Machining distortion prediction of aerospace monolithic components 被引量：2

Machining distortion prediction of aerospace monolithic components

导出

摘要 To predict the distortion of aerospace monolithic components, a model is established to simulate the numerical control (NC) milling process using 3D finite element method (FEM). In this model, the cutting layer is simplified firstly. Then, the models of cutting force and cutting temperature are established to gain the cutting loads, which are applied to the mesh model of the part. Finally, a prototype of machining simulation environment is developed to simulate the milling process of a spar. Key factors influencing the distortion, such as initial residual stress, cutting loads, fixture layout, cutting sequence, and tool path are considered all together. The total distortion of the spar is predicted and an experiment is conducted to validate the numerical results. It is found that the maximum discrepancy between the simulation results and experiment values is 19.0% To predict the distortion of aerospace monolithic components, a model is established to simulate the numerical control （NC） milling process using 3D finite element method （FEM）. In this model, the cutting layer is simplified firstly. Then, the models of cutting force and cutting temperature are established to gain the cutting loads, which are applied to the mesh model of the part. Finally, a prototype of machining simulation environment is developed to simulate the milling process of a spar. Key factors influencing the distortion, such as initial residual stress, cutting loads, fixture layout, cutting sequence, and tool path are considered all together. The total distortion of the spar is predicted and an experiment is conducted to validate the numerical results. It is found that the maximum discrepancy between the simulation results and experiment values is 19.0%.

作者 Yun-bo BI Qun-lin CHENG Hui-yue DONG Ying-lin KE

机构地区 State Key Lab of Fluid Power Transmission and Control Shanghai Spaceflight Precision Machinery Research Institute

出处《Journal of Zhejiang University-Science A(Applied Physics & Engineering)》 SCIE EI CAS CSCD 2009年第5期661-668,共8页 浙江大学学报（英文版）A辑（应用物理与工程）

基金 Project (No. 50435020) supported by the National Natural Science Foundation of China

关键词 Monolithic component Machining distortion Finite element simulation 变形预测加工利用航空航天单片元件三维有限元法网格模型环境模拟

分类号 TG501.4 [金属学及工艺—金属切削加工及机床] TV698.11 [水利工程—水利水电工程]

引文网络
相关文献

参考文献3

1成群林,柯映林,董辉跃.航空铝合金铣削加工中切削力的数值模拟研究[J].航空学报,2006,27(4):724-727. 被引量：35
2董辉跃,柯映林,吴群,许德.基于残余应力分布的框类零件装夹方案优选的有限元模拟[J].航空学报,2003,24(4):382-384. 被引量：17
3梅中义,王运巧,范玉青.飞机结构件数控加工变形控制研究与仿真[J].航空学报,2005,26(2):234-239. 被引量：27

二级参考文献25

1de Meter E C. Fast support layout optimization. International Journal of Machine[]]. Tool & Manufacture, 1998, 38:1221- 1239.
2Menassa R J. Optimization methods applied to selecting support positions in fixture design [ J ]. Transactions of the ASME, 1991, 113: 412-418.
3Cogun C. The importance of the application sequence of clamping forces on workpiece accuracy[J ]. Journal of Engineering for Industry, 1992, 114:539-543.
4Li B, Melkote S N. Improved workpiece location accuracy through fixture layout optimization [ J ]. International Journal of Machine Tool & Manufacture, 1999, 39 : 871 - 883.
5Yoshihara N, Hina Y. Removal technique of residual stress in 7075 aluminum alloy[A]. In: Fujiwara H, et al eds. Residual Stress-III, Science and Technology[C]. London and New York: Elsevier Science Publishers, 1992. 1140- 1145.
6Tsai J S, Liao C L. Finite-element modeling of static surface errors in the peripheral milling of thin-walled workpieces[J]. Journal of Materials Processing Technology, 1999, 94(3):235-246.
7Ozel T, Altan T. Process simulation using finite element method-prediction of cutting forces, tool stresses and temperatures in highspeed flat end milling[J].International Journal of Machine Tools & Manufacture, 2000, 40(5):713-738.
8Krishnakumar K. Machining fixture layout optimization using the genetic algorithm[J]. International Journal of Machine Tools & Manufacture, 2000, 40(4):579-598.
9Lee W B, Cheung C F, Chiu W M, et al. An investigation of residual form error compensation in the ultra-precision machining of aspheric surfaces[J]. Journal of Materials Processing Technology, 2000, 99(2):129-134.
10Lin Z C, Lo S P. A study of deformation of the machined workpiece and tool under different low cutting velocities with an elastic cutting tool[J]. Int J Mech Sci, 1998, 40(7):663-681.

