元素法啟動轉矩田口法雙反應曲面法
外文關鍵詞:LS-PMSMDamper Bar180 degree sinusoidal drivingFinite Element MethodStarting TorqueTaguchi MethodResponse Surface Method
相關次數:
  • 被引用被引用:0
  • 點閱點閱:678
  • 評分評分:
  • 下載下載:0
  • 收藏至我的研究室書目清單書目收藏:0
直接啟動永磁同步電動機(Line-Start Permanent Magnet Synchronous Motor,LS-PMSM),不同於傳統的永磁同步電機(Permanent Magnet Synchronous Motors,PMSM)具有容易啟動的特性,特別適合用來作為壓縮機馬達之用,因其具有設計為永磁凸極短路阻尼棒(Damper Bar),使得啟動比較容易。故不需要採用一般偵測反電動勢的方法,所以不同於傳統120度方波驅動方式,可以使用180度正弦驅動。
本論文將對180度正弦驅動之LS-PMSM研究其效率與性能提升的方法。因此本文利用有限元素分析軟體MagneForce針對不同結構來對此馬達做靜態分析,並且分析LS-PMSM輸出單一轉矩(Starting Torque)現象,以變更原始結構如氣隙、轉子鋁導體等來模擬馬達的輸出特性,最後配合田口實驗設計法(Taguchi Method)與雙反應曲面法(Response Surface Method,RSM)預估各種組合,依照新的參數來搜尋出最大啟動轉矩的馬達幾何結構。
Line-Start Permanent Magnet Synchronous Motor(LS-PMSM) is different from the Permanent Magnet Synchronous Motor.The LS-PMSM is easy to start since the damper copper bar is embedded in the salient pole.The controller drive is developed to control the LS-PMSM including the starting of the motor.180 degree sinusoidal driving is used to provide better performance.
Therefore, the FEM will be employed to discuss the magnetostatic analysis and transient properties of the LS-PMSM in the thsis. More specifically, the starting torque of the LS-PMSM will be assessed when altered the geometries such as alterations of the air gap, and the damper bar of the stator of the LS-PMSM. Additionally, the design of the experiments (DOE) will be employed to find out the maximum starting torque.
摘要............................................I
Abstract............................................II
致謝............................................III
目錄............................................IV
圖目錄............................................VI
表目錄............................................IV
第一章 緒論..............................................1
1.1 前言.................................................2
1.2 研究背景與目的 ...................................... 2
1.3 研究目標及方法 .......................................3
1.4 文獻回顧.............................................5
1.5 論文大綱.............................................6
第二章 直接啟動永磁同步馬達之驅動.....................7
2.1 直接啟動永磁同步馬達之簡介...........................7
2.1.1 轉子磁極結構...................................8
2.1.2 永久磁鐵種類簡介...............................9
2.1.3 PM馬達的分類..................................10
2.1.4 LS-PMSM數學模型的建立與推導...................11
2.1.5 LS-PMSM穩態模型...............................14
2.2 三相交流馬達之變頻驅動..............................16
2.2.1 三相交流馬達驅動電路..........................16
2.2.2 變頻器數學模式................................18
2.2.3 正弦波寬調變策略..............................20
2.3 LS-PMSM馬達電路系統架構.............................24
2.3.1 變頻器電路........................................25
2.3.2 閘極驅動電路..................................26
2.3.3 電源級........................................27
2.4系統相關波形量測.....................................28
第三章 永磁同步電機之有限元素模型....................34
3.1 有限元素法介紹......................................34
3.2 靜磁模組的數學理論..................................35
3.3 MagneForce基本介紹..................................36
3.4 永磁式電機之模型建立................................39
3.4.1 永磁式電動機之規格簡介........................39
3.4.2 幾何結構的建立................................40
3.4.3 馬達之網格劃分................................41
3.4.4 材質介紹與設定................................42
3.4.5馬達繞組排列方式...............................44
3.4.6 驅動電路與轉子導體棒設定..........................47
3.5 永磁式同步電機模擬結果..............................49
3.5.1 靜態電磁場分析................................49
3.5.2 暫態電磁場分析................................50
3.5.3 啟動性能模擬結果..............................53
第四章 田口實驗設計法................................58
4.1 田口法原理..........................................58
4.2 損失函數............................................59
4.3 直交表..............................................61
4.4 信號雜音比的選擇....................................62
4.5 變異數分析..........................................63
4.6 田口法實驗程序 ......................................64
4.7 田口法實驗..........................................66
4.7.1 問題定義的描述................................66
4.7.2 品質特性及量測系統的選定......................66
4.7.3 選擇適當的直交表..............................69
4.7.4 進行實驗及分析實驗所得之結果..................71
第五章 雙反應曲面法..................................79
5.1 雙反應曲面法簡介....................................79
5.2 雙反應曲面法的理論與分析設計........................80
5.2.1 實驗設計......................................81
5.2.2 模型建構......................................81
5.2.3 參數優化......................................84
5.3 雜訊因子未知下的穩健設計............................85
5.4 實驗設計-未知雜訊因子...............................86
5.4.1 模型建構......................................87
5.4.2 參數設計......................................91
5.5 實驗設計-已知雜訊因子...............................91
5.5.1 模型建構......................................93
5.5.2 參數設計......................................98
5.6 田口實驗設計法與雙反應曲面法之評論..................99
