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研究生: 戴仲瑜
Tai, Chung-Yu
論文名稱: 灰狼演算法應用於複合電力電動車輛系統之控制器設計
Control Unit Design Using Gray Wolf Algorithm for a Multiple-Electric-Energy Vehicle
指導教授: 洪翊軒
Hung, Yi-Hsuan
學位類別: 碩士
Master
系所名稱: 工業教育學系
Department of Industrial Education
論文出版年: 2020
畢業學年度: 108
語文別: 中文
論文頁數: 70
中文關鍵詞: 控制器設計灰狼演算法規則庫管理人工蜂群演算法複合電力
英文關鍵詞: control unit design, gray wolf algorithm, rule-based management, artificial bee colony algorithm, multiple electric power
DOI URL: http://doi.org/10.6345/NTNU202000879
論文種類: 學術論文
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  • 本研究應用灰狼演算法(Gray Wolf Algorithm, GWA)進行複合電力車之電力系統控制器設計。選定Tesla Model 3作為目標車輛,並透過動力輸出馬達、傳動系統、目標車輛動態參數、駕駛行為參數,將目標車輛數學化。並透過鋰電池模型、燃料電池模型與超級電容模型,建立一含三電力源之複合電力電動車模型。基於目標車輛與標準行車型態,根據不同控制策略:規則庫控制(Rule-based)、最小等效油耗控制策略(Equivalent Consumption Minimization Strategy, ECMS)、人工蜂群演算法(Artificial Bee Colony Algorithm, ABC)、GWA進行電力系統控制器設計。分析控制策略於行車型態下所消耗之電力進行比較,並使用快速雛型控制器(Rapid Prototyping Controller)進行即時(Real time, RT)控制,測試即時控制策略於實際車輛之可行性。ECMS、ABC、GWA於NEDC與規則庫控制之電力消耗比較,電力消耗改善為[33.8%、25.8%、32.5%],於FTP-72改善為[32.5%、25.1%、30.2%],灰狼演算法有較佳改善。GWA、GWA(RT)、GWA(HIL)電力消耗累積於NEDC下為[4270仟焦、4430仟焦、4483仟焦],FTP-72為[5183仟焦、5197仟焦、5251仟焦],其具有高度相似,未來可應用於實際車輛上。

    To design the power system of an electric vehicle control unit, we used the gray wolf algorithm(GWA). According to the target vehicle-Tesla model 3, we built the traction motor, transmission system, target vehicle dynamics, driving behavior parameters to formulate a target vehicle simulation system. Then, we built the electric power source system with the lithium battery model, fuel cell model and supercapacitor model. The target vehicle simulation system and the electric power source system were combined to form a multiple-electric energy vehicle system and the vehicle control unit was employed to calculate the power consumption. Based on the target vehicle and standardized driving cycles, we adopted different control strategies such as rule-based control, ECMS, artificial bee colony algorithm (ABC), gray wolf algorithm (GWA) to design the power system control unit. By analyzing the power consumed of each algorithm under different driving cycles for comparison. We used a rapid prototype controller on the real-time control platform to test the feasibility of the control strategy in an actual vehicle.
    Comparing the power consumption of ECMS, ABC, GWA in NEDC driving cycles with the rule base control, the power consumption is improved by [33.8%, 25.8%, 32.5%]. The improvement for the FTP-72 case is [32.5%, 25.1%, 30.2%], which shows respectively that the gray wolf algorithm has better power consumption improvement. Comparing the power consumption of GWA, GWA(RT) and GWA(HIL) in NEDC driving cycle, the power consumption is [4272(kJ), 4430(kJ)], and [5183(kJ), 5197(kJ), 5251(kJ)] in FTP-72 driving cycle respectively. It has a very high similarity compared with real-time control, which can be used on the actual electric vehicle in the future.

    摘要 i Abstract ii 誌謝 iv 目 次 v 表 次 viii 圖 次 ix 第 一 章 緒論 1 1.1 引言 1 1.2 研究動機 2 1.3 研究目的 3 1.4 研究方法 4 1.5 文獻回顧 7 1.6 論文架構 12 第 二 章 子系統架構與目標車輛模型 13 2.1 系統架構 13 2.1.1 目標車輛系統 14 2.2 行車型態模塊 16 2.3 駕駛行為控制模塊 17 2.4 動力輸出馬達 18 2.5 燃料電池模型 19 2.6 鋰電池模型 20 2.7 超級電容模型 21 2.8 傳動系統 23 2.9 目標車輛動態模型 24 2.10 硬體嵌入式系統架構 25 2.10.1 快速雛型控制器 25 2.10.2 硬體嵌入式系統(HIL)模型架構 26 2.10.3 硬體嵌入式系統(HIL)硬體架構 27 第 三 章 控制器控制策略設計 29 3.1 複合電力源電動車架構 29 3.2 規則庫控制策略 30 3.3 最小等效油耗控制策略 33 3.4 仿生控制策略之人工蜂群演算法 36 3.4.1 人工蜂群演算法介紹 36 3.4.2 人工蜂群演算法流程圖 37 3.5 仿生控制策略之灰狼演算法 38 3.5.1 灰狼演算法介紹 38 3.5.2 灰狼演算法建立步驟 39 3.5.3 灰狼演算法流程圖 42 第 四 章 模擬結果與討論 43 4.1 各策略車速追蹤與行駛距離結果 43 4.1.1 NEDC行車型態速度追蹤結果 43 4.1.2 FTP-72行車型態速度追蹤結果 44 4.1.3 NEDC行車型態行駛距離結果 45 4.1.4 FTP-72行車型態行駛距離結果 45 4.2 控制策略之複合電力源分配結果 46 4.2.1 規則庫控制模式切換與電力分配結果 46 4.2.2 最小等效油耗控制策略之電力分配結果 48 4.2.3 仿生演算法之電力分配結果 49 4.2.4 各控制策略殘電量模擬結果 54 4.3 電力消耗累積分析與比較 56 4.4 硬體嵌入式系統結果分析 60 第 五 章 結論與未來工作 63 5.1 結論 63 5.2 未來工作與建議 64 參考文獻 65 符號彙整 69

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