簡易檢索 / 詳目顯示

研究生: 蔡偉崙
Tasi Wei Loong
論文名稱: 脈衝式Nd:YAG雷射封裝3003鋁合金方型鋰電池殼體之機械性質與熱傳分析
A Study on the Mechanical Properties and Heat Transfer Analysis of Packaging 3003 Aluminous Prismatic Li-Ion Battery Case by Pulsed Nd:YAG Laser
指導教授: 程金保
Cheng, Chin-Pao
周長彬
Zhou, Chang-Bin
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: 2005
畢業學年度: 93
語文別: 中文
論文頁數: 114
中文關鍵詞: 脈衝式Nd:YAG雷射鋰離子電池3003鋁合金雷射銲接ANSYS熱傳分析
英文關鍵詞: Pulsed Nd:YAG Laser, Li-ion Battery, 3003 Aluminum Alloy, Laser Welding, ANSYS Heat Transfer Analysis
論文種類: 學術論文
相關次數: 點閱:315下載:28
分享至:
查詢本校圖書館目錄 查詢臺灣博碩士論文知識加值系統 勘誤回報
  • 本研究利用脈衝式Nd:YAG雷射進行3003鋁質方型鋰離子電池殼體封裝,主要探討雷射輸入脈衝能量、峰值功率、以及銲道重疊率大小對封裝品質的影響,藉此得到最佳化製程參數。同時,利用ANSYS有限元素模擬分析以及熱電偶實際測量銲道表面溫度,藉此了解輸入能量大小所造成的表面溫度變化,以及解釋脈衝能量對銲道熱裂、氣孔、合金成分揮發等機械性質的影響。

    研究發現輸入能量越大時,造成的銲道表面溫度越高,在輸入能量20 J以上時,銲道表面溫度已超過主要合金元素Mn的沸點,使銲道合金元素含量比例因揮發而明顯下降,且氧化程度也較嚴重,因此造成銲道的熱裂、氣孔也相對提高。根據結果顯示當重疊率60~70 ﹪,峰值功率Pk=3 kW、4 kW,脈衝能量E=10~12.5 J時,為最佳化製程參數範圍。

    This study includes the mechanical properties and heat transfer effects of the pulsed energy, peak power and overlap of pulsed Nd:YAG laser on packaging 3003 aluminum prismatic Li-ion battery case. The experimental analysis and ANSYS simulation have been made in this study to investigate the change of surface temperature of weld, hot cracking, porosity and alloy elements when different pulsed energy parameters were used.

    The results show that the weld surface temperatures increase with increasing of the energy inputs. The weld surface temperatures have exceeded the boiling point of the chief alloy element, Mn, when the input energy was used more than 20 J. It made the proportion of alloy elements in weld cut down obviously and oxidation more seriously. There are also a lot of porosities and hot cracking in the weld with high energy input. The results of experiment show that optimum parameters are about 60 to 70 ﹪of overlap, 3 kW or 4 kW of peak power (Pk), and 10 to 12.5 J of pulsed energy (E)

    目 錄 謝誌……………………………………………………………I 中文摘要……………………………………………………II Abstract……………………………………………………III 目錄…………………………………………………………IV 表目錄………………………………………………………VI 圖目錄………………………………………………………VII 第一章 緒言…………………………………………………1 第二章 理論與文獻探討……………………………………3 第一節 鋰電池組裝製程與殼體材料………………………………3 2-1-1 鋰電池組裝製程………………………………………………3 2-1-2 鋰電池殼體材料……………………………………………4 第二節 Nd:YAG雷射原理與製程參數………………………………8 2-2-1 脈衝式Nd:YAG雷射……………………………………………8 2-2-2 雷射製程參數…………………………………………………10 2-2-3 銲點重疊率(Overlap)………………………………………13 第三節 鋁合金特性…………………………………………………19 2-3-1 3003鋁合金機械性質…………………………………………19 2-3-2 鋁合金的光學特性……………………………………………21 第四節 雷射銲接模式………………………………………………26 2-4-1 雷射銲接銲道模式……………………………………………26 2-4-2 保護氣體與電漿行為…………………………………………26 第五節 熱傳理論分析………………………………………………28 2-5-1 銲道表面溫度與穿透深度之數學推導………………………28 2-5-2 有限元素數值分析……………………………………………30 2-5-3 雷射銲接熱傳分析文獻回顧…………………………………33 第三章 研究方法與步驟…………………………………39 第一節 實驗流程……………………………………………………39 第二節 實驗設計……………………………………………………41 3-2-1 材料準備………………………………………………………41 3-2-2 夾治具設計與製作……………………………………………42 3-2-3 溫度擷取器安裝………………………………………………44 3-2-4 設備組裝………………………………………………………44 3-2-5 製程參數設計…………………………………………………45 第三節 分析試驗與方法……………………………………………58 3-3-1 製程評估標準…………………………………………………58 3-3-2 機械性質試驗…………………………………………………58 3-3-3 數值分析方法…………………………………………………60 第四章 結果與討論…………………………………………68 第一節 機械性質分析……………………………………………68 4-1-1 銲道直徑………………………………………………………68 4-1-2 銲道深度、凹陷量……………………………………………69 4-1-3 金相顯微組織…………………………………………………70 4-1-4 拉伸試驗………………………………………………………71 4-1-5 EDS合金元素成分分析………………………………………72 第二節 ANSYS數值分析與溫度測量結果…………………………94 第五章 結論與建議………………………………………108 第一節 結論……………………………………………………108 第二節 建議……………………………………………………110 參考文獻……………………………………………………111

