磁共振式無線功率傳輸系統之線圈及鐵氧體設計與分析

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姓名

陳淑郡(Shu-Chun Chen) 查詢紙本館藏

畢業系所

電機工程學系

論文名稱

磁共振式無線功率傳輸系統之線圈及鐵氧體設計與分析
(Design and Analysis of Coil and Ferrite for Magnetic Resonance Wireless Power Transmission System)

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摘要(中)

本論文旨在設計無線功率傳輸系統之線圈與鐵氧體，首先透過磁共振式無線功率傳輸之等效電路，推得傳輸效率與各參數的關係，加上分析線圈參數對傳輸效能的影響，接續進行線圈設計，再利用電磁模擬軟體(Maxwell)及先進設計系統(ADS)進行模擬分析和驗證，以確認線圈之間的傳輸效果。根據推論可得知加裝鐵氧體的必要性，可以有效限制磁力線的範圍、減少漏磁、降低電磁干擾，最後根據無線功率傳輸的使用需求進行鐵氧體形狀的設計，使得傳輸效率可以有效提升。

摘要(英)

The purpose of this paper is to design coils and ferrites for wireless power transmission system. First, through the equivalent circuit of magnetic resonance wireless power transmission, the relationship between transmission efficiency and various parameters are derived, and analyze the influence of the coil’s parameters on transmission performance. Continue to design the coils, use electromagnetic simulation software (Maxwell) and Advanced Design System (ADS) for simulations and verifications, and confirm the transmission efficiency between the coils afterwards. According to the inference, it can be known that the necessity of installing the ferrites, it can effectively limit the range of magnetic flux, reduce magnetic flux leakage and reduce electromagnetic interference. Finally, design the ferrite shapes according to the usage requirements of wireless power transmission so that the transmission efficiency can be improve effectively.

關鍵字(中)

★ 無線功率傳輸
★ 線圈
★ 鐵氧體

關鍵字(英)

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 1
1-2 無線功率傳輸方式概述 2
1-3 無線功率傳輸技術之國內外研究情況 5
1-4 研究方法與目的 8
第二章無線功率傳輸之原理與特性 9
2-1 無線功率傳輸裝置之構成 9
2-2 等效電路模型分析 10
2-3 非理想效應 11
2-3-1 集膚效應 12
2-3-2 鄰近效應 14
2-4 共振電路分析 16
2-4-1 SS補償架構 17
2-4-2 SP補償架構 21
2-4-3 PP補償架構 22
2-4-4 PS補償架構 23
2-4-5補償結構的比較與選擇 24
第三章線圈與鐵氧體之設計與分析 26
3-1 線圈特性分析 26
3-1-1 線圈常用結構 26
3-1-2 耦合係數的影響 27
3-1-3 品質因數的影響 29
3-2 鐵氧體之設計與分析 33
3-2-1 屏蔽方式之比較與選擇 33
3-2-2 加入鐵氧體的必要性 34
3-2-3 鐵氧體之設計 38
3-3 改善線圈錯位問題 40
3-4 結論 44
第四章無線功率傳輸之線圈參數設計與驗證 45
4-1無線功率傳輸線圈設計 45
4-1-1 系統等效電路 45
4-1-2 平面螺旋線圈參數 46
4-1-3 線圈設計 48
4-2 系統模擬驗證 53
4-3 結論 56
第五章無線功率傳輸之鐵氧體設計與比較 57
5-1 Case 1：未加入鐵氧體 57
5-2 Case 2：一般型鐵氧體 59
5-3 Case 3：U型鐵氧體 65
5-4 Case 4：米型鐵氧體 67
5-5 Case 5：各式鐵氧體加入中柱 69
第六章結論與未來研究方向 73
6-1 結論 73
6-2 未來研究方向 74
參考文獻 75

參考文獻

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指導教授

陳正一(Cheng-I Chen)

審核日期

2018-8-17

推文