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研究生: 林宏杰
Hong-Jie Lin
論文名稱: 矩形杯引伸成形料片外形設計之有限元素分析
The blank shape designed of the rectangular cups in deep drawing by FEM method.
指導教授: 葉維磬
Wei-Ching Yeh
口試委員:
學位類別: 碩士
Master
系所名稱: 工學院 - 機械工程學系
Department of Mechanical Engineering
畢業學年度: 95
語文別: 中文
論文頁數: 88
中文關鍵詞: 引伸成形
外文關鍵詞: deep drawing
相關次數: 點閱:11下載:0
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    • 應用MARC有限元素軟體,並結合Toh與Kobayashi[1]之引伸成形料片外形設計法做為本文分析矩形杯引伸成型料片設計的問題。本文以矩形杯之長寬邊比值為3、2.5、2、1.5及1等五組不同外形的引伸件為例,並建立各組在引伸成形後的理想成形外形與形狀誤差的計算方式。在形狀誤差符合國際公差標準IT13~IT16的範圍內探討設計過程中所對應的形狀誤差及其達到的公差等級,並探討不同的初始料片外形與設計尺寸對於設計次數與成品品質的影響。為瞭解MARC應用於三維引伸加工問題的預測性及妥適性,本文利用Choi與Huh[7] 及Toh與Kobayashi[1]的實驗結果對MARC分析做驗證,並探討料片外形經設計候對於成形性之影響。

    In this paper, A numerical analysis combined finite element code “MARC’ and Toh with Kobayashi’s blank designed method to analyze the blank design of the deep drawing of rectangular cups. It used the ratio of the length and width side is 3, 2.5, 2, 1.5, 1of the rectangular cups. It established ideal shapes of the drawing cups and the count of the shape error. As for the shape error conform to IT13~IT16 of the Internationable Toleranzeinheit discuss various of the initial blank shapes and designed shapes effect design times and the quality of the products. In order to verify the validity of the 3-D deep drawing analysis by MARC, the paper applied Choi with Huh’s and Toh with Kobayashi’s experimental results to verify the validity of the analysis by MARC and discuss the formability of the drawing cups with the designed blanks.

    摘要 Ⅰ 誌謝 Ⅲ 目錄 Ⅳ 圖表說明 Ⅶ 符號索引 ⅩⅢ 第一章 緒論 1-1 前言 1 1-2 文獻回顧 2 1-3 研究動機與目的 4 第二章 基本理論 2-1 Update Lagrangian Formulation(ULF)理論 7 2-2 有限元素分析基本概念 8 2-3 MARC接觸問題的處理 13 2-3-1 接觸之定義 13 2-3-2 接觸面摩擦效應之處理 14 2-3-3 接觸之處理程序 15 2-4 MARC分析求解技術分析 17 2-4-1 參考座標系統 17 2-4-2 非線性代數方程組疊代求解方法 18 2-4-3 收斂性判斷依據(Convergence Testing) 19 2-4-4 元素技術 20 第三章 有限元素模擬及設計方法 3-1 基本假設 22 3-2 料片機械性質 23 3-3 初始料片幾何尺寸 23 3-4 加工模組幾何尺寸 24 3-5 有限元素分析之加工參數 24 3-6 國際公差標準(Internationable Toleranzeinheit) 24 3-7 有限元素分析之參數控制 25 3-8 MARC之架構與各部份的功能介紹 25 3-9 MARC應用於3-D引伸加工問題的設定與操作程序 26 3-9-1 前處理器 26 3-9-2 分析器 27 3-9-3 後處理器 28 3-10 設計方法 28 第四章 結果與討論 4-1 3-D矩形杯與方杯引伸成形實驗驗證結果 30 4-2 料片設計分析 32 4-2-1 料片引伸誤差分析 32 4-2-2 設計尺寸及初始料片外形對設計的影響 36 4-2-3 厚度應變分析 38 4-2-4 等效塑性應變分析 39 4-2-5 衝頭負載分析 39 第五章 結論與建議 5-1 結論 41 5-2 建議 42 參考文獻 43