    1. 梁桂肇,〝線通訊用鋰離子電池市場應用及發展〞,電子與材料雜誌第19期,pp.34-39.
    2. 陳金銘,〝薄型化鋰電池之發展趨勢〞,工業材料雜誌第180期,(2001) pp.93-99.
    3. 于鶴齡,〝脈衝式Nd:YAG雷射焊接封裝技術最適化參數之研究〞,國立清華大學工程與系統科學系,碩士論文,(2002) pp.1-2.
    4. 姚慶意,〝鋰離子二次電池之製作技術〞,小型二次電池市場與技術專輯,工業材料系列叢書7,(1996) pp.49.
    5. 川 崎徹,〝Development of Li-ion Rechargeable Battery Materials〞,CMC,(1997) Chapter 9.
    6. 〝Power 2000〞, Proceeding of the 8th Annual International Conference on Power Requirements for Mobile Computing and Wireless Communications, (2000 Sept) pp.24-27.
    7. 陳復國,〝鋰電池方型外殼沖壓成形製程設計之研究(1/2) 〞,國家科學委員會專題研究計畫執行報告,(2000) NSC 89-2212-E-002-020.
    8. 楊模樺、施明宏,〝鋰電池組裝製程-極板組裝及銲接技術介紹〞,工業材料158期,(2000) pp.141-144.
    9. 丁勝懋,〝光電工程〞,中國電機工程學會編行,科技圖書公司出版,(1999) pp.16~75.
    10. Rofin BAASEL LASERTECH,〝StarWeld40-Chp.2~Chp.5〞, Rofin Company Nd:YAG Laser Hand book.
    11. T. Y. Fan and R. L. Byer ,〝 Modeling and CW Operation of a Quasi-Three -Level 946nm Nd:YAG Laser〞, IEEE J. Quantum Electron, Vol.23, (1989) pp.605.
    12. T. Kushida, H. M. Marcos, and G. E. Geusic,〝 Laser Transition Cross Section and Fluorescence Branching Ratio for Nd3+ in Yttrium Aluminum Garnet〞, Phys.Rev, Vol. 167, (1973) pp.289.
    13. 蔡偉崙,〝脈衝式Nd:YAG雷射銲接5052鋁合金薄板製程參數之研究〞,中國機械工程學會第二十屆全國學術研討會論文集,第D冊 製造與材料 上集,(2003) pp.127~133.
    14. A. Punkari, D. C. Weckman and H. W. Kerr, 〝Effects of magnesium content on dual beam Nd:YAG laser welding of Al-Mg alloys〞, Science and Technology of Welding and Jointing, Vol.8 No.4, (2003) pp.269-281.
    15. 何慶炎,〝雷射加工穴內的能量吸收〞,行政院國家科學委員會專題研究計畫成果報告,(2000) NSC 89-2212-E-146-002.
    16. Ramasamy Sivakumar,〝 CO2 and Nd:YAG laser beam Nd:YAG laser beam welding of 6111-T4 and 5754-O aluminum alloys for automotive applications〞, UMI Dissertation Information Service,(1997) pp.18-31.
    17. 35.Walter W. Duley,〝Laser Welding〞, John Wiley & Sons, Inc.,(1999) pp.27-32.
    18. 蔡偉崙、高弘杰、簡永泰、程金保,〝5052鋁合金應用脈衝式Nd:YAG雷射微銲接之接合性質研究〞,中華民國銲接協會九十二年年會手冊暨論文集,(2003) pp.A72~A75.
    19. Yih-fong Tzeng,〝 Parametric analysis of the pulsed Nd:YAG laser seam-welding process〞, Journal of Materials Processing Technology, Vol. 102, (2000) pp. 40-47.
    20. 陳憲雄,〝鋁合金資料集〞,啟學出版社,(1989) pp.39~40.
    21. 金重勳,〝機械材料〞,第五版,復文書局,(1988)pp.363~401.
    22. 〝 Properties and Section:Nonferrous Alloys and Special-purpose Materials〞, ASM Handbook, vol.2, (1990).
    23. 周振丰,〝普通高等教育机划教材-焊接冶金(金焊接性) 〞,第一版,北京:机械工出版社,(2002) pp.122~140.
    24. 水野政夫,〝及合金焊接〞,北京:冶金工出版社,(1985).
    25. M. J. Cieslak, and P. W. Fuerschbach, 〝On the Weldability, Composition, and Hardness of Pulsed and Continuous Nd:YAG Laser Welds in Aluminum Alloys 6061, 5456, and 5086〞, Metallurgical Transaction B, Vol.19B, (1988) pp.319-329.
    26. M. G. Deutsch, A. Punkari, D. C. Weckman and H. W. Kerr,〝 Weldability of 1.6 mm thick aluminum alloy 5182 sheet by single and dual beam Nd :YAG laser welding〞, Science and Technology of Welding and Joining, Vol.8 No.4, (2003) pp.246-256.
