高效率通訊設備電源模組之研製

、線上人數：79

、訪客IP：3.144.252.140

姓名	張千謹(Chien-Chin Chang) 查詢紙本館藏	畢業系所	通訊工程學系
論文名稱	高效率通訊設備電源模組之研製 (Design and Implementation of a Communication Equipment Power Module with High Efficiency)
檔案	[Endnote RIS 格式] [Bibtex 格式] [相關文章] [文章引用] [完整記錄] [館藏目錄] 至系統瀏覽論文 (2029-2-1以後開放)
摘要(中)	本論文主要的目的為研製一款高效率的通訊設備電源模組，擁有高效率及高功率密度的體積的優勢，透過模組化設計，可縮短整體系統體積及開發時程，對於小型通訊基站架設可帶來更好的便利性。本論文的系統架構，由兩級電路所組成包含第一級的功率因數修正電路，第二級的相移式全橋轉換電路。交錯式升壓型功率因數修正電路採用Texas Instruments公司所生產之型號UCC28070A控制晶片，輸入電壓範圍為90~264VAC，利用雙相交錯技術達到功率因數修正的目的，輸出390VDC直流電壓至相移式全橋轉換電路。相移式全橋轉換電路採用Texas Instruments公司所生產之型號UCC28950控制晶片，利用相移技術達到零電壓切換之柔性技術及同步整流技術，可有效降低損失，進而提升整機效率。最後實驗結果可驗證本論文所研製之電源模組，於交流穩壓電源的輸入交流電壓90~264VAC，功率因數修正電路輸出為390VDC，相移式全橋轉換器輸出為48VDC，且最大輸出功率為1.6kW，而230VAC輸入時在滿載的條件下整體效率為94.7%，高效率通訊設備電源模組得以驗證。
摘要(英)	The main purpose of this paper is to develop a high-efficiency communication equipment power module, which has the advantages of high efficiency and high power density. Through modular design, the overall system volume and development time can be shortened. For small communications Base station erection can bring better convenience. The system architecture of this paper is composed of two-stage circuits, including the first-stage power factor correction circuit and the second-stage phase-shifted full-bridge conversion circuit. The interleaved boost power factor correction circuit uses the model UCC28070A control chip produced by Texas Instruments. The input voltage range is 90~264VAC. It uses two-phase interleaved technology to achieve the purpose of power factor correction and outputs 390VDC DC voltage to a phase-shifted full Bridge conversion circuit. The phase-shifted full-bridge conversion circuit uses the model UCC28950 control chip produced by Texas Instruments. It uses phase-shift technology to achieve zero-voltage switching, flexible technology and synchronous rectification technology, which can effectively reduce losses and improve the efficiency of the entire machine. The final experimental results can verify that the power module developed in this paper has an input AC voltage of 90~264VAC in the AC regulated power supply, the output of the power factor correction circuit is 390VDC, the output of the phase-shifted full-bridge converter is 48VDC, and the maximum output power It is 1.6kW, and the overall efficiency under full load conditions is 94.7% when inputting 230VAC. The high-efficiency communication power module has been verified.
關鍵字(中)	★ 通訊設備 ★ 交錯式功率因數修正器 ★ 相移式全橋轉換器 ★ 柔性切換 ★ 零電壓切換	關鍵字(英)	★ Communication Equipment ★ Interleaved Power Factor Corrector ★ Phase-Shifted Full-Bridge Converter ★ Soft Switching ★ Zero Voltage Switching
論文目次	論文摘要 I ABSTRACT II 致謝 III 目錄 IV 圖目錄 VII 表目錄 X 第一章緒論 1 1-1研究背景與動機 1 1-2論文架構 4 第二章文獻回顧 5 2-1功率因數概念 5 2-2功率因數修正電路之種類 7 2-2-1被動式功率因數修正器 7 2-2-2主動式功率因數修正器 8 2-3功率因數修正器操作模式與控制方法 9 2-3-1功率因數修正器操作模式 9 2-3-2 功率因數修正器控制方法 10 2-4硬性切換技術及柔性切換技術之差異 13 2-4-1硬性切換技術 13 2-4-2柔性切換技術 14 2-4-3硬性與柔性切換時電壓及電流波形之軌跡 14 2-4-4零電壓切換(ZVS)及零電流切換(ZCS)之定義 15 2-5相移式全橋轉換電路架構與工作原理分析 15 2-5-1相移式全橋轉換電路架構 15 2-5-2相移式全橋轉換電路工作原理分析 17 2-6整流電路架構 22 2-6-1半波整流電路 22 2-6-2全橋整流電路 22 2-6-3中間抽頭式整流電路 23 2-6-4 倍流整流電路 24 第三章本論文所提轉換器的相關內容介紹 25 3-1文獻架構 25 3-2系統架構 28 第四章系統架構實例設計與考量 30 4-1 功率因數修正電路設計 32 4-1-1 功率因數修正電路控制晶片UCC28070A 32 4-1-2 功率因數修正電路設計考量 40 4-1-3功率因數修正電路元件選用 45 4-2相移式全橋轉換電路設計 49 4-2-1相移式全橋轉換電路控制晶片UCC28950 49 4-2-2相移式全橋轉換電路架構 58 4-2-3相移式全橋轉換電路設計考量 59 4-2-4相移式全橋轉換電路元件選用 65 第五章電路模擬與實驗結果 70 5-1-1功率因數修正電路模擬之波形 70 5-1-2模擬相移式全橋轉換電路之波形 73 5-2實際電路量測 78 5-2-1功率因數修正電路量測 79 5-2-2相移式全橋轉換電路量測 80 5-3整體系統效率之量測結果 84 5-4整機Layout示意圖 85 第六章結論與未來研究方向 86 6-1結論 86 6-2未來研究方向 87 參考文獻 88
