本論文提出一具有非接觸型串入並出無線線圈半橋LCC諧振電路，以達成使用非接觸式無線線圈對直流負載提供能量，本轉換器電路利用LCC諧振轉換技術，使半橋轉換器能具有零電壓切換之特性，來減少功率開關上的切換損並提高整體電路之效率，且考慮到使用上不可能完全對準設計線圈之中心點，在搭配 LCC諧振電路架構後能夠在一定範圍下容許水平偏移且仍保有零電壓切換之特性。
本轉換器具有以下特點:(1)使用串入並出架構之無線線圈來減少二次側的電流應力，二次側電流保持均衡(2)使用LCC諧振電路使線圈在一定水平移動範圍內仍可保有零電壓切換之特性(3)使用磁感應式能量傳輸(inductively power transfer，IPT)達成無線能量傳輸(4)對整體電路做損耗分析；本文適用於直流負載之非接觸式轉換器，最終經過實驗驗證整體效率曲線高且平緩，線圈在零水平偏移平貼狀態下量測100W上效率80.5%，200W以上效率皆可超過88%，且在1kW的效率點來到90.6%。

The thesis proposes a half-bridge LCC resonant circuit with a contactless serial-in and parallel-out wireless coil to achieve the use of non-contact wireless coils providing energy to DC loads. The converter circuit uses LCC resonance technology to enable the half-bridge converter to have the function of zero voltage switching that can reduce the switching loss on the switch and improve the efficiency of the whole circuit. Considering that it is difficult to align the center of the coil perfectly in use, using LCC resonant circuit can move in a little range and still has the function of zero voltage switching.
This converter has the following characteristics:(1) Use the wireless coil with serial-in and parallel-out architecture to reduce the current stress on the secondary side, and the current of secondary side can remain balanced. (2) Use LCC resonant circuit to make the coil still maintain the function of zero voltage switching when having a little horizontal movement range. (3) Use inductive power transfer (IPT) to achieve wireless energy transfer. The thesis is applicable to the non-contact converter of DC load. Finally, the overall efficiency curve is presented high and smooth by the experiment. Besides the efficiency of the coil in 100W is 80.5% under the state of zero horizontal offset, The efficiency all may surpass 88% above 200W, and the efficiency in 1kW can reache 90.6%.

摘要…………i
Abstract………ii
誌謝………iii
目錄………iv
表目錄………vi
圖目錄………vii
第一章 緒論………1
1.1研究動機與目的………1
1.2文獻探討………1
1.3內容架構………3
第二章 無線能量傳輸研究………4
2.1無線能量傳輸發展………4
2.1.1無線能量傳輸技術介紹………4
2.1.2無線能量傳輸對健康探討………4
2.2無線能量傳輸種類………4
2.2.1磁感應式無線能量傳輸………5
2.2.2磁共振式無線能量傳輸………6
2.2.3電場耦合式無線能量傳輸………7
2.2.4微波諧振式無線能量傳輸………7
2.3鬆散耦合變壓器架構分析與比較………8
2.3.1鬆散耦合變壓器建模與分析………8
2.3.2串入並出鬆散耦合變壓器架構設計………15
第三章 轉換器架構與分析………20
3.1隔離型轉換器………20
3.1.1半橋轉換器架構………20
3.1.2全橋轉換器架構………21
3.2諧振轉換器………21
3.2.1CLC-T型諧振轉換器介紹與分析………21
3.2.2LLC串並聯諧振轉換器介紹與分析………26
3.2.3LCC串並聯諧振轉換器介紹與分析………29
第四章 半橋LCC諧振轉換器操作模式與分析………33
4.1雙串入並出無線線圈半橋LCC諧振轉換器架構分析………33
4.2無線能量傳輸串入並出LCC諧振動作原理分析………33
第五章 電路設計流程與實驗結果………39
5.1轉換器設計流程………39
5.2電路實驗波形與效率曲線圖………45
5.2.1發射/接收線圈於水平零偏移下的波形圖………45
5.2.2發射/接收線圈於水平零偏移下的效率圖………48
5.2.3水平偏移下的波形圖………49
5.2.4水平偏移下的效率圖………55
