簡易檢索 / 詳目顯示

回結果列表
研究生: 李承翰
Cheng-han Lee
論文名稱: 銅管鍛粗加工製程之分析
An analysis of manufacturing process of different thicknesses copper pipes
指導教授: 黃佑民
You-min Huang
口試委員: 向四海
Su-hai Hsiang  
陳聰嘉
Tsung-chia Chen
學位類別: 碩士
Master
系所名稱: 工程學院 - 機械工程系
Department of Mechanical Engineering
論文出版年: 2009
畢業學年度: 97
語文別: 中文
論文頁數: 82
中文關鍵詞: 溫鍛製程分析
外文關鍵詞: Warm forging, An analysis of manufacturing process
相關次數: 點閱:277下載:2
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

    • 國內中小企業從事於關鍵性零組件之開發的廠商相當多,而鍛造加工在零組件之製造上是目前相當普遍採用之方法之一,但鍛造加工尤其是溫鍛加工製程所需之技術層次相當高,因此在加工之過程中常因製程設計不良而無法得到精密之半成品或是成品。本研究即有鑑於此而擬,將針對溫鍛加工之製程設計予以學理上分析,並以不同管徑之銅管材零組件為例,研發其加工製程,包括數值模擬之輸入數據之取得、加工溫度之預測與擬定、模具之設計等,藉由溫鍛製程分析計算出溫鍛品於加工所需之加工壓力,成形過程,溫度的影響,進而判斷各加工製程之合理性。期待能讓業者藉由此研究之成果應用,累積銅管材溫鍛之加工經驗,從以往之冷鍛加工或是熱鍛加工轉型至高技術層次之溫鍛加工,提升產品之附加價值,進而提升產業之競爭力。

    There are many small and medium enterprises engaged in the development of important components. The most common method in manufacturing components is forging. One of the most difficult ways to manufacture components is warm forging. Because of the imperfection in manufacturing design, they can not obtain precise finished or semi-finished products in the process of manufacturing. This project is aim at improving this drawback to analyze the manufacturing design of warm forging. Developing its manufacturing procedures are including the acquirement of input and output data, the prediction and setting of temperature and the design of mold etc. by the different thicknesses of copper pipes. We can calculate how many pressures that be needed in the process of manufacturing warm forging products and the effect on temperatures in shaping process by the manufacturing analysis of warm forging, And then we can judge the rationality of every manufacturing procedures. Hoping for manufacturers can apply the result of research to accumulate the warm forging experiences of copper pipes manufacturing. No matter the cold forging or hot forging, they can be transferred to the higher level technique of warm forging. It can increase additional value of products and heighten the competition of manufacturing.

    摘要..................................... I ABSTRACT ................................ II 誌謝.....................................III 目錄.................................... IV 圖表索引................................. X 第一章 緒論..............................1 1.1前言..................................1 1.2 文獻回顧.............................2 1.2.1 鍛造成形加工介紹...................2 1.2.2 金屬成形分析常用的方法.............8 1.3 研究目的............................13 1.4 論文架構............................14 第二章 基本理論........................ 15 2.1 基本假設............................15 2.1.1 有限變形之應變與應變率...........15 2.2 有限變形之應力與應力率..............17 2.3 有限變形之update Lagrangian formulation .....19 2.4 材料之彈塑性構成關係式......................22 第三章 動態有限元素分析軟體..................... 27 3.1 LS-DYNA 簡介................................27 3.2 動態有限元素簡介.............................28 3.2.1 前處理器.................................30 3.2.2 主程式求解器..............................36 3.2.3 後處理器...................................37 第四章 數值分析與實驗製程規劃................... 38 4.1 材料參數...................................40 4.2 電腦數值模擬解析方法步驟....................44 4.2.1 鍛粗加工之數值模型........................45 4.2.2 鍛粗加工之數值模擬........................47 4.3 實驗設備....................................52 4.3.1 模具組合圖....................................53 4.3.2 實驗機構規劃圖................................63 4.4 實驗結果.................................69 第五章 結論............................... 70 5.1 結論...................................70 5.2 未來研究之展望.........................71 5.2 改善成品卡模問題之製程建議.............71 5.2.1 製程建議.............................73 參考文獻................................... 78 作者簡介....................................81