參考文獻	[1]G. Hua and F. C. Lee, “Soft-switching techniques in PWM converters,” IEEE Transactions on Industrial Electronics, Vol. 42, pp. 595-603, 1995. [2]Raymond A. Mack, Jr, Demystifying switching power supplies, Newnes. , 2005. [3]J. G. Cho, J. A. Sabate, and F. C. Lee, “Novel full bridge zero-voltage-transition PWM DC/DC converter for high power applications,” IEEE APEC, pp.143-149,1994. [4]C. M. Wang, “A new family of zero-current-switching (ZCS) PWM converter,” IEEE Transactions on Power Electronics, vol. 52, no. 4, pp. 1117-1125, Aug. 2005. [5]梁適安，高頻交換式電源供應器原理與設計，第二版，全華圖書，2016。 [6]梁適安，交換式電源供給器之理論與實務設計，第三版，全華圖書，2018。 [7]Y. Geng, Y. Liu, J. Chen, P. Luo, “Analysis and design of a predictive CCM power factor correction converter,” in Proc. IEEE ICCCAS, vol. 2, pp. 398-401, Chengdu, November. 2013. [8]Gandhi B, M. Ezhilmaran, “Achieving high input power factor for DCM boost PFC converters by controlling variable duty cycle,” in Proc. IEEE ICCPEIC, pp. 18-20, Chennai, April. 2013. [9]S. P. Yang, S. J. Chen, C. M. Huang, “Small-signal modeling and controller design of BCM boost PFC converters,” in Proc. IEEE ICIEA, pp. 1096-1101, Singapore , July. 2012. [10]L. Rosseto, G. Spiazzi, P. Tenti, “Control techniques for power factor correction converters,” Proc. PEMC’94, 1994. [11]X. K. Wu, J. M. Zhang, X. Ye, and Z. M. Qian, “Analysis and derivations for a family ZVS converter based on a new active clamp ZVS cell,” IEEE Trans. Ind. Electron., vol. 52, no. 2, pp. 773-781, 2008. [12]F. T. Wakabayashi and C. A. Canesin, “Improvements for ZCS-PWM commutation cell in high-power-factor preregulator application,” IEE Proc. -Electr. Power Appl., vol. 153, no. 2, pp. 247-254, 2006. [13]Jae-Bum Lee, Ki-Bum Park, Hyoung-Suk Kim, “ZVS half-bridge zeta converter with center-tapped rectifier,” IEEE, July 2011. [14]Laszlo Huber, Milan M. Jovanović, “Performance evaluation of synchronous rectification in front-end full-bridge rectifiers,” IEEE Applied Power Electronics Conference and Exposition, March 2012 [15]UCC28070A, Datasheet, Texas Instruments, May 2016. [16]IPW60R120P7, Datasheet, Infineon Technologies, May 2018. [17]TRS8A65F, Datasheet, TOSHIBA, September 2020. [18]Powder Core Catalog, Magnetics, 2017. [19]Magnetic powder cores, Chang Sung Corporation, from https://www.changsung.com [20]C058894A2, Datasheet, Magnetics, January 2022. [21]UCC28950, Datasheet, Texas Instruments, November 2016. [22]SLUA56D, Datasheet, Texas Instruments, March 2022. [23]黃子維，高功率雷射源之切換式電源供應器，國立中央大學電機工程學系碩士論文，中華民國106年6月。 [24]IPW60R090CFD7, Datasheet, Infineon Technologies, February 2018. [25]IXTH60N20X4, Datasheet, IXYS Corporation, 2021. [26]Material characteristics for PC95, Datasheet, TDK Corporation, May 2022. [27]Ferrite Cores for PQ series, Datasheet, TDK Corporation, March 2014. [28]C058071A2, Datasheet, Magnetics, October 2021.
指導教授	胡誌麟陳正一(Chih-Lin Hu Cheng-I Chen)	審核日期	2024-1-25
推文	facebook plurk twitter funp google live udn HD myshare reddit netvibes friend youpush delicious baidu
網路書籤	Google bookmarks del.icio.us hemidemi myshare

博碩士論文 109553007 詳細資訊