第六章 結論與未來展望...............................102
參考文獻...............................................104
附錄-詞彙中英對照(依出現順序)..........................107
作者簡歷...............................................111
[1]創盛網-通風設備頻道商務交易網,http://tf.cs365.com.cn/.
[2]J. Hu, D. Zhu, and B. Wu, “Permanent magnet synchronous motor drive without mechanical sensors,” IEEE Electrical and Computer Engineering, Canadian Conference, vol. 2, pp. 603-606, 1996.
[3]L. Xu and C. Wang, “Implementation and experimental investigation of senseless control schemes for PMSM in super-high variable speed operation,” IEEE Industry Applications Conference, Thirty-Third IAS Annual Meeting, vol. 1, pp. 483-489, 1998.
[4]T. Miller, “Synchronization of line-start permanent magnet AC motor [J],”IEEE Trans. On Power Apparatus and System, pp.1822-1828, 1984.
[5]Wen-Bin Tsai and Ting-Yu Chang, “Analysis of Flux Leakage in a Brushless Permanent Magnet Motor with Embedded Magnets,”IEEE Transactions on Magnetics, vol. 35, NO. 1, pp. 543-547, January, 1999.
[6]R.D. Lorenz and P.B. Schmidt, “Synchronized motion control for process automation,”Proceedings of the IEEE Industry Applications Annual Meeting, pp.1693-1698,1989.
[7]A. Munoz-Garcia, T.A. Lipo, D.W. Novotny, “A new induction motor V/f control method capable of high-performance regulation at low speeds,” Industry Applications, IEEE Transactions on Electric Power Application ,vol.34 , Issue: 4 ,pp. 813-821, July- Aug. 1998.
[8] J. John, N. Nomura, and H. Ohsawa, “A Sensorless, Stable V/f Control Method for Permanent-Magnet Synchronous Motor Drives,” Power Conversion Conference , 2002 ,PCC-osaka , Proceedings of the ,vol.3 , pp.1310-1315, 2002.
[9]A.M. Have, R. J. Kerkman, and T.A. Lipo, “high- performance generalized discontinuous PWM algorithm,” Industry Applications, IEEE Transactions on, vol.34, Issue:5, pp.1059-1071, Sept.- Oct.1998.
[10]K.R. Shouse and D.G. Taylor, “Sensorless velocity control of permanent-magnet synchronous motors,” IEEE Transactions on Control Systems Technology, Vol. 6, No. 3, pp. 313-324, 1998.
[11]D.W. Shimmin, J. Wang, N. Bennett, and K.J. Binns, “Modelling and stability analysis of a permanent-magnet synchronous machine taking into account the effect of cage bars,” IEE Proceedings 142 Electric Power Application,:pp.137-144, March 1995.
[12]John Wiley, and Sons, Equivalent Circuits of Electric Machinery, Gabriel Kron., 1951.
[13]Benard Adkins, The General Theory of Electrical Machines, Chapman and Hall Ltd., 1959.
[14]唐任遠,現代永磁電機理論與設計,機械工業出版社,2004年4月。
[15]李鐘明、劉衛國,稀土永磁電機,國防工業出版社,1999年7月。
[16]Rajeev Vyas, Sunil Murthy and Tomy Sebastian, “Evaluation of Brushless Permanent Magnet Motor Rotor Configuration for Square Wave Current Excitaion, ” IEEE Power Electronics, Drives and Energy Systems for Industrial Growth, Vol. 2, pp.895-899, January 1996.
[17]彭美珠摘譯,“變頻器”,光堡冷凍空調技術網,http://HVACR.com.tw.
[18]J. I. Itoh, N. Nomura, and H. Ohsawa, “ A Sensorless, Stable V/f Control Method for Permanent-Magnet Synchronous Motor Drives,” Power Conversion Conference ,PCC-osaka, Proceedings of the ,vol:3 , pp.1310-1315 , 2002.
[19]J. R. Hendershot, Jr and T. J. M. Miller, “Design of Brushless Permanent-Magnet Motor, ”Chapter 3, Oxford. University Press, 1994.
[20]張正、林清一,現代電力電子技術,全華書局,1998年4月
[21]龔應時、陳建武、徐永松、TMS320F/C24x DSP控制器原理與應用,滄海書局,2001年9月
[22]李輝煌,田口方法-品質設計的原理與實務,高立圖書有限公司,2003年。
[23]鄧世輝,漫談傳統型品質工程與田口品質工程,品質管制月刊,1987年。
[24]林鴻裕、厲光耀,“結合有限元素法和田口法對硬碟磁盤震動特性之研究”,國立屏東科技大學機械研究所碩士論文,2003。
[25]李輝煌,田口方法品質設計得原理與實務,高利圖書公司,2002年。
[26]S.K. Fan and E.D. Castillo, Calculation of an optimal region of operation dual response systems fitted from experimental data, Journal of the Operational Research Society, 50, 8, 826-836, 1999.
[27]G. S. Peace, Taguchi Method - A Hand On Approach, Addison - Wesley, 1989.
[28]M. S. Phadk, Quality Engineering Using Robust Design. AT & T Bell Laboratories , 1985.
[29]金屬工業研究發展中心,http://www.mirdc.org.tw/.
[30]賴益志,“無刷直流馬達之磁路特性分析”,國立成功大學機械工程系碩士論文,2000年。
[31]E.D. Castillo and D.C. Montgomery, A nonlinear programming solution to the dual response problem, Journal of Quality Technology, pp.199-204, 1993.
[32]L.C. Tang and K. Xu, A unified approach for dual response surface optimization, Journal of Quality Technology, 34, pp.437-447, 2002.
[33]S.K. Fan and E.D. Castillo, Calculation of an optimal region of operation dual response systems fitted from experimental data, Journal of the Operational Research Society, 50, 8, pp.826-836, 1999.
QRCODE
 
 
 
 
 
                                                                                                                                                                                                                                                                                                                                                                                                               
第一頁 上一頁 下一頁 最後一頁 top