5.2.5垂直偏移下的波形圖………56
5.2.6垂直偏移下的效率圖………60
5.3電路元件損耗計算………61
5.3.1在1kW下各元件的損耗分析………61
5.3.2在100W下各元件的損耗分析………67
第六章 結論與未來展望………70
6.1結論………70
6.2研究展望………70
參考文獻………71

楊子弘，“短弧氙燈續弧特性與電子安定器之研究”，國立虎尾科技大學電機工程系碩士論文，民國一百零二年七月。
楊大為，“應用於非接觸型充電器的LLC半橋轉換器之研製”，中原大學電機工程系碩士論文，民國九十九年七月
黃永宏，“半橋諧振電容式LLC轉換器之分析與研製”，國立成功大學電機工程系碩士論文，民國一百零二年六月。
S. Jeong, Y. J. Jang, D. Kum and M. S. Lee, "Charging Automation for Electric Vehicles: Is a Smaller Battery Good for the Wireless Charging Electric Vehicles?," in IEEE Transactions on Automation Science and Engineering, vol. 16, no. 1, pp. 486-497, Jan. 2019, doi: 10.1109/TASE.2018.2827954.
陳信銘，“旋轉式感應耦合結構於可旋型非接觸式電能傳輸系統之研究”，國立成功大學電機工程系碩士論文，民國一百零三年六月。
S. Li and C. C. Mi, "Wireless Power Transfer for Electric Vehicle Applications," in IEEE Journal of Emerging and Selected Topics in Power Electronics, vol. 3, no. 1, pp. 4-17, March 2015, doi: 10.1109/JESTPE.2014.2319453.
C. Liu, C. Jiang and C. Qiu, “Overview of coil designs for wireless charging of electric vehicle,” in Proc. IEEE PELS Workshop Emerg. Technologies: Wireless Power Transfer, Chongqing, China, 2017, pp. 1–6.
K. Aditya and S. S. Williamson, “Design guidelines to avoid bifurcation in a series–series compensated inductive power transfer system,” IEEE Trans. Ind. Electron., vol. 66, no. 5, pp. 3973–3982, May 2019.
Y. Li, T. Lin, R. Mai, L. Huang, and Z. He, “Compact double-sided decoupled coils based WPT systems for high power applications: Analysis, design and experimental verification,” IEEE Trans. Transp. Electrific., vol. 4, no. 1, pp. 64–75, Mar. 2018.
[10]P.-P. Ding, L. Bernard, L. Pichon, and A. Razek, “Evaluation of electromagnetic fields in human body exposed to wireless inductive charging system,” IEEE Trans. Mag., vol. 50, no. 2, pp. 1037–1040, Feb. 2014.
J. B. Lee, J. I. Baek, H. S. Youn, C. O. Yeon, C. Y. Lim and G. W. Moon, "A high efficiency half-bridge LLC converter with simple hold-up compensation circuit," 2015 9th International Conference on Power Electronics and ECCE Asia (ICPE-ECCE Asia), Seoul, 2015, pp. 227-232, doi: 10.1109/ICPE.2015.7167791.
J. Wang, M. Hu, C. Cai, Z. Lin, L. Li, and Z. Fang, ‘‘Optimization design of wireless charging system for autonomous robots based on magnetic resonance coupling,’’ AIP Adv., vol. 8, no. 5, p. 055004, 2018.
X. Wang, Y. Wang, G. Fan, Y. Hu, X. Nie and Z. Yan, "Experimental and Numerical Study of a Magnetic Resonance Wireless Power Transfer System Using Superconductor and Ferromagnetic Metamaterials," in IEEE Transactions on Applied Superconductivity, vol. 28, no. 5, pp. 1-6, Aug. 2018, Art no. 1800206, doi: 10.1109/TASC.2018.2825305.
