Tendency of homogeneous radial deformation during electromagnetic compression of aluminium tube 被引量：4

Tendency of homogeneous radial deformation during electromagnetic compression of aluminium tube

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摘要 Electromagnetic forming is one of the high-rate forming methods that can be extensively used to form and join axisymmetric metal sheet and tube. Tendency of homogeneous radial deformation during electromagnetic compression of aluminium tube was investigated through the design optimization method based on sequential coupling numerical simulation and experiments. The results show that the tendency depends on the length ratio of tube to coil (R), which has a critical value (Rc) corresponding to the relatively homogeneous radial deformation along axial direction. The tube length relative to Rc is insensitive to the discharge voltage. When R is greater than Rc, the deformed tube presents horn shape and the shorter coil makes for local deformation. If R is less than Rc, the deformed tube presents drum shape and the longer coil contributes to larger deformation at tube end. Rc increases with coli length and could approach to 1; inversely, it could approach to 0. These results indicate the design optimization method based on the sequential coupling numerical simulation is feasible, which can be used to realize the controllable and precise deformation of metal tube. Electromagnetic forming is one of the high-rate forming methods that can be extensively used to form and join axisymmetric metal sheet and tube. Tendency of homogeneous radial deformation during electromagnetic compression of aluminium tube was investigated through the design optimization method based on sequential coupling numerical simulation and experiments. The results show that the tendency depends on the length ratio of tube to coil （R）, which has a critical value （Re） corresponding to the relatively homogeneous radial deformation along axial direction. The tube length relative to Re is insensitive to the discharge voltage. When R is greater than Rc, the deformed tube presents horn shape and the shorter coil makes for local deformation. IfR is less than Re, the deformed tube presents drum shape and the longer coil contributes to larger deformation at tube end. Rc increases with coli length and could approach to 1; inversely, it could approach to 0. These results indicate the design optimization method based on the sequential coupling numerical simulation is feasible, which can be used to realize the controllable and precise deformation of metal tube.

作者于海平李春峰刘大海梅险

机构地区 School of Materials Science and Engineering Computer Centre

出处《中国有色金属学会会刊：英文版》 CSCD 2010年第1期7-13,共7页 Transactions of Nonferrous Metals Society of China

基金 Projects(50575052, 50805036) supported by the National Natural Science Foundation of China

关键词变形趋势径向变形电磁成形均质铝管优化设计方法缩管数值模拟 homogeneous radial deformation design optimization method electromagnetic forming aluminium tube

分类号 TG391 [金属学及工艺—金属压力加工] P642.22 [天文地球—工程地质学]

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参考文献15

1JABLONSKI J, WINKLER R. Analysis of the electromagnetic forming process [J]. Int J Mech Sci, 1978, 20: 315-325.
2VOHNOUT V J. A hybrid quasi-static/dynamic process for forming large metal parts from aluminum [D]. Ohio, Columbus: Ohio State University, 1998: 1-15.
3MAMALIS A G, MANOLAKOS D E, KLADAS A G, KOUMOUTSOS A K. Electromagnetic forming and powder processing: Trends and developments [J]. Appl Mech Rev (ASME), 2004, 57(4): 299-324.
4WANG L F, CHEN Z Y, LI C X, HUANG S Y. Numerical simulation of the electromagnetic sheet metal bulging process [J]. International Journal of Advanced Manufacturing Technology, 2006, 30: 395-400.
5EL-AZAB A, GARNICH M, KAPOOR A. Modeling of the electromagnetic forming of sheet metals: State-of-the-art and future needs [J]. Journal of Materials Processing Technology, 2003, 142: 744-754.
6李忠,李春峰,于海平,赵志衡.Effect of tube size on electromagnetic tube bulging[J].中国有色金属学会会刊：英文版,2007,17(4):705-710. 被引量：2
7IMBERT J M, WINKLER S L, WORSWICK M J, OLIVEIRA D A, GOLOVASHCHENKO S. The effect of tool-sheet interaction on damage evolution in electromagnetic forming of aluminum alloy sheet [J]. Journal of Engineering Materials and Technology, 2005, 27(1): 145-153.
8MAMALIS A G.MANOLAKOS D E, KLADAS A G.KOUMOUTSOS A K. Electromagnetic forming tools and processing conditions: Numerical simulation [J]. Materials and Manufacturing Processes, 2006, 21:411-423.
9UNGER J, STIEMER M, SVENDSEN B, BLUM H. Multifield modeling of electromagnetic metal forming processes [J]. Journal of Materials Processing Technology, 2006, 177: 270-273.
10YU H P, LI C F, DENG J H. Sequential coupling simulation for electromagnetic-mechanical tube compression by finite element analysis [J]. Journal of Materials Processing Technology, 2009, 209(2): 707-713.

