研究生: |
張書僑 SHU-CHIAO CHANG |
---|---|
論文名稱: |
儀器用高功率雙輸出電源供應器之研究 Study on a High Power Dual-output Power Supply for Instrumentation Applications |
指導教授: |
劉益華
Yi-Hua Liu 羅有綱 Yu-Kang Lo 邱煌仁 Huang-Jen Chiu |
口試委員: |
林景源
Jing-Yuan Lin 林忠義 Chung Yi Lin |
學位類別: |
碩士 Master |
系所名稱: |
電資學院 - 電機工程系 Department of Electrical Engineering |
論文出版年: | 2014 |
畢業學年度: | 102 |
語文別: | 中文 |
論文頁數: | 123 |
中文關鍵詞: | 無橋式昇壓型功率因數修正器 、全橋串聯諧振轉換器 、ZVS零電壓柔性切換 |
外文關鍵詞: | Bridgeless Boost Power Factor Corrector, Full-Bridge Series Resonant Converter, Zero Voltage Switching |
相關次數: | 點閱:554 下載:5 |
分享至: |
查詢本校圖書館目錄 查詢臺灣博碩士論文知識加值系統 勘誤回報 |
本文研製一台儀器用高功率雙組輸出轉換器,前級採用無橋式昇壓型功率因數修正器以達到高功率因數和低輸入電流諧波,且使用無橋技術減少損耗提高轉換效率。後級採用全橋串聯諧振轉換器,實現零電壓柔性切換,降低切換損。本文分析各級的電路工作原理與等效電路推導,再利用MATHCAD模擬軟體針對全橋串聯諧振轉換器,模擬品質因數Q、K因子、特性阻抗Zo及圈數比n,分析與探討其轉移函數曲線,以設計適合的功率及磁性元件。最後,實際設計一組電源供應器,在輸入265Vac的情況下,效率最高可達95%,並將量測結果與理論相互印證。
This thesis focuses on the study on High Power Dual-output Power Supply for Instrumentation Applications. A bridgeless boost power factor corrector (PFC) operated under continuous conduction mode (CCM) is designed and implemented to achieve high power factor, low input current ripple and high efficiency. A full-bridge series resonant converter with zero voltage switching (ZVS) is used as the post-stage circuit. The influences of the quality factor, K factor, characteristic impedance, and turns ratio on the voltage gain transfer function have been analyzed and discussed by using the MATHCAD software to design the magnetics for presented power converter.Satisfactory experimental results confirm the validity and feasibility of the adopted schemes. Potential future works are mentioned to further improve the power rating and conversion efficiency.
Chang-Hua Lin, Chien-Ming Wang, Min-Hsuan Hung, and Ming-Hsuan Li, “Series-Resonant Battery Charger with Synchronous Rectifiers for LiFePO4 Battery Pack,” ICIEA, pp. 316 - 321, 21-23 June 2011.
[2] Yinquan Hu and Heping Liu, “Design of Management System for LiFePO4 Power Batteries Group,” ICECE, pp. 5110 - 5113, 25-27 June 2010.
[3] Pei Zhang, Changqing Du, Fuwu Yan, and Jianqiang Kang, “Research on Energy Efficiency of the Vehicle's Battery Pack,” ICEICE, pp. 5245 - 5248, 15-17 April 2011.
[4] Youn Ki Ko, Sang Soon Cho, Hoon Huh, Sang Yeob Lee, Hong Tae Park, and Il Sung Oh, “Design of HEV-Relay Using Response Surface Method to Improve Bounce Characteristics,” ISIE, pp. 169 - 174, 5-8 July 2009.
[5] Tae-Uk Jung, Sung-Ho Lee, Sung-II Kim, Sung-Jun Park, and Jung-Pyo Hong, “The Development of Hybrid Electric Compressor Motor Drive System for HEV,” VPPC, pp. 802 - 807, 9-12 Sept. 2007.
