研究生: |
洪紹輔 Shao-fu Hung |
---|---|
論文名稱: |
3 kW鋰電池充電器研製 Study and Implementation of a 3 kW Charger for Li-ion Battery |
指導教授: |
羅有綱
Yu-kang Lo 邱煌仁 Huang-Jen Chiu |
口試委員: |
林景源
Jing-yuan Lin |
學位類別: |
碩士 Master |
系所名稱: |
電資學院 - 電子工程系 Department of Electronic and Computer Engineering |
論文出版年: | 2014 |
畢業學年度: | 102 |
語文別: | 中文 |
論文頁數: | 116 |
中文關鍵詞: | 交錯式功因修正器 、全橋串聯諧振轉換器 、定電流/定電壓充電 |
外文關鍵詞: | constant-current/constant-voltage charging, full-bridge series resonant converter, Power factor corrector |
相關次數: | 點閱:418 下載:17 |
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本文目的在於研究並實作出一台3 kW鋰離子電池充電器,前級採用兩相交錯式升壓型功因修正器以提升功率因數、降低輸入電流漣波並縮小EMI濾波器體積。後級採用全橋式串聯諧振轉換器和降壓型轉換器,前者實現零電壓及零電流切換技術,降低切換損失提高效率,並具輸入及輸出的電氣隔離;後者降壓型轉換器包含定電流控制迴路及定電壓控制迴路實現鋰電池充電。本文最後成功實現了一組輸入交流電壓340 V~440 V,額定功率為3 kW,88.8 V輸出電壓的充電器,滿載效率達92%。
This thesis presents the study and Implementation of a 3-kW charger for Li-ion battery. The front stage is a two-phase interleaved boost power factor corrector (PFC) circuit to achieve high power factor, low input current ripple and decrease the volume of EMI filter. The second stage consists of a full-bridge series resonant converter (FB-SRC) and a buck converter. The former achieves zero-voltage switching (ZVS) so that the power switch loss can be reduced and the efficiency can be improved. In addition, it also has electrical isolation between input and output. The battery charger with both constant-current and constant-voltage control loops is fulfilled by a buck converter. Finally, a charge with rated power of 3 kW, AC input voltage from 340 V to 440 V, and an output voltage of 88.8V is implemented and tested. The measured peak efficiency is up to 92 %.
參考文獻
[1] C. C. Hua and M. Y. Lin, “A Study of Charging Control of Lead-acid Battery for Electric Vehicles,” ISIE 2000, pp. 135-140.
[2] R. C. Cope and Y. Podrazhansky, “The Art of Battery Charging,” BCAA 1999, pp. 233-235.
[3] S. Harrington and J. Dunlop, “Battery Charge Controller Characteristics in Photovoltaic Systems,” IEEE Aerospace Electronics System Magazine, vol. 7, no. 8, pp. 15-21, Aug. 1992.
[4] T. S. Mundra and A. Kumar “An Innovative Battery Charger for Safe Charging of NiMH/NiCd Batteries,” IEEE Transactions on Consumer Electronics, vol. 53, no. 3, pp. 1044-1052, Aug. 2007.
[5] F. Boico, B. Lehman, and K. Shujaee, “Solar Battery Chargers for NiMH Batteries,” IEEE Transactions on Power Electronics, vol. 22, no. 5, pp. 1600-1609, Sept. 2007.
[6] M. Gonzdez, F. J. Ferrero, J. C. Antbn, and M. A. Pkez “Considerations to Improve the Practical Design of Universal and Full-Effective NiCd/NiMH Battery Fast Chargers,” APEC 1999, pp. 167-173.
[7] J. Diaz, J. A. Martin-Ramos, A. M. Pernia, F. Nuno, and F. F. Linera, “Intelligent and Universal Fast Charger for NiCd and NiMH Batteries in Portable Applications,” IEEE Transaction on Industrial Electronics, vol. 51, no. 4, pp. 857-863, Aug. 2004.
[8] Y. S. Wong, W. G. Hurley, and W. H. Wolfle, “Temperature Compensation Algorithm for Interrupted Charge Control Regime for a VRLA Battery in Standby Applications,” APEC 2008, pp. 1278-1283.
[9] 梁適安,高頻交換式電源供應器原理與設計,第二版,台北:全華圖書,1995年。(原著 G. Chryssis, 1984)
[10] 梁適安,交換式電源供給器之理論與實務設計,第二版,台北:全華圖書,2008年。
[11] EPARC,電力電子學綜論,第二版,台北:全華圖書,2008年。
[12] T. Ishii and Y. Mizutani, “Power Factor Correction Using Interleaving Technique for Critical-Mode Switching Converter,” PESC 1998, pp. 905-910.