    [1] C.H. TOH and SHIRO KOBAYASHI,“DEFORMATION ANALYSIS
    AND BLANK DESIGN IN SQUARE CUP DRAWING”, Int.J.Mach.
    Tool Des., Vol.25, No.1,pp15-32, 1985.
    [2] H.B. Shim and D. Y. Yang,“Elastic-Plastic Finite Element Analysis of Deep Drawing Process by Membrance and Sheel Elements”, Journal of Manufacturing Science and Engineering, Vol.119,pp.341
    -349,1997.
    [3] M.M. Moshksar and A. Zamanian,“Optimization of the tool geometry
    in the deep drawing of aluminium”, Journal of Materials Processing
    Technology Vol.72,pp.363-370,1997.
    [4] N.M. Wang and S.C. Tang,“Analysis of Bending Effects in Sheet
    Forming Operations”, Int. J. for Num. Meth. in Engng., Vol.25,pp.
    253~267,1998.
    [5] Sangdo Kim, Minbo Park, Sangjin Kim, Daegyo Seo,“Blank design
    and formability for non-circular deep drawing processes by the finite
    -element method”, Journal of Materials Processing Technology Vol.
    72,pp.363-370,1998.
    [6] A.M. Zaky, A.B. Nassr, M.G.. El-Sebaie,“Optimum blank shape of
    cylindrical cups in deep drawing of anisotropic sheet metals. ”,
    Journal of Materials Processing Vol.76,pp.203-211,1998.
    [7] T. H. Choi and H. Huh,“Sheet metal forming analysis of planar
    anisotropic materials by a modified membrane finite element method
    with bending effect”, Journal of Materials Processing Technology Vo1.89-90,pp.135-140,1999.
    [8] Yasuo Marumo, Hiroyuki Saiki and Toshihiko Mori,“Combined
    effects of strain hardening characteristics and tool geometry on the deep-drawability of square aluminium cups”, Journal of Materials
    Processing Technology Vol.89,no1,pt.0,pp.30-36,1999.
    [9] S.H. Park, J.W. Yoon, D.Y. Yang, Y.H. Kim,“Optimum blank design in
    sheet metal forming by the deformation path iteration method”,
    International Journal of Mechanical Sciences Vol.41,pp.1217-1232,
    ,1999.
    [10] Hyunbo Shim, Kichan Son, Kwanghee Kim,“Optimum blank shape
    design by sensitivity analysis”, Journal of Materials Processing
    Technology Vol104,pp.191-199,2000.
    [12] W. Thomas, T. Oenoki, T. Altan,“Process simulation in stamping -
    recent application for production and process design”, Journal of Materials Processing Technology Vol98,pp.232-243,2000.
    [13] Y.Q. Guo, J. L.Batoz, H.Naceur, S. Bouabdallah, F. Mercier , O. Barlet,“Recent developments on the analysis and optimum design of sheet metal forming parts using a simplified inverse approach”, Computers and Structures Vol78,pp.133-148,2000
    [14] E. Doege and L.-E. Elend, “Design and Application of Pliable Blank
    Holder System for the Optimization of Process Conditions in Sheet
    Metal Forming”, Journal of Materials Processing Technology Vol.111,pp.182-187,2001.
    [15] D.H. Park, S.S. Kang, S.B. Park, “A study on the improvement of formability for elliptical deep drawing process”, Journal of Materials Processing Technology Vol113,pp.662-665,2001.
    [16] Li-Ping Lei, Sang-Moon Hwang, Beom-Soo Kang, “Finite element
    and its experimental comparison”, Journal of Materials Processing
    Technology Vol110,pp.70-77,2001.
    [17] H. Naceur, Y.Q. Guo, J.L. Batoz, C. Knopf-Lenoir, “Optimization of drawbead restraining forces and drawbead design in sheet metal forming process”, International Journal of Mechanical Sciences Vol.43, pp.2407-2434,2001
    [18] Vijay Pegada, Young Chun, Sridhar Santhanam, “An algorithm for
    the Optimal blank shape for the deep drawing of aluminum cups”, Journal of Materials Processin Technology Vol125-126,pp.743-750,
    2002.
    [19] Naval Kishor, D. Ravi Kumar, “Optimization of initial blank shape to minimize earing in deep drawing using finite element method”,
    Journal of Materials Processing Technology Vol,130-131,pp.20-30,
    2002.
    [20] Mark Colgan, John Monaghan, “Deep drawing process : analysis
    and experiment”, Journal of Materials Processing Technology
    Vol.132,pp.35-41,2003.
    [21] H. Naceur, A. Delameziere, J.L. Batoz, Y.Q. Guo, C. Knopf-Lenoir,
    “Some improvements on the optimum process design in deep
    drawing using the inverse approach”, Journal of Materials
    Processing Technology Vol146,pp.250-262,2004.
    [22] G. Gantar, K. Kuzman, B. Filipic,“Increasing the stability of
    the deep drawing process by simulation-based optimization”,
    Journal of Materials Processing Technology Vol.164-165,pp.1343-
    1350,2005.
    [23] Claudio Garcia, Diego Celentano, Fernando Flores,Jean-Philippe
    Ponthot, Omar Oliva, “Numerical modeling and experimental
    validation of steel deep drawing process Part Ⅱ : Applications”,
    Journal of Materials Processing Technology Vol172,pp.461-471,
    2006.
    [24] H.D. Hibbitt, P.V. Marcal and J.R. Rice, “A Finite Element Formulation for problems of large strain and displacement”, Int. J.
    Solids Struct., Vol6,pp.1069-1086,1970.
    [25] R. M. Mcmeeking and J.R. Rice, “Finite Element Formulation for
    Problem of Large elastic-plastic deformation”, Int. J. Solids Struct
    ., Vol11,pp.601-616,1975.
    [26] “Theory and user information”, MARC Analysis Research Corporation. Volume A. Version K7.
    [27] 何信森, “方杯引伸成形之彈塑性有限元素分析”碩士論文,國
    立中央大學機械工程研究所,1999.
    [28] 李建彰, “引伸成形加工問題之有限元素分析”碩士論文,國立中央大學機械工程研究所,2000.
    [29]劉庚寅, “公差測量基礎與應用”,北京:機械工業出版社,1996

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