    1. Y. Tozawa, N. Kato and H. Kudo, “Effect of Upsetting Speed on the Upsetting Limit”, Annals of CIRP, Vol.30 , pp.203-206 ,(1981) .
    2. E. Evangelista, A. Forcellese, F. Gabrielli and P. Mengucci, “Hot Formability of AA6061 PM Aluminium Alloy”, J. Mat.Proc. Tech., Vol.24 , pp.323-332 ,(1990) .
    3. H. Sekiguchi, K. Osakada, Y. Tozawa, “Improvement of Cold Forgability in Steels”, Annals of CIRP, Vol.32 , pp.181-185 ,(1983) .
    4. J. C. Gelin, J. Oudin, Y. Ravalard and A. Moisan, “A New Testing Method for the Determination of Ductile Fracture in Cold Forming processes”, Annals of CIRP, Vol.32 , pp.191-194 ,(1983) .
    5. Oskar Pawelski, Karl Edgar Hagedorn, and Rene Hop,“Development of New Methods for Determining the Formability and Flow Stress of Materials Based on Intermetallic Compounds”, Steel Research, No.8, pp.326-329 ,(1994) .
    6. H. A. Kuhn, P. W. Lee and T. Erturk, “A Fracture Criterion for Cold Forming”, J. of Eng. Mat. and Tech. Trans of ASME, pp.213-328 ,(1973) .
    7. E. Erman and H. A. Kuhn, “Novel Test Specimens for Workability Measurements in Compression Testing of Homogeneous Materials and Composites”, American Society for Testing and Materials, pp.279-290 ,(1983) .
    8. 中華民國鍛造協會編審委員會,“鍛造技術手冊”,中華民國產業科學發展協進會、中華民國鍛造協會,民國86年。
    9. 許源泉,“鍛造學-理論與實習”,三民書局,民國79年。
    10. 李冠宗,“潤滑學”,高立圖書有限公司,民國81年。
    11. C. H. Lee and S. Kobayashi, “ New Solution to Rigid-Plastic Deformation Problems Using a Matrix Method ”, J. Eng. Ind., Trans. ASME, Vol. 95, pp. 865-873, 1973.
    12. Y. Yamada, N. Yoshimura and T. Sakurai, “ Plastic Stress-Strain Matrix and its Application for the Solution of Elastic-Plastic Problems by the Finite Element Method ”, Int. J. Mech. Sci., Vol. 10, pp. 343-354, 1968.
    13. E. I. Odell, “ A study of Wall Ironing by the Finite Element Technique ”, J. of Engrg. for Ind., Vol. 100, pp. 31-36, 1978.
    14. S. Brandal and H. Valberg, “ Analysis of the Deformation Process during Wire Drawing by means of the Finite Element Method ”, Wire J. Int., pp. 64-70, 1982.
    15. H. D. Hibbitt, P.V. Marcal and J. R. Rice, “ A Finite Element Formulation for Problems of Large Strain and Large Displacement ”, Int. J. Solids Structure, Vol. 6, pp. 1069-1086, 1970.
    16. R. M. McMeeking and J. R. Rice, “ Finite-Element Formulations for Problems of Large Elastic-Plastic Deformation ”, Int. J. Solids Structure, Vol. 11, pp. 601-616, 1975.
    17. A. S. Wifi, “ Incremental Complete Solution of the Stretch Forming and Deep-Drawing of a Circular Blank Using a Hemispherical Punch ”, Int. J. Mech. Sci., Vol. 18, pp. 23-31, 1976.
    18. A. S. Wifi, “ Studies on Large Strain Elasto-Plasticity and Finite Element Analysis of Deformation Processes ”, the University of Tokyo, June, 1978.
    19. J. C. Nagtegaal and N. Rebelo, “On the Development of A General Purpose Finite Element Program for Analysis of Forming Process,” Int. J. Num. Meth. Engng. , Vol. 25, pp.113-131 (1988).
    20. A. Makinouchi and S. D. Liu, “Finite Element Analysis of Contact Problems at Finite Elasto-Plastic Deformation,” Proceedings of NUMIFORM’89, pp26-30 (1989).
    21. A. Makinouchi and Y. Shirataki, S. D. Liu and Y. Nagai, “Generalization of Tool-Work Contact Conditions for Elasto-Plastic Analysis of Forming Process,” Advanced Technology of Plasticity, Vol. 3, pp.1161-1166 (1990).
    22. Y. Yamada and T. Hirakawa, “Large Deformation and Instability Analysis of Metal Forming Process,” Applications of Numerical Methods to Forming Processes,ASME,AMD-28,pp.27-38(1978).
    23. J. H. Cheng and N. Kikuchi, “An Analysis of Metal Forming Process Using Large Deformation Elastic-Plastic Formulations,” Computer Methods in Applied Mechanics and Engineering, Vol. 49, pp.71-108 (1985)
    24. M. J. Saran and R. H. Wagoner, “A Consistent Implicit Formulation for Nonlinear Finite Element Modeling with Contact Problems in Elasticity,” Journal of Applied Mechanics, Vol. 58, pp.499-506 (1991)

    QR CODE