    27. L. F. Mondolfo,〝Aluminum Alloys: Structure and Properties〞, Boston: Butterworths, (1976) pp.108-111.
    28. John E. Hatch, 〝Aluminum Properties and Physical Metallurgy〞, American Society for Metal, (1984) pp.13-15.
    29. E. A. Estalote and K. G. Ramanthan ,〝Journal of the Optical Society of America〞, Vol. 67,(1977) pp.39-43.
    30. Y. S. Touloukian and D. P. DeWitt, Eds., 〝Thermophysical Properties of Matter〞, Thermal Radiative Properties-Metallic Elements and Alloys, Vol. 7,New York:IFI/Plenum,(1970).
    31. 史俊,〝CO2激光熔深焊接光致等离子体行的值仿真〞,北京工大士文,(2001) pp.1~11.
    32. Joao M. P. Coelhl, Manuel A. Abreu, F. Carvalho Rodrigues, 〝High-speed laser cutting of superposed thermoplastic films: thermal modeling and process characterization〞, Optics &Laser in Engineering, (2003) pp.1-13.
    33. Y.-F. Tzeng,〝 Process Characteristics of Pulsed Nd:YAG Laser Seam Welding〞, The International Journal of Advanced Manufacturing Technology, Vol.16, (2000) pp.10–18.
    34. R. Brockmann, K. Dickmann, P. Geshev, K.-J. Matthes,〝Calculation of laser-induced temperature field on moving thin metal foils in consideration of Stefan problem〞, Optics &Laser Technology, Vol.35,(2003) pp.115-122.
    35. 涂乙平,〝平板對接銲件之三維熱傳分析〞,國立台灣海洋大學機械與輪機工程學系碩士論文,(2000) pp.2~12.
    36. 陳天青,〝多雷射束雷射焊接技術對熔池熔融金屬流向控制之研究〞 ,行政院國家科學委員會專題研究計畫成果報告,(1998) NSC88-2212- E-159-001。
    37. M. Kalyon and B. S. Y.ilbas, 〝Closed Form Solution for Exponentially Decaying Laser Pulse Heating: Evaporation at the Surface〞, The Japan Society of Applied Physics, Vol.41, (2002) pp.3737-3746, 2002.
    38. B. Li, B. W. Shiu and K. J. Lau, 〝 Weld Pattern Design for Sheet Metal Laser Welding Considering Fixturing Quality〞, The International Journal of Advanced Manufacturing Technology, Vol.19, (2002) pp.418-425.
    39. B. Li, B. W. Shiu, 〝Principle and Simulation of Fixture Configuration Design for Sheet Metal Assembly with Laser Welding. Part2: Optimal Configuration Design with the genetic Algorithm〞, The International Journal of Advanced Manufacturing Technology, Vol.18, (2001) pp.276- 284.
    40. 林豐年,〝表面熱傳性質即時量測系統之開發〞,國立台灣海洋大學機械與輪機工程學系碩士論文, (2001) pp.23~36.
    41. Mills A. F.,〝Heat Transfer”, 2nd edition, Prentice Hall, (1999) pp.143-237、
    651-743.
    42. William D., Callister Jr., 〝Material Science and Engineering〞, 5th Edition, (1999) pp.708- 729.
    43. B. Li, B. W. Shiu and K. J. Lau, 〝Principle and Simulation of Fixture Configuration Design for Sheet Metal Assembly with Laser Welding. Part: Finite-Element Modeling and a Prediction and Correction Method〞, The International Journal of Advanced Manufacturing Technology, Vol.18, (2001) pp.266-275, 2001.

    QR CODE