[13] P. W. Lee, Y. S. Lee, D. K. W. Cheng, and X. C. Liu, “Steady-State Analysis of an Interleaved Boost Converter with Coupled Inductor,” IEEE Transactions on Industrial Electronic, vol. 47, no. 4, pp. 787-795, Aug. 2000.
[14] J. R. Pinheiro, H. A. Grundling, D. L. R. Vidor, and J. E. Baggio, “Control Strategy of an Interleaved Boost Power Factor Correction Converter,” PESC 1999, pp. 137-142.
[15] H. G. Lei, X. J. Yang, H. L. Miao, and P. S. Ye, “Power Switch Deiving Techniques in Single-Phase Dual-Parallel Interleaved Boost PFC,” PEDS 2003, pp. 1086-1089.
[16] R. Teodorescu, S. B. Kjaer, and S. Munk-Nielsen, F. Blaabjerg, “Comparative Analysis of Three Interleaved Boost Power Factor Corrected Topologies in DCM,” PESC 2001, pp. 3-7.
[17] T. W. Heo, Y. D. Son, and E. Santi, “Analysis of the Interleaved Type Power Factor Correction Converter in Discontinuous Current Mode,” IECON 2004, pp. 2706-2711.
[18] M. Veerachary, T. Senjyu, and K. Uezato, “Modeling and Analysis of Interleaved Dual Boost Converter,” ISIE 2001, pp. 718-722.
[19] C. S. Babu and M. J. Veerachary, “Predictive Controller for Interleaved Boost Converter” ISIE 2005, pp. 577-581.
[20] R. Martinez and P. N. Enjeti, “A High-Performance Single-Phase Rectifier with Input Power Factor Correction,” IEEE Transactions on Power Electronics, vol. 11, no. 2, pp. 311-317, Mar. 1996.
[21] O. Garcia, J. A. Cobos, R. Prieto, P. Alou, and J. Uceda, “Single Phase Power Factor Correction:A Survey,” IEEE Transactions on Power Electronics, vol. 18, no 3, pp. 749-754, May 2003.
[22] C. S. Lin, T. M. Chen, and C. L. Chen, “Analysis of Low Frequency Harmonics for Continuous-Conduction-Mode Boost Power-Factor Correction,” IEE Proc. Electric Power Applicat., vol. 148, no. 2, pp. 202-206, Mar. 2001.
[23] J. S. Lai and D. Chen, , “Design Consideration for Power Factor Correction Boost Converter Operating at the Boundary of Continuous Conduction Mode and Discontinuous Conduction Mode,” APEC 1993, pp. 267-273.
[24] D. S. Chen and J. S. Lai, “A Study of Power Correction Boost Converter Operating at CCM-DCM Mode,” IEEE Southeastcon, 1993.
[25] J. Luo, M. K. Jeoh, and H. C. Huang, “A New Continuous Conduction Mode PFC IC with Average Current Mode Control,” PEDS 2003, pp. 1110-1114.
[26] S. Kim and P. N. Enjeti, “A Modular Single-Phase Power Factor Correction Scheme With a Harmonic Filtering Function,” IEEE Transactions on Industrial Electronics, vol. 50, no. 2, pp. 328-335, Apr. 2003.
[27] Texas Instruments Inc., “Using the UCC28070EVM,” User's Guide, 2008.
[28] Texas Instruments Inc., “Interleaving Continuous Conduction Mode PFC Controller (UCC28070),” Datasheet, 2008.
[29] Texas Instruments Inc., “Designing Switching Voltage Regulators With the TL494,” Datasheet, 2004.
[30] ST Microwlwctronics, “L6561, Enhanced Transition Mode Power Factor Corrector,” Application Note, AN966, Mar. 2003.
[31] P. C. Toff, “UC3854 Controlled Power Factor Correction Circuit Design,” Application Note, U-134.
[32] Texas Instruments Inc., “Dual Operational Amplifiers,” Datasheet, May 2013.
[33] Texas Instruments Inc., “Differential Comparaotrs with Strobes,” Datasheet, Aug. 2003.
[34] K. C. Tseng, T. J. Liang, J. F. Chen, and M. T. Chang, “High Frequency Positive/Negative Pulse Charger with Power Factor Correction,” PESC 2002, pp. 671-675.
[35] P. H. Cheng and C. L. Chen, “A High-Efficiency Fast Charger for Lead-Acid Batteries,” IECON 2002, pp. 1410-1415.