跳到主要內容

簡易檢索 / 詳目顯示

回結果列表
研究生: 陳遠欣
Yuan-Shin Chen
論文名稱: A1050P板材經非對稱壓延之彎曲行為的實驗研究
This experiment of bent appearance at asymmetrical rolling with A1050P specimens
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: 96
語文別: 中文
論文頁數: 98
中文關鍵詞: 曲率異周速非對稱壓延
外文關鍵詞: Curvature, asymmetrical rolling, mismatch peripheral speed
相關次數: 點閱:16下載:0
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

    • 由於非對稱壓延可有效降低壓延力及壓延扭矩,使材料於壓延製程安排上,更趨自由與多樣性,在壓延工業之應用上,具有極大之助益;但於非對稱壓延後之板材易產生彎曲現象而造成產品品質降低及設備損壞。
    本文以試片厚度2mm及2.9mm的A0150P鋁板進行同徑對稱及非對稱壓延實驗,以探討試片厚度、縮減率、輥輪周速比及界面潤滑條件對成形板材彎曲曲率的效應。實驗結果顯示,(1) 成形試片曲率達到平板狀態理想值(±0.0025)的縮減率和試片厚度成正比關係;(2) 成形試片曲率達到平板狀態理想值(±0.0025)的縮減率和周速比係成正比的關係;(3) 不同界面潤滑條件對於壓延力及壓延扭矩有明顯的降低效應,但對改善成形試片曲率無明顯的效應。

    Due to the asymmetrical rolling can reduce rolling force and rolling torque that will make rolling process also flexible and variable. There are extreme advantages in application of rolling industry. The specimens will curvature after the asymmetrical rolling, the flat bending will reduce production quality and impact machine.
    This paper observe various of curvature ratio at symmetrical and asymmetrical rolling with different specimens thickness(2mm and 2.9mm),mismatch peripheral speed,reduction, lubrication. The result is that:(1) The specimens reduction that curvature ratio is between ±0.0025 is directly proportional to specimens thickness.(2) The specimens reduction that curvature ratio is between ±0.0025 is directly proportional to mismatch peripheral speed.(3) With Lubrication, rolling force and rolling torque is decreased, but curvature ratio is not improve.

    中文摘要 I 英文摘要 II 誌謝 III 目錄 IV 圖目錄 VII 表目錄 XII 第一章 緒論 1 1-1 前言 1 1-2 板材非對稱壓延 2 1-3 研究動機 3 第二章 理論基礎 4 2-1 壓延種類 4 2-2 文獻回顧 5 2-2-1 實驗研究方面 5 2-2-2 理論解析方面 8 2-2-3 摩擦係數方面 10 第三章 實驗設備與方法 13 3-1 實驗設備 13 3-1-1 壓延機 13 3-1-2 資料擷取系統 14 3-2 實驗方法 14 3-2-1 試片準備 14 3-2-2 實驗條件 15 3-2-3 編號表示意義 16 3-2-4 輥輪與試片之界面潤滑條件 17 3-2-5 輥輪及工作平台之調整 18 3-2-6 壓延實驗步驟 19 3-3 試片成形曲率之量測 20 3-3-1 曲率計之測定原理 20 3-3-2 曲率量測方法之探討 21 3-3-3 曲率計之校正 22 3-4 拉伸試驗 22 3-5 環壓試驗 24 3-6 Forward Slip 26 第四章 結果與討論 30 4-1 拉伸實驗 30 4-2 環壓實驗 31 4-3 Forward Slip 31 4-4壓延實驗結果 33 4-4-1 周速比( )對壓延力的影響 35 4-4-2 周速比( )對壓延扭矩的影響 38 4-4-3 試片厚度對成形試片曲率之效應 40 4-4-3 周速比對成形試片曲率之效應 43 4-4-4 界面潤滑條件對成形試片曲率之效應 46 第五章 結論 49 參考文獻 51 附錄A 87 附錄B 90 附錄C 93

