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完整後設資料紀錄
DC 欄位 | 值 | 語言 |
---|---|---|
dc.contributor.advisor | 吳文方(Wen-Fang Wu) | |
dc.contributor.author | Yi-Chen Huang | en |
dc.contributor.author | 黃伊辰 | zh_TW |
dc.date.accessioned | 2021-06-16T03:02:07Z | - |
dc.date.available | 2017-07-20 | |
dc.date.copyright | 2015-07-20 | |
dc.date.issued | 2015 | |
dc.date.submitted | 2015-07-02 | |
dc.identifier.citation | [1] 盧樹台、陳仁和、謝文桐,「電動車用鋰電池之殘電量估測」,清雲學報,第31期,第3冊,第1-19頁,2011。
[2] 李添財,電動汽機車,第二版,全華圖書股份有限公司,臺灣,2009。 [3] S. Negarestani, A. R. Ghahnavieh, and A. S. Mobarakeh, “A Study of the Reliability of Various Types of the Electric Vehicles,” 2012 IEEE International Electric Vehicle Conference, pp. 1-6, 2012. [4] S.-H. Jeon, J.-H. Cho, Y. Jung, S. Park, and T.-M. Han, “Automotive Hardware Development According to ISO 26262,” 13th International Conference on Advanced Communication Technology, pp. 588-592, 2011. [5] 陳柏睿,「ISO 26262 系統功能安全設計標準之研究」,機械工業雜誌,第344期,第106-122頁,2011。 [6] 朱慧德、胡玉書,「ISO 26262-汽車特定的功能安全標準」,品質月刊,第48期,第8冊,第15-20頁,2012。 [7] M. Bellotti and R. Mariani, “How Future Automotive Functional Safety Requirements will Impact Microprocessors Design,” Microelectronics Reliability, Vol. 50, No. 9-11, pp. 1320-1326, 2010. [8] 張雍昌、黃立仁、劉興庄、楊智仁,「具錯誤回復能力之低成本車用微處理器架構」,電腦與通訊,第152期,第17冊,第128-133頁,2013。 [9] K. J. Lee, Y. H. Ki, J. S. Cheon, and H. S. A. G. Hwang, “Approach to Functional Safety-Component ECU Design for Electro-Mechanical Brake Systems,” International Journal of Automotive Technology, Vol. 15, No. 2, pp. 325-332, 2014. [10] 吳宇平、袁翔雲、董超、段冀淵,鋰離子電池-應用與實踐,第二版,化學工業出版社,北京,2013。 [11] J. Zhang and J. Lee, “A Review on Prognostics and Health Monitoring of Li-Ion Battery,” Journal of Power Sources, Vol. 196, No. 15, pp. 6007-6014, 2011. [12] D. Andrea, Battery Management Systems for Large Lithium Ion Battert Packs, Artech House, Boston, 2010. [13] 許家興,電動車成敗的關鍵技術-電池管理系統,財團法人車輛研究測試中心綠能車輛發展處,2011。 [14] C. Sen and N. C. Kar, “Battery Pack Modeling for the Analysis of Battery Management System of a Hybrid Electric Vehicle,” 2009 IEEE Vehicle Power and Propulsion Conference (VPPC), pp. 207-212, 2009. [15] L. Lu, X. Han, J. Li, J. Hua, and M. Ouyang, “A Review on the Key Issues for Lithium-Ion Battery Management in Electric Vehicles,” Journal of Power Sources Vol. 226, No., pp. 272-282, 2013. [16] C. E. Ebeling, An Introduction to Reliability and Maintainability Engineering, McGraw-Hill Inc., New York, 1997. [17] 黃清賢,危害分析與風險評估,初版,三民書局,臺灣,1996。 [18] 陳雨軒,機車碟煞系統之可靠度研究,臺灣大學機械工程學研究所碩士論文,臺北,臺灣,2012。 [19] 闕延洲,自行車內變速系統之可靠度研究,臺灣大學機械工程學研究所碩士論文,臺北,臺灣,2004。 [20] ISO/FDIS 26262-1~10, Road Vehicle-Functional Safety-Part 1~10, International Organization for Standardization, 2011. [21] M. Tweeddale, Managing Risk and Reliability of Process Plants, Gulf Professional Publishing, Elsevier, 2003. [22] 行政院研究發展考核委員會,風險管理及危機處理作業手冊,2009。 [23] W. Taylor, G. Krithivasan, and J. J. Nelson, “System Safety and ISO 26262 Compliance for Automotive Lithium-Ion Batteries,” 2012 IEEE Symposium on Product Compliance Engineering, pp. 1-6, 2012. [24] 我的E政府,車速限制,國家發展委員會,2015。 [25] TEXAS Instruments, M3641 Lithium-Ion Battery Pack Protection Circuit, TEXAS Instruments, 2011. [26] 鄭星山,馬達驅動控制器之量化可靠度研究,臺灣大學機械工程學研究所碩士論文,臺北,臺灣,2013。 [27] Y. Xing, E. W. M. Ma, K. L. Tsui, and M. Pecht, “Battery Management Systems in Electric and Hybrid Vehicles,” Energies, Vol. 4, No. 11, pp. 1840-1857, 2011. [28] 劉錦釧、鍾明裕、伍慶雄、張仁山,「電動汽機車鋰電池組品質檢測與改善技術」,新新季刊,第42期,第1冊,第147-162頁,2014。 [29] User's Guide, EDLC Cell Balance LSI BD14000EFV-C Ecaluation Board, ROHM Semiconductor, 2015. [30] 谷腰欣司、趙中興譯,感測器,初版,全華圖書股份有限公司,臺灣,2006。 [31] Naval Surface Warfare Center, Handbook of Reliability Prediction Procedures for Mechanical Equipment, US Naval Surface Warfare Center, 2011. | |
dc.identifier.uri | http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/54525 | - |
dc.description.abstract | 電動車因具有低汙染、節能、低噪音等優點,漸漸被大眾廣泛使用,然而,其動力來源-蓄電池有能量損耗及儲存的問題,會影響使用者的生命安全。而安全一直是車輛產業非常關注的焦點,車用電機/電子產品或其零組件的安裝與使用者的生命財產安全息息相關,為了避免車輛危害帶來重大損失,國際標準組織(International Organization for Standardization, ISO)專為車用電機/電子發佈ISO 26262標準。本論文以電池管理系統(Battery Management System, BMS)為案例,示範符合ISO 26262標準之執行流程,並評估電池管理系統之可靠度。首先介紹電池基本概念以及電池管理系統的功能;接著說明ISO 26262組成架構與功能安全管理,並進一步介紹概念階段以及硬體架構評估所需推動的工作或實施項目;最後透過ISO 26262功能安全標準來發展一電池管理系統,使其能符合功能安全設計的要求;同時亦建立一個完整的功能安全管理流程,以利產品達到高安全、高可靠度以及高品質的境界。此外,本研究亦探討電池管理系統的失效模式與影響分析,並使用MIL-HDBK-217F N2或FIDES Guide 2009兩種可靠度預估模型,計算電池管理系統與其零組件之可靠度和平均失效時間(Mean Time to Failure, MTTF)。研究結果發現,本論文所探討的電池管理系統平均失效時間為3.79年,而依照失效模式之影響程度將各零組件予以排列,失效嚴重程度依序為電池組過熱、ECU訊號異常、ECU燒毀與電池組爆炸等。 | zh_TW |
dc.description.abstract | Owing to their low pollution, energy saving, low noise, and other benefits, electric vehicles will be widely used in the near future. However, the batteries of and electric vehicle encounter a few problems including energy loss and storage limitation. Their failures would threaten lives of the driver and passengers of a vehicle and should be paid attention to safety has always been a major concern in the automotive industry. The electric or electronic devices are closely related to the safety of a vehicle. In order to avoid losses caused by failure of a vehicle, the International Organization for Standardization published ISO 26262 which is functional safety standard entitled “Road Vehicles – Functional Safety.” To demonstrate how ISO 26262 can be fulfilled, a battery management system (BMS) used in an electric vehicle is studied from reliability engineering point of view in this thesis. First, the BMS used in an electric vehicle is introduced. The overall architecture and functional safety management of ISO 26262 is introduced briefly afterwards. Emphasis is placed on the concept phase and assessment of the hardware architectures. The required work to implement ISO 26262 to a product is highlighted in particular. Finally, an example of implementing ISO 26262 to the introduced BMS and is carried out. The purpose is to create a completion functional safety management toward the high safety, reliability and quality target to meet ISO 26262 standard for the BMS. In addition, the failure mode and effect analysis (FMEA) of the BMS is performed. The reliability and mean time to failure (MTTF) of the BMS and its components are evaluated. The result shows the MTTF of the studied BMS is 3.79 years. Based on FMEA, it’s found that critical failure modes of the BMS are overheating of battery packs, abnormal signal of the electric control unit (ECU), burned-out ECU, and the explosion of battery packs etc., in sequential order of seriousness. | en |
