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研究生:胡志國
研究生(外文):Chih-Kuo Hu
論文名稱:應用數據交換之串聯電池電量平衡
論文名稱(外文):Charge-Equalization on Series-Connected Batteries Based on Data Communication
指導教授:謝耀慶
指導教授(外文):Yao-Ching Hsieh
口試委員:邱煌仁謝耀慶林景源陳景然
口試委員(外文):Huang-Jen ChiuYao-Ching HsiehJing-Yuan LinChing-Jan Chen
口試日期:2017-06-16
學位類別:碩士
校院名稱:國立臺灣科技大學
系所名稱:電子工程系
學門:工程學門
學類:電資工程學類
論文種類:學術論文
論文出版年:2017
畢業學年度:105
語文別:中文
論文頁數:63
中文關鍵詞:串聯電池組返馳式轉換器電量平衡系統
外文關鍵詞:Series-connected batteriesflyback convertercharge equalization system
相關次數:
  • 被引用被引用:2
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由於串聯電池組內的電池之間具有不同的化學特性,在充放電過程中,電池之間特性會漸漸偏移,使得電池之間出現了電量差距,若是不注意此現象,會造成電池損毀,產生安全上的疑慮。切換式電能轉換器平衡法較其他種的電量平衡法具有高功率、短時間與容易擴充等優點。本文提出了串聯電池組電量平衡系統,採用雙向返馳式轉換器做為硬體架構,並且搭配數位控制核心與通訊網路。數位控制核心透過通訊網路取得資料後,運算出電路控制命令,進而驅動雙向返馳式轉換器來達成直接電量轉移之目的。
Variability between batteries is caused by the manufacturing process,
which will increase by cycle life. It is very dangerous to ignore battery
cell’s degradation effect. Severe damage will happen to batteries and threat
user’s personal safety.
Compare to other charge balancing method, applying switching
power supply as charge balancing method has some advantages, such as
high balancing power, low balancing time and easy to expand. A
bi-directional flyback converter is applied as experimental platform for
charge equalization system. Digital control units and communication
network are also inserted in charge equalization system. Digital control
units will exchange data over communication network and generate a
control command to control bi-directional flyback converter. In the other
word, charge will be transferred between batteries by giving the control
command to bi-directional flyback converter and batteries will be
balanced.
摘要 ............................................................................................................... i
Abstract ........................................................................................................ ii
誌謝 ............................................................................................................. iii
目錄 .............................................................................................................. v
圖表目錄 .................................................................................................... vii
第一章 緒論 ............................................................................................ 1
1.1 研究動機與目的 .............................................................. 1
1.2 內文編排方式 .................................................................. 3
第二章 典型串聯電池模組平衡方式 .................................................... 4
2.1 電池平衡電路之介紹 ...................................................... 4
2.1.1 電阻式平衡法 ........................................................... 5
2.1.2 電容式平衡法 ........................................................... 6
2.1.3 電感式平衡法 ........................................................... 8
2.1.4 變壓器平衡法 ........................................................... 9
2.1.5 切換式電源轉換器平衡法 ..................................... 10
2.2 電池平衡電路之選用 .................................................... 11
第三章 硬體實驗平台架構 .................................................................. 13
3.1 系統架構之介紹 ............................................................ 13
3.2 串聯電池組平衡電路之動作流程與平衡策略 ............ 14
3.2.1 電路動作流程介紹 ................................................. 14
3.2.2 平衡策略介紹 ......................................................... 17
第四章 軟體控制策略與流程 .............................................................. 21
4.1 前言 ................................................................................ 21
4.2 數位控制器介紹 ............................................................ 22
4.3 通訊網路介紹 ................................................................ 23
4.3.1 通訊介面簡介 ......................................................... 24
4.3.2 通訊轉換IC 介紹 ................................................... 30
4.4 電池管理IC 介紹 .......................................................... 32
4.5 軟體控制流程 ................................................................ 33
第五章 實驗數據與結果 ...................................................................... 40
5.1 實驗波形 ........................................................................ 40
5.2 實驗結果 ........................................................................ 43
第六章 結論與未來展望 ...................................................................... 47
6.1 結論 ................................................................................ 47
6.2 未來展望 ........................................................................ 48
參考文獻 .................................................................................................... 49
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