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研究生:王邇竣
研究生(外文):WANG, ER-CHUN
論文名稱:手機充電使用高頻段微波轉電微小能量擷取並升壓與儲能技術之研發
論文名稱(外文):The Implementation of Low Energy Harvesting, Boosting and Energy-Storing Technologies for High-Frequency Microwave-Transformed-Electricity applied on Mobile Phone Charging.
指導教授:王欽戊
指導教授(外文):WANG, CHING-WU
口試委員:周卓煇林正亮陳政裕王欽戊
口試委員(外文):JOU, JWO-HUEILIN, JENG-LIANGCHENG, JENG-YUEWANG, CHING-WU
口試日期:2021-07-27
學位類別:碩士
校院名稱:國立中正大學
系所名稱:機械工程系研究所
學門:工程學門
學類:機械工程學類
論文種類:學術論文
論文出版年:2021
畢業學年度:109
語文別:英文
論文頁數:59
中文關鍵詞:低能量擷取微波轉電升壓電路手機充電
外文關鍵詞:low energy harvestingwave-transformed-electricitybooster circuitmobile phone charging
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本論文已完成『手機充電使用高頻段微波轉電微小能量擷取並升壓與儲能技術之研發』。首先,本論文利用8W微波發射器發射微波,經由十六木微帶天線接收微波,再透過阻抗匹配電路及倍壓整流濾波電路將微波轉成直流電;緊接著透過兩階段的升壓與儲能電路,即可成功對手機進行充電。本論文在儲能電池充電實驗的結果顯示,儲能電池透過波轉電及第一階段升壓儲能電路充電160分鐘後,儲能電池電壓會從1.12V上升至1.15V。此外,在手機充電實驗結果顯示,1.15V的儲能電池透過第二階段升壓電路後可對手機充電持續54秒,實驗證明整體裝置使用微小能量擷取、及適當的升壓和儲能技術可以成功對手機實現隔空充電。
This thesis has completed “The Implementation of Low Energy Harvesting, Boosting and Energy-Storing Technologies for High-Frequency Microwave-Transformed-Electricity Applied on Mobile Phone Charging”. In the beginning, the 8W microwave transmitter transmitted microwaves. The antenna adding with 16-directors was applied to receive the microwaves at the receiver. The impedance matching circuit and the voltage doubler rectifier filter circuit were added after the antenna converted the microwaves into direct current. Thereafter, the direct current through the operation of the two-stage booster and energy storage circuit could charge the mobile phone successfully. The experiment of charging energy storage battery showed that the voltage of energy storage battery could be charged from 1.12V to 1.15V after 160 minutes charging by the wave-transformed-electricity circuit and the first stage booster energy storage circuit. Besides, the experiment of charging mobile phone showed that the 1.15V energy storage battery could charge the mobile phone lasting for 54 seconds using the second stage boost circuit. Evidence showed that the whole device could air charge the mobile phone successfully by using low energy harvesting, appropriate boosting, and energy storage technology.
Honors and Published Paper ii
Abstract (in Chinese) iii
Abstract (in English) iv
Acknowledgements vi
List of Figures x
List of Tables xi
Contents xii
Chapter 1 : Introduction 1
1.1 Background and Motivation 1
1.2 Thesis Structure 2
Chapter 2 : Literature Review 3
2.1 RF-to-Electricity Circuit 3
2.1.1 Impedance Matching 3
2.1.2 Rectifying Circuit 4
2.2 DC-DC Boosting Circuit 5
2.2.1 Introduction to DC-DC Boosting Circuit 5
2.2.2 Flyback DC-DC Boosting Circuit Design 9
Chapter 3 : Introduction to Establishment of Microwave-Transformed-Electricity and Boosted Energy Storage 12
3.1 Reception Antenna 12
3.2 Multiplying and Rectifying Filter Circuit 13
3.3 Matching Circuit 14
3.4 1st-Phase DC-to-DC Boosting Circuit 14
3.5 1st-Phase Tank Circuit 16
3.6 Energy Storage Battery 18
3.7 2st-Phase DC-to-DC Boosting Circuit 19
Chapter 4 : Experiment Process 20
4.1 1st-Phase DC-to-DC Boosting Circuit 20
4.1.1 Load Resistance 20
4.1.2 Coupling Inductor Turns 20
4.1.3 1st-Phase DC-to-DC Boosting Circuit Implementation 21
4.2 1st-Phase Tank Circuit Implementation 21
4.3 Energy-Storing Battery Charging Measurements 21
4.4 1st-Phase DC-to-DC Boosting Circuit 22
4.5 Measurements to Mobile Phone Charging 23
Chapter 5 : Conclusions 24
Chapter 6 : Future Applications and Prospects 25



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