[6] Haoming Zhang and Shenping Ding, “Application of Synergic Electric Power Supply in HEV,” WCICA, pp. 4097 - 4100, 7-9 July 2010.
[7] Dae-Sung Jung, Jae-Hong Song, Un-Ho Lee, and Hyeoun-dong Lee, “Improving Design of HEV Traction Motor for High Power Density,” ICPE & ECCE, pp. 2677 - 2680, May 30 2011-June 3 2011.
[8] Xiusheng Cheng and Yinshu Wang, “A Study on The Engaging Process of Energy-Saving Clutch in ISG HEV,” MEC, pp. 1732 - 1735, 19-22 Aug. 2011.
[9] Yongchang Du, Jinwen Gao, Liangyao Yu, Jian Song, Feng Zhao, and Wenzhang Zhan, “HEV System Based on Electric Variable Transmission,” VPPC, pp. 578 - 583, 7-10 Sept. 2009.
[10] Bin Su, Junming Zhang, and Zhengyu Lu, “Single Inductor Three-Level Boost Bridgeless PFC Rectifier with Nature Voltage Clamp,” IPEC, pp. 2092 - 2097, 21-24 June 2010.
[11] Woo-Young Choi, Jung-Min Kwon, and Bong-Hwan Kwon, “An Improved Bridgeless PFC Boost-doubler Rectifier with High-Efficiency,” PESC, pp. 1309 - 1313, 15-19 June 2008.
[12] Tsorng-Juu Liang, Shih-Cheng Kang, Chun-An Cheng, Ray-Lee Lin, and Jiann-Fuh Chen, “Analysis and Design of Single-Stage Electronic Ballast with Bridgeless PFC Configuration,” IECON, Vol. 1, pp. 502 - 508, 2-6 Nov. 2003.
[13] Shi-Gong Jiang, Gui-Hua Liu, Wei Wang, and Dian-Guo Xu, “Research on Bridgeless Boost PFC with Soft-Switching,” VPPC, pp. 1461 - 1464, 7-10 Sept. 2009.
[14] Jong-Won Shin, Jong-Bok Baek, and Bo-Hyung Cho, “Bridgeless Isolated PFC Rectifier Using Bidirectional Switch and Dual Output Windings,” ECCE, pp. 2879 - 2884, 17-22 Sept. 2011.
[15] Wei Wang, Guihua Liu, and Dianguo Xu, “Bridgeless Boost PFC with Fast Dynamic Response Algorithm,” EPE, pp. 1-6, 8-10 Sept. 2009.
[16] Woo-Young Choi, Jae-Yeon Choi, and Ju-Seung Yoo, “Single-Stage Bridgeless Three-Level AC/DC Converter with Current Doubler Rectifier,” ICPE & ECCE, pp. 2704 - 2708, May 30 2011-June 3 2011.
[17] Woo-Young Choi, Wen-Song Yu, and Jih-Sheng Lai, “A Novel Bridgeless Single-Stage Half-Bridge AC/DC Converter,” APEC, pp. 42 - 46, 21-25 Feb. 2010.
[18] Koulin Wu, Qianhong Chen, Ke Jin, and Xinbo Ruan, “Integrated Magnetic for Hybrid Full-Bridge Three-Level LLC Resonant Converter,” ICEMS, pp. 1937 - 1941, 17-20 Oct. 2008.
[19] Ke Jin, and Xinbo Ruan, “Hybrid Full-Bridge Three-Level LLC Resonant Converter- A Novel DC-DC Converter Suitable for Fuel Cell Power System,” PESC, pp. 361 - 367, 16-16 June 2005.
[20] Xiucheng Huang, Jianfeng Wang, Junming Zhang, and Zhaoming Qian, “A Hybrid Driving Scheme for Full-Bridge Synchronous Rectified LLC Resonant DC/DC Converter,” APEC, pp. 579 - 584, 6-11 March 2011.