共引文献76

1成群林,柯映林,董辉跃,毕运波,黄志刚.航空整体结构件铣削加工变形预测研究[J].浙江大学学报（工学版）,2007,41(5):799-803. 被引量：18
2金秋,刘少岗.薄壁弧形件铣削加工装夹方案的优化[J].工具技术,2007,41(12):54-57. 被引量：6
3唐东红.工艺系统变形分析及精度控制技术研究[J].机床与液压,2008,36(1):70-72. 被引量：4
4季宏宇.大型航空结构件比较式优化设计[J].常州工学院学报,2008,21(3):16-18.
5吴恩启,杜宝江,张辉辉,刘小宇.太阳能电池层压机的有限元分析与优化[J].机械设计与制造,2008(7):72-74. 被引量：5
6成群林,侯正全,唐建平,安庆龙,陈明.基于切削力建模的结构件高效铣削加工技术[J].航天制造技术,2008(4):6-8. 被引量：1
7吴琼,张以都,张洪伟,赵晓慈.航空薄壁件与铣刀的加工变形误差补偿研究[J].武汉理工大学学报,2008,30(9):116-119. 被引量：10
8白万金,柯映林,吴红兵,董辉跃.航空薄壁件对称及阶梯对称铣削的数值仿真与分析[J].中国机械工程,2009,10(2):214-217. 被引量：13
9陈绍清,彭承明,王聪康.基于多应力耦合的航空框类零件加工变形仿真分析及其控制技术[J].机械工程师,2009(4):34-36. 被引量：3
10杨振朝,张定华,姚倡锋,任军学,田卫军.TC11钛合金插铣加工铣削力影响参数的灵敏度分析[J].航空学报,2009,30(9):1776-1781. 被引量：16

同被引文献25

1郭魂,左敦稳,王树宏,王焱,王珉.拉伸装夹对航空框类零件加工变形影响的有限元分析[J].南京航空航天大学学报,2005,37(B11):72-76. 被引量：14
2付秀丽,艾兴,张松,潘永智.航空整体结构件的高速切削加工[J].工具技术,2006,40(3):80-83. 被引量：13
3张云峰,曹岩.薄壁件加工变形分析与控制[J].科技信息,2008(8):200-200. 被引量：11
4何宁,杨吟飞,李亮,赵威.航空结构件加工变形及其控制[J].航空制造技术,2009,52(6):32-35. 被引量：30
5张以都,张洪伟.航空整体结构件加工变形有限元数值仿真[J].北京航空航天大学学报,2009,35(2):188-192. 被引量：15
6武凯,何宁,廖文和,宋良煌,陈雪梅.阶梯对称铣削工艺在薄壁件精密加工中的应用[J].航空精密制造技术,2005,41(5):46-47. 被引量：4
7李江,李付国,薛凤梅,彭富华,袁战伟.7050高强铝合金断裂韧性及其影响因素研究[J].稀有金属材料与工程,2013,42(9):1921-1925. 被引量：19
8姬浩.先进铝合金锻件在大型飞机上应用研究[J].热加工工艺,2014,43(11):13-15. 被引量：17
9刘嘉辰,王金亮,陈慧琴.高强铝合金超厚板淬火残余应力及其冷压缩消除过程分析[J].轻合金加工技术,2014,42(9):27-32. 被引量：4
10单英吉,孙树强,杨巍.高速切削技术在飞机结构件加工中的应用研究[J].中国新技术新产品,2016(8):16-17. 被引量：4

引证文献2

1马秀伟,胡越,姚雯莉,蒋睿嵩.国产7050铝合金薄壁承力框车削变形预测研究[J].航空工程进展,2025,16(1):108-116.
2段士伟,李萍,康敬波,崔敏超,池亚达.薄壁零件加工残余应力变形预测及控制技术研究现状[J].机械工程与技术,2022,11(6):647-659.

1周杰,李晶,孟毅.基于CAD/CAE技术的汽车曲轴模锻工艺优化[J].锻压装备与制造技术,2007,42(4):46-48. 被引量：4
2盖超,陈伟,吕彦明.DEFORM-3D软件在叶片锻坯结构形式选取中的应用[J].热加工工艺,2007,36(1):74-76. 被引量：7
3杨大勇,李艳,杨立光,任连生,王淑凤,伏金娟,刘建勇,李勇.整体叶轮电火花加工技术研究[J].航空制造技术,2012,55(15):42-45. 被引量：1
4王荣滨.防止电火花线切割裂纹产生的措施[J].机械工人（冷加工）,2006(1):46-46.
5黄东男,李静媛,谢建新.模具结构对AZ91镁合金挤压成形性能的影响[J].塑性工程学报,2009,16(4):105-110. 被引量：8
6刘红艳,李海峰,徐致让.PC轧机辊系的三维建模与有限元分析[J].安徽工业大学学报（自然科学版）,2007,24(2):177-180. 被引量：3
7A. Mitchell Advanced Materials Research Laboratory, University of British Columbia, Vancouver BC,Canada.ELIMIMATION OF RANDOM DEFACTS IN AEROSPACE MATERIALS[J].Acta Metallurgica Sinica(English Letters),1999,12(4):283-296. 被引量：2
8楼文高,喻怀仁.三维有限元法在麻花钻结构分析中的应用[J].上海工业大学学报,1991,12(3):233-239.
9许思广,曹起骧,连家创.异形截面环件轧制过程的三维有限元分析[J].锻压机械,1994,29(3):8-11. 被引量：6
10火力与指挥控制研究会2011年度学术年会在青岛召开[J].火力与指挥控制,2011,36(11).

Journal of Zhejiang University-Science A(Applied Physics & Engineering)

2009年第5期

浏览历史

内容加载中请稍等...