二级参考文献20

1于海平,李春峰.Finite element analysis of free expansion of aluminum alloy tube under magnetic pressure[J].中国有色金属学会会刊：英文版,2005,15(5):1040-1044. 被引量：5
2于海平,李春峰,李忠.基于FEM的电磁缩径耦合场数值模拟[J].机械工程学报,2006,42(7):231-234. 被引量：8
3MAMALIS A G,MANOLAKOS D E,KLADAS A G,KOUMOUTSOS A K.Physical principles of electromagnetic forming process:A constitutive finite element model[J].Journal of Materials Processing Technology,2005,161:294-299.
4SETH M,VOHNOUT V J,DAEHN G S.Formability of steel sheet in high velocity impact[J].Journal of Materials Processing Technology,2005,168:390-400.
5GIANNOGLOU A,KLADAS A,TEGOPOULOUS J.Electromagnetic forming:A coupled numerical electromagneticmechanical-electrical approach compared to measurements[J].International Journal for Computation and Mathematics in Electrical and Electronic Engineering,2004,23(3):789-799.
6OLIVEIRA D A,WORSWICK M J.Electromagnetic forming of aluminum alloy sheet[J].J Phys Ⅳ,2003,110:293-298.
7OLIVEIRA D A,WORSWICK M J.Simulation of electromagnetic forming of aluminum alloy sheet[J].SAE Trans J Mat Manuf,2001,110:687-695.
8LI Chun-feng,ZHAO Zhi-heng,LI Jian-hui,LI Zhong.The effect of tube length on magnetic pressure in tube electromagnetic bulging[J].Journal of Materials Processing Technology,2005,166:381-386.
9FENTON G K,DAEHN G S.Modeling of electromagnetically formed sheet metal[J].Journal of Materials Processing Technology,1998,75:6-16.
10BENDJIMA B,SRAIRI K,FELIACHI M.A coupling model for analyzing dynamical behaviors of an electromagnetic forming system[J].IEEE Transactions on Magnetics,1997,33(2):1638-1641.

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1于海平,徐志丹,江洪伟,赵志学,李春峰.铝合金-碳钢管的磁脉冲变形连接(英文)[J].中国有色金属学会会刊：英文版,2012,22(S2):548-552. 被引量：5
2崔晓辉,莫健华,何文治.基于松散耦合法的电磁管件胀形3D模拟[J].中国有色金属学报,2011,21(11):2896-2902. 被引量：3
3CUI Xiao-hui,MO Jian-hua,ZHU Ying.3D modeling and deformation analysis for electromagnetic sheet forming process[J].Transactions of Nonferrous Metals Society of China,2012,22(1):164-169. 被引量：5
4Zhi-Song Fan,Su-Ting Huang,Jiang-Hua Deng.Cladding of aluminum alloy 6061-T6 to mild steel by an electromagnetic tube bulging process: finite element modeling[J].Advances in Manufacturing,2019,7(1):73-83.
5白雪山,张鑫,张帅,张铁森,赵天章.航空5A02铝合金波纹管电磁成形的试验研究[J].锻压技术,2021,46(12):165-169. 被引量：5
6吴伟业.新型线圈加载的管件电磁胀形电磁力及成形性分析[J].材料开发与应用,2022,37(5):62-67. 被引量：1
7洪秀冬,黄亮,李建军,马飞,林磊.大口径铝合金波纹管电磁胀形数值模拟[J].精密成形工程,2016,8(4):1-7. 被引量：7

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1赵志衡,李春峰,邓将华.管坯电磁成形时线圈受力的研究[J].材料科学与工艺,2004,12(4):387-390. 被引量：5
2李春峰,于海平.电磁成形技术理论研究进展[J].塑性工程学报,2005,12(5):1-7. 被引量：19
3于海平,李春峰.Finite element analysis of free expansion of aluminum alloy tube under magnetic pressure[J].中国有色金属学会会刊：英文版,2005,15(5):1040-1044. 被引量：5
4于海平,李春峰,李忠.基于FEM的电磁缩径耦合场数值模拟[J].机械工程学报,2006,42(7):231-234. 被引量：8
5宋福民,王仲仁,张旭,于连仲.管件电磁成形研究[J].塑性工程学报,1996,3(3):15-22. 被引量：12
6于海平,李春峰.Effects of coil length on tube compression in electromagnetic forming[J].中国有色金属学会会刊：英文版,2007,17(6):1270-1275. 被引量：7
7M.A. Bahmani,K. Niayesh,A. Karimi.3D Simulation of magnetic field distribution in electromagnetic forming systems with field-shaper[J].Journal of Materials Processing Tech.2008(5)
8S. F. Golovashchenko,,V. S. Manutov,V. V. Dmitriev.Formability of Sheet Metal with Pulsed Electromagnetic and Electrohydraulic Technologies. Aluminum 2003 . 2003
9Lee, Sung Ho,Lee, Dong Nyung.Finite element analysis of electromagnetic forming for tube expansion. Journal of Engineering . 1994
10李忠,李春峰,赵志衡.电磁胀形管坯所受磁压力的瞬态分布[J].材料科学与工艺,2008,16(3):301-305. 被引量：1

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1赵新海,王同海,刘清津,赵国群,孙景洲.管接头复合成形新工艺及有限元模拟[J].山东工业大学学报,1998,28(2):165-168. 被引量：3
2刘怡.用缩管法设计铝铸件冒口[J].铸造技术,1992(4):17-21. 被引量：1
3梅晓军.半环类铝铸件铸造工艺[J].航天工艺,1994(5):20-22.
4李惠民.普通油压机上用的缩管模设计[J].机械制造,1990,28(8):14-15.
5黑泽文夫.金属耐锈皮膜的形成方法[J].国外轴承技术,1993(4):25-28.
6单才华.大缩比缩管工艺分析及其自动化加工[J].金属加工（热加工）,2011(15):53-55.
7张明升.淬火锻钢轧辊的超声检测[J].大型铸锻件,1985(1):40-49.
8刘俊生,周明贵,张喜涛.燃料混合管压形缩管模设计[J].模具工业,2004,30(8):24-25.
9吕鸣剑,王宏昌.几种球铁件工艺的改进[J].铸造设备研究,2001(6):30-31.
10刘俊生,周明贵,张喜涛.燃料混合管压形缩管模[J].模具制造,2004,4(5):25-25.

中国有色金属学会会刊：英文版

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