高功率雷射源之切換式電源供應器

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姓名

黃子維(Zih-Wei Huang) 查詢紙本館藏

畢業系所

電機工程學系

論文名稱

高功率雷射源之切換式電源供應器
(High-power Laser Switching Power Supply)

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至系統瀏覽論文 ( 永不開放)

摘要(中)

藉由調節輸入雷射二極體電流大小來控制雷射的強度，因此設計可調節電流之電源供應器作為雷射的電源供應即是本論文之目的。透過電源供應器的架構設計，提高能源的轉換效率，縮小電源供應模組的體積，並且能夠同時提供3組獨立雷射機台穩定可調變之電流源。
在本論文的系統架構中包括功率因數修正電路、相移式全橋轉換電路以及降壓型直流轉換電路。升壓型功率因數修正電路採用Texas Instruments公司所生產之型號UCC28180控制晶片，輸入電壓範圍為100~240VAC，輸出390VDC直流電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UCC3895控制晶片，利用相移技術達到零電壓切換之柔性技術。降壓型直流轉換電路中PI控制器則是由運算放大器構成類比控制器，可將單組獨立輸出電流於21.6~32A間進行調節。

摘要(英)

The intensity of the laser is controlled by adjusting the magnitude of the input laser diode current. Therefore, it is the purpose of this thesis to design a power supply with adjustable current for the laser. Through the architecture design of the power supply, the energy conversion efficiency is improved, the volume of the power supply module is reduced, and three sets of independent laser machines can be simultaneously provided with a stable and adjustable current source.
In the system architecture of this thesis, a power factor correction circuit, a phase shift full bridge conversion circuit, and a buck converter are included. The boost power factor correction circuit uses a model UCC28180 control chip manufactured by Texas Instruments, with the input AC voltage range of 100 to 240 V and the output voltage to a phase-shifted full-bridge conversion circuit is DC 390 V. The phase-shifted full-bridge conversion circuit uses a model UCC3895 control chip manufactured by Texas Instruments, and uses a phase shift technique to achieve a zero voltage switching flexible technology. The PI controller in the buck is composed of an operational amplifier to form an analog controller, which can adjust a single independent output current between 21.6 and 32A.

關鍵字(中)

★ 功率因數修正
★ 相移式全橋轉換
★ 降壓型直流轉換電路
★ 柔性切換

關鍵字(英)

★ Power factor corrector
★ Phase-shift full-bridge conversion
★ Buck converter
★ Soft-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 XII
第一章緒論 1
1-1 研究背景與動機 1
1-2 系統架構 3
1-3 論文架構 5
第二章功率因數修正系統 6
2-1 功率因數概念 6
2-2 功率因數修正電路 8
第三章相移式全橋轉換電路 19
3-1柔性切換技術概述 19
3-1-1 切換損失 19
3-1-2 柔性切換技術 20
3-2 相移式全橋轉換電路架構與原理 22
3-2-1 傳統全橋轉換電路 26
3-2-2 相移式全橋轉換電路 30
3-3 整流電路架構 41
第四章直流降壓型電路 46
第五章系統架構設計與研製 56
5-1 相移式全橋轉換電路設計 58
5-1-1 相移式控制晶片UCC3895 58
5-1-2 相移式全橋轉換電路架構 66
5-1-3 功率開關元件選用 68
5-1-4 諧振電感設計 70
5-1-5 高頻變壓器設計 71
5-1-6 整流二極體選用 75
5-1-7 光耦合回授補償電路 77
5-1-8 隔離驅動電路 79
5-2 直流降壓型電路設計 80
5-2-1 直流降壓型電路架構 80
5-2-2 功率元件開關、二極體選用 81
5-2-3 PI回授控制器設計 82
第六章模擬與實驗結果 85
6-1 PSIM模擬 85
6-2 相移式全橋轉換電路實測 88
6-3 直流降壓型電路實測 91
第七章結論與未來研究方向 92
7-1 結論 92
7-2 未來研究方向 93
參考文獻 94
附錄 98

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指導教授

陳正一(Cheng-I Chen)

審核日期

2018-8-23

推文