    [1] O. Hoffman and G. Sachs, "Introduction to the Theory of Plasticity for Engineers," Fig. 19.1, McGraw-Hill Book Company, New York, 1953.
    [2] N. Bay, et al., "Cross Shear Roll Bonding," J. Mater. Process. Technol., 45(1994)1-6.
    [3] T. Von Karman, Zeitschrift fur angewandte Mathematik und Mechanik, 5(1925)139.
    [4] E. Orowan, "The Calculation of Roll Pressure in Hot and Cold Flat
    Rolling," Proceedings of the Institution of Mechanical Engineers, 150(1943) 140-167.
    [5] D. R. Bland, and H. Ford, "The Calculation of Roll Force and Torque in Cold Strip Rolling with Tensions," Proc. Instn. Mech. Engrs., 159(1948) 144-153.
    [6] H. Ford, F. Ellis, and D. R. Bland, "Cold Rolling with Strip Tension
    Part I. A New Approximate Method of Calculation and a Comparison
    with Other Method," Jounal of the Iron and Steel Institute, (1951)57-72.
    [7] R. B. Sims, "The Calculation of Roll Force and Torque in Hot Rolling
    Mills," Proc. Instn. Mech. Engrs., 168(1954)191-200.
    [8] J.M. Alexander, "On the Theory of Rolling," Proceedings of the Royal Socity of London. Series A., 326(1972)535-563.
    [9] D. Rusia, "Improvements to Alexander''s Computer Model for Force and Torque Calculations in Strip Rolling Process," Journal of the Material
    Shaping Technology, 8(1990)167-177.
    [10] D. Rusia, "Review and Evaluation of Different Methods for Force and Torque Calculations in the Strip Rolling Process," Journal of the
    Material Shaping Technology, 9(1991)117-125.
    [11] W. Johnson and G. Needham, "An Experimental Study of
    Asymmetrical Rolling," Applied Mechanics Convention, Cambridge,
    Instn. Mech. Engrs. 180(1966)270-281.
    [12] W. Johnson and G. Needham, "Further Experiments In Asymmetrical rolling", Int. J. Mech. Sci., 8 (February 1966) 433-455.
    [13] D. Pan and D. H. Sansome, "An Experimental Study of the Effect of
    Roll Speed Mismatch on the Rolling Load during the Cold Rolling of
    the Thin strip," Journal of Mechanical Working Technology, 6(1982)361-377.
    [14] H. Shiozaki, S. Shinya, M. Mikami, S. Koide. “Experimental Study on the Effects of Differential Roll Speed Ratio on the Rolling Force, Rolling Torque and Forward Slip in Thin Strip Rolling.”, 塑性加工,23(1982)1080-1086
    [15] K. Narita et al., "The Characteristics of Curvature in Asymmetrical
    Cold Rolling," Proc. s-63 Sp. Conf. of JSTP, (1988)241-244.
    [16] J. Jeswiet, P.G.Greene, ”Experimental measurement of curl in rolling,” J. Mater. Proces. Technol., 84(1998)202-209
    [17] 黃永茂,徐宏修, "應用流線函數法於壓延加工之研究-單層板非對稱壓延速度場之修正," 第十九屆全國力學會議, (1995)171-178.
    [18] H. Dyja, P.Korczak, J.W.Pilarczyk, J. Grzybowski, “Theoretical and Experimental Analysis of Plates Asymmetric Rolling”, Journal of Materials Processing Technology, 45 (1994) 167-172
    [19] H. Dyja, J. Markowski and D. Stoninski, “Asymmetry of the Roll Gap as a Factor Improving Work of the Hydraulic Gauge Control in the Plate Rolling Mill”, Journal of Materials Processing Technology, 60 (1996) 73-80.
    [20] M.Salimi, F.Sassanib, "Modifed slab analysis of asymmetrical plate
    rolling",International Journal of Mechanical Sciences 44 ,
    (2002)1999–2023.
    [21] A. Kawalek, ”Forming of Band Curvature in Asymmetrical Rolling
    Process,”Journal of Materials Processing Technology,155-156(2004) 2033-2038.
    [22] A. Kawalek, "The Theoretical and Experimental Analysis of The
    Effect of Asymmetrical Rolling on The Value of Unit Pressure," Journal of Materials Processing Technology, 157-158(2004)531-535.
    [23] R. Hill, “The Mathematical Theory of Plasticity”, Oxford University Press, London, 1950.
    [24] A.T. Male and M.G. Cockcroft, "A Method for the Determination of
    the Coefficient of Friction of Metals under Conditions of Bulk Plastic
    Deformation", Journal of the Institute of Metals, 93(1964-65)38-46.
    [25] Schroeder, W., and Webster, D. A., “Press Forging Thin Sections : Effect of Friction, Area and Thickness on Pressure Required”, Journal of Applied Mechanics, 16(1949)289-294.
    [26] J.G. Lenard, “Friction and Forward Slip in Cold Strip Rolling”, Tribology Transactions, 35(1992)423-428.
    [27] S. Ekelund, "The Analysis of Fators Influencing Rolling Pressure and Power Consumption in the Hot Rolling of Sheet", Steel, 93(1933)27-29.
    [28] R.B. Sims, "The Forward Slip in Cold Strip Rolling", Sheet Metal industries", 29(1952)869-877.
    [29] H. Inhaber, "The Coefficient of Friction in Cold Rolling ", Journal of Engineering for Industry, 88(1966)421-429.
    [30] W.L. Roberts, "Cold Rolling of Steel", Dekker and Co., New York, (1987).
    [31] J. G. Lenard, S. Zhang, “A study of friction during the lubricated cold rolling of an aluminum alloy”, Journal of Materials Processing Technology, 72(1997)293-301.
    [32] E.B. Li, A.K. Tieu, W.Y.D. Yuen, “Application of digital image correlation technique to dynamic measurement of the velocity field in the deformation zone in cold rolling”, Optics and Lasers in Engineering, 39(2003)479-488.
    [33] A.K. Tieu, Y.J. Liu, “Friction variation in the cold-rolling process”, Tribology International, 37(2004)177-183.
    [34] 孟繼洛, “機械材料”, 臺北市:曉園出版社, (1990)430-431
    [35] Designation:E8M-91, Standard Test Methods for Tension Testing of
    Metallic Materials [Metric], 150-168.
    [36] W.F. Hosford and M.C. Caddell, "Metal forming Mechanics and
    Metallurgy," Prentice-Hall International, Inc. (1993)55-60.

    QR CODE
    :::