A. Kurs et al., “Wireless power transfer via strongly coupled magnetic resonances,” Science, vol. 317, no. 5834, pp. 83–86, Jun. 2007.
J. O. Mur-Miranda et al., “Wireless power transfer using weakly coupled magnetostatic resonators,” in Proc. IEEE ECCE, Atlanta, GA, USA,Sep. 2010, pp. 4179–4186.
E. Culurciello and A. G. Andreou, “Capacitive inter-chip data and power transfer for 3-D VLSI,” Circuits and Systems II: Express Briefs, IEEE Transactions on, vol. 53, no. 12, pp. 1348–1352, Dec. 2006.
A. M. Sodagar and P. Amiri, "Capacitive coupling for power and data telemetry to implantable biomedical microsystems," 2009 4th International IEEE/EMBS Conference on Neural Engineering, Antalya, 2009, pp. 411-414, doi: 10.1109/NER.2009.5109320.
M. Kline, I. Izyumin, B. Boser, and S. Sanders, “Capacitive power transfer for contactless charging,” in Proc. IEEE Appl. Power Electron. Conf. Expo., Fort Worth, TX, USA, Mar. 2011, pp. 1398–1404.
S. Yoshida, N. Hasegawa, Y. Kobayashi, A. Miyachi, H. Sakaki, K. Nishikawa, Y. Moriguchi, S. Furuta, C. Maekawa, I. Urushibara, and S. Kawasaki, "Wireless Sensor Network System with Wireless Powering by Time Division Operation at 5.8 GHz in a Reusable Rocket," Proc. iEEE RFiT 2015, Sendai, Japan, Aug. 2015.
S. Ishino, Y. Takimoto, A. Kishimoto, Y. Huang, N. Shinohara, and S. Kato, "Study on WPT System Using a Radio Wave Hose as a New Transmission Line," Proc. iEEE WPTC 2015, CO, USA, May 2015.
S. Ishino, I. Takano, K. Yano and N. Shinohara, "Frequency-division techniques for microwave power transfer and wireless communication system with closed waveguide," 2016 IEEE Wireless Power Transfer Conference (WPTC), Aveiro, 2016, pp. 1-4, doi: 10.1109/WPT.2016.7498769..
Q. Huang, L. Dong and L. Wang, "LC Passive Wireless Sensors Toward a Wireless Sensing Platform: Status, Prospects, and Challenges," in Journal of Microelectromechanical Systems, vol. 25, no. 5, pp. 822-841, Oct. 2016, doi: 10.1109/JMEMS.2016.2602298.
Sheng-Yuan Ou, Ho-Pu Hsiao and Chen-Hung Tien, "Analysis and design of a prototype single-stage half-bridge power converter," 2010 5th IEEE Conference on Industrial Electronics and Applications, Taichung, 2010, pp. 1168-1173, doi: 10.1109/ICIEA.2010.5515882.
G. F. W. Khoo, D. R. H. Carter and R. A. McMahon, "Comparison of charge pump circuits for half-bridge inverters," in IEE Proceedings - Circuits, Devices and Systems, vol. 147, no. 6, pp. 356-362, Dec. 2000, doi: 10.1049/ip-cds:20000690.
M. L. Heldwein, A. Ferrari de Souza and I. Barbi, "A primary side clamping circuit applied to the ZVS-PWM asymmetrical half-bridge converter," 2000 IEEE 31st Annual Power Electronics Specialists Conference. Conference Proceedings (Cat. No.00CH37018), Galway, Ireland, 2000, pp. 199-204 vol.1, doi: 10.1109/PESC.2000.878838.
C. Lee and C. Leu, "A novel soft-switching full-bridge converter," 2009 International Conference on Power Electronics and Drive Systems (PEDS), Taipei, 2009, pp. 993-996, doi: 10.1109/PEDS.2009.5385858.