dc.description.provenance | Made available in DSpace on 2021-06-16T03:02:07Z (GMT). No. of bitstreams: 1 ntu-104-R02522512-1.pdf: 4420809 bytes, checksum: a9e0432eb7176b7f3d09bd1b4f1d99eb (MD5) Previous issue date: 2015 | en |
dc.description.tableofcontents | 致謝.......................................I
摘要......................................II ABSTRACT.................................III 目錄.......................................V 表目錄..................................VIII 圖目錄....................................IX 第一章 緒論................................1 1.1 研究動機...........................1 1.2 文獻回顧...........................3 1.3 研究目的...........................7 1.4 論文架構...........................7 第二章 應用原理介紹........................9 2.1 電池基本概念.......................9 2.2 電池管理系統......................11 2.3 可靠度基本原理....................12 2.3.1 可靠度定義..........................12 2.3.2 系統可靠度..........................14 2.4 可靠度預估模型....................16 2.4.1 MIL-HDBK-217F N2....................16 2.4.2 FIDES Guide 2009....................17 2.5 失效模式與影響分析................18 第三章 ISO 26262介紹......................21 3.1 組成架構..........................21 3.2 項目定義..........................24 3.3 生命安全週期展開..................25 3.4 危害分析與風險評估................26 3.4.1 危害事件辨識........................27 3.4.2 危害事件分析........................27 3.4.3 危害事件評估........................29 3.4.4 建立安全目標........................30 3.5 功能安全概念......................31 3.6 硬體架構評估......................32 第四章 ISO 26262在電池管理系統之應用......36 4.1 項目定義..........................36 4.2 危害分析與風險評估................37 4.3 功能安全概念......................39 第五章 可靠度評估.........................40 5.1 失效模式與影響分析................40 5.1.1 可靠度模式建立......................40 5.1.2 零組件失效模式分析..................41 5.1.3 失效影響與機率評估..................42 5.1.4 風險矩陣建立與失效關鍵性評估........43 5.2 零組件可靠度計算..................47 5.2.1 電子控制單元(ECU)可靠度.............47 5.2.2 電池平衡控制器可靠度................48 5.2.3 電池組可靠度........................49 5.2.4 數據儲存器可靠度....................49 5.3 系統可靠度計算....................50 5.4 FMEA發生機率探討..................52 5.5 硬體架構評估......................53 第六章 結論與建議.........................55 6.1 結論..............................55 6.2 建議..............................56 文獻參考..................................57 | |
dc.language.iso | zh-TW | |
dc.title | 符合ISO 26262車用電池管理系統之可靠度評估 | zh_TW |
dc.title | Reliability Assessment of Automotive Battery Management Systems for Fulfillment of ISO 26262 | en |
dc.type | Thesis | |
dc.date.schoolyear | 103-2 | |
dc.description.degree | 碩士 | |
dc.contributor.oralexamcommittee | 劉霆(Tyng Liu),詹魁元(Kuei-Yuan Chan) | |
dc.subject.keyword | 功能安全,ISO 26262,電池管理系統,可靠度評估,失效模式與影響分析, | zh_TW |
dc.subject.keyword | Functional Safety,ISO 26262,Battery Management System,Reliability Assessment,Failure Mode and Effect Analysis, | en |
dc.relation.page | 59 | |
dc.rights.note | 有償授權 | |
dc.date.accepted | 2015-07-02 | |
dc.contributor.author-college | 工學院 | zh_TW |
dc.contributor.author-dept | 機械工程學研究所 | zh_TW |
顯示於系所單位: | 機械工程學系 |
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