[21] Yu Chen, Xuejun Pei, Li Peng, and Yong Kang, “A High Performance Dual Output DC-DC Converter Combined the Phase Shift Full Bridge and LLC Resonant Half Bridge with the Shared Lagging Leg,” APEC, pp. 1435 - 1440, 21-25 Feb. 2010.
[22] Ray-Lee Lin, and Chiao-Wen Lin, “Design Criteria for Resonant Tank of LLC DC-DC Resonant Converter,” IECON, pp. 427 - 432, 7-10 Nov. 2010.
[23] Jee-Hoon Jung, Ho-Sung Kim, Jong-Hyun Kim, Myoung-Hyo Ryu, and Ju-Won Baek, “High Efficiency Bidirectional LLC Resonant Converter for 380V DC Power Distribution System Using Digital Control Scheme,” APEC, pp. 532 - 538, 5-9 Feb. 2012.
[24] Wei Chen, Yilei Gu, and Zhengyu Lu, “A Novel Three Level Full Bridge Resonant DC-DC Converter Suitable for High Power Wide Range Input Applications,” APEC, pp. 373 - 379, Feb. 25 2007-March 1 2007.
[25] Cheng-Tao Tsai, Chih-Lung Shen, Jyh-Chau Su, and Ying-Che Kuo, “Analysis and Implementation of An Interleaved ZVS Buck Converter with Coupled-Inductors,” ICIEA, pp. 1392 - 1397, 21-23 June 2011.
[26] Cheng-Tao Tsai, and Chih-Lung Shen, “Interleaved Soft-Switching Buck Converter with Coupled Inductors,” ICSET, pp. 877 - 882, 24-27 Nov. 2008.
[27] Zhong Chen, Miao Chen, Yingpeng Luo, and Lei Shi, “A Family of Shunt Active Filter Based on the Interleaved Buck Switch Cell,” ECCE, pp. 1102 - 1107, 17-22 Sept. 2011.
[28] Il-Oun Lee, Shin-Young Cho, and Gun-Woo Moon, “Interleaved Buck Converter Having Low Switching Losses and Improved Step-Down Conversion Ratio,” ICPE & ECCE, pp. 2136 - 2143, May 30 2011-June 3 2011.
[29] Yao-Ching Hsieh, Yu-Jen Chen, Chin-Sien Moo, and Hung-Liang Cheng, “An Interleaved Twin-Buck Converter with Zero-Voltage-Transition,” ICIT, pp. 1 - 5, 10-13 Feb. 2009.
[30] Bor-Ren Lin, Chau-Shing Wang, Jyun-Ji Chen, and Kun-Liang Shih, “Interleaved PWM Active-Clamping Buck-Type Converter,” IPEC, pp. 68 - 75, 21-24 June 2010.
[31] Ray-Lee Lin, Cheng-Ching Hsu, and Shih-Kuen Changchien, “Interleaved Four-Phase Buck-Based Current Source with Center-Tapped Energy-Recovery Scheme for Electrical Discharge Machining,” APEC, pp. 1536 - 1542, 24-28 Feb. 2008.
[32] Huang-Hua Chiu, Ming-Fa Tsai, Chung-Shi Tseng, and Shu-Yi Yen, “A Novel Interleaved and Isolated Buck Converter with High Voltage Ratio,” IPEC, pp. 2715 - 2721, 21-24 June 2010.
[33] Cheng-Tao Tsai, and Chih-Lung Shen, “Interleaved soft-switching coupled-buck converter with active-clamp circuits,” PEDS, pp. 1113 - 1118, 2-5 Nov. 2009.
[34] Texas Instruments, Inc, “8-Pin Continuous Conduction Mode PFC Controller,” Datasheet, April 2007.
[35] Texas Instruments, Inc, “8-Pin High-Performance Resonant Mode Controller,” Datasheet, September 2008.