B. A. Gusev, V. I. Meleshin and D. A. Ovchinnikov, "Transformer Core Unbalancing Issue in a Full-Bridge DC-DC Converter with Current Doubler Rectifier," 2006 International Conference on Power Electronic, Drives and Energy Systems, New Delhi, 2006, pp. 1-6, doi: 10.1109/PEDES.2006.344409.
M. Jiang, S. Perng, C. Wang, T. Wu, C. Ke and J. Jhan, "Analysis and design of a novel single-phase full-bridge soft-switching rectifier," 2009 International Conference on Power Electronics and Drive Systems (PEDS), Taipei, 2009, pp. 1249-1254, doi: 10.1109/PEDS.2009.5385731.
P. D. Teodosescu, M. Bojan and R. Marschalko, "Resonant LED driver with inherent constant current and power factor correction," in Electronics Letters, vol. 50, no. 15, pp. 1086-1088, 17 July 2014, doi: 10.1049/el.2014.1701.
C. -. Cheng, H. -. Cheng, F. -. Yang and C. -. Ku, "Single-stage driver for supplying high-power light-emitting-diodes with universal utility-line input voltages," in IET Power Electronics, vol. 5, no. 9, pp. 1614-1623, November 2012, doi: 10.1049/iet-pel.2011.0478.
A. J. Gilbert, C. M. Bingham, D. A. Stone and M. P. Foster, "Normalized Analysis and Design of LCC Resonant Converters," in IEEE Transactions on Power Electronics, vol. 22, no. 6, pp. 2386-2402, Nov. 2007, doi: 10.1109/TPEL.2007.909243.
A. Kamineni, G. A. Covic, and J. T. Boys, “Analysis of coplanar intermediate coil structures in inductive power transfer systems,” IEEE Trans. Power Electron., vol. 30, no. 11, pp. 6141–6154, Nov. 2015.
Y. Yang, "A half-bridge LLC resonant converter with loose-coupling transformer and transition capacitor," 2014 9th IEEE Conference on Industrial Electronics and Applications, Hangzhou, 2014, pp. 1344-1349, doi: 10.1109/ICIEA.2014.6931377.
R. Lin and C. Lin, "Design criteria for resonant tank of LLC DC-DC resonant converter," IECON 2010 - 36th Annual Conference on IEEE Industrial Electronics Society, Glendale, AZ, 2010, pp. 427-432, doi: 10.1109/IECON.2010.5674988.
J. B. Lee, J. I. Baek, H. S. Youn, C. O. Yeon, C. Y. Lim and G. W. Moon, "A high efficiency half-bridge LLC converter with simple hold-up compensation circuit," 2015 9th International Conference on Power Electronics and ECCE Asia (ICPE-ECCE Asia), Seoul, 2015, pp. 227-232, doi: 10.1109/ICPE.2015.7167791.
Y. Shen, W. Zhao, Z. Chen and C. Cai, "Full-Bridge LLC Resonant Converter With Series-Parallel Connected Transformers for Electric Vehicle On-Board Charger," in IEEE Access, vol. 6, pp. 13490-13500, 2018, doi: 10.1109/ACCESS.2018.2811760.
EI40, Mn-Zn Ferrite Cores for Switching Power Supplies EI series, Datasheet, TDK Product Center, 2014.
C3M0065090D, Silicon Carbide Power MOSFET, Datasheet, CREE, 2019.
AT2300, Mn-Zn Ferrite Cores for Wireless Charging, A&T, 2020.
STPS30170C, High voltage power Schottky rectifier, STMicroelectronics,2015.
Elektrisola。利茲線的技術基礎與計算。Retrieved June 20, 2020, from http://www.familymealtime.org:https://www.elektrisola.com/cn/hf-litz-wire/products/terminology-basics/technical-basics-and-calculation.html
吳義利，2015年，切換式電源轉換器原理與實用設計技術(實例設計導向)，第二版，文笙書局股份有限公司。