几何参数对空心铝型材拉弯起皱特性的影响规律及机理

doi:10.3969/j.issn.1004-132X.2025.05.020

摘要/Abstract

摘要： 基于板壳理论推导了空心铝型材拉弯成形的起皱能和外力做功函数表达式，结合能量准则建立了空心型材拉弯起皱理论预测模型，并通过实验验证了模型的准确性。揭示了空心型材拉弯起皱缺陷的产生机理，定量研究了几何参数对起皱极限及形态的影响。研究结果表明：三种不同弯曲半径下，空心型材起皱数量和高度的理论预测与实验结果吻合性较好，最大差异分别为1.2和0.55 mm，相对误差分别为16.93%和11.28%。弯曲成形阶段的外力做功增速大于起皱能增速，且随弯曲时间的增加，外力做功大于起皱能，导致产生起皱失稳。增大型材厚高比和厚宽比，起皱率降低，起皱极限提高，且起皱数量减少，起皱高度增大；增大型材宽高比，起皱率提高，起皱极限和起皱数量减少，起皱高度增大；在型材型腔增添内加强筋可提高起皱极限，但起皱数量增加，起皱高度减小。

关键词: 空心铝型材, 拉弯, 起皱, 几何参数, 能量准则

Abstract: Based on the plate and shell theory， the expression of wrinkling energy and external force work functions of hollow aluminum profiles in stretch-bending were derived. Combined with the energy criterion， the theoretical prediction model of wrinkling was established for hollow profiles in stretch-bending and the accuracy of model was verified by bending experiments. The formation mechanism of wrinkling defects in stretch-bending of hollow profiles was revealed and the influences of geometric parameters on wrinkling limit and morphology were quantitatively studied. The results show that the theoretical predictions of the number and height of wrinkling under three different bending radii are in good agreement with those of the experimental ones. The maximum differences are as 1.2 and 0.55 mm， respectively， with relative errors of 16.93% and 11.28%， respectively. The growth rate of external force work in the bending stages is greater than that of wrinkling energy. With the increase of bending time， the external force work is greater than the wrinkling energy， resulting in the appearance of wrinkling instability. With the increase of thickness-to-height ratio and thickness-to-width ratio of the profiles， the wrinkle ratio and wrinkling number decrease， while the wrinkling limit and wrinkling height increase. With the increase of the aspect ratio， the wrinkle ratio and wrinkle height increase， while the wrinkling limit and wrinkling number decrease. The wrinkling limit might be increased by adding inner reinforcement rib in the profile cavities， while the wrinkling number increases and the wrinkling height decreases.

Key words: hollow aluminum profile, stretch-bending, wrinkling, geometric parameter, energy criterion

中图分类号:

TG376.2

刘志文1, 2, 雷冲1, 孙凯博1, 欧阳八生1, 李落星2, 刘筱3, 李发智1. 几何参数对空心铝型材拉弯起皱特性的影响规律及机理[J]. 中国机械工程, 2025, 36(05): 1083-1093.

LIU Zhiwen1, 2, LEI Chong1, SUN Kaibo1, OUYANG Basheng1, LI Luoxing2, LIU Xiao3, LI Fazhi1. Influence Law and Mechanism of Geometric Parameters on Wrinkling Characteristics of Hollow Aluminum Profiles in Stretch-Bending#br#[J]. China Mechanical Engineering, 2025, 36(05): 1083-1093.

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https://www.cmemo.org.cn/CN/Y2025/V36/I05/1083

参考文献

［1］曹立波，陈杰，欧阳志高，等. 基于碰撞安全性的保险杠横梁轻量化设计与优化［J］. 中国机械工程， 2012， 23（23）：2888-2893.
CAO Libo， CHEN Jie， OUYANG Zhigao， et al. Lightweight Design and Optimization of Bumper Beam Based on Automotive Crash Safety［J］. China Mechanical Engineering， 2012， 23（23）：2888-2893.
［2］张凯成，李舜酩，孙明杰. 钢铝材料结合的商用车车架多工况轻量化优化设计［J］. 中国机械工程， 2020， 31（18）：2206-2211.
ZHANG Kaicheng， LI Shunming， SUN Mingjie. Lightweight Optimization Design of Commercial Vehicle Frames Combined by Steel and Aluminum Materials under Multiple Working Conditions［J］. China Mechanical Engineering， 2020， 31（18）：2206-2211.
［3］LANG Lihui， LIU Kangning， CAI Gaoshen， et al. A Critical Review on Special Forming Processes and Associated Research for Lightweight Components Based on Sheet and Tube Materials［J］. Manufacturing Review， 2014， 1：9.
［4］刘志文，李落星. 轻量化构件弯曲短流程工艺研究现状与进展［J］. 中国有色金属学报， 2014， 24（8）：2003-2012.
LIU Zhiwen， LI Luoxing. Review of Bending Short Process for Lightweight Component［J］. The Chinese Journal of Nonferrous Metals， 2014， 24（8）：2003-2012.
［5］高嵩，孙荧力，李奇涵，等. 钛合金型材多点三维热拉弯成形工艺及其微观组织演化［J］. 中国机械工程， 2023， 34（24）：2986-2995.
GAO Song， SUN Yingli， LI Qihan， et al. Multi-point 3D Hot Stretch-Bending Process of Titanium Alloy Profiles and Their Microstructure Evolution［J］. China Mechanical Engineering， 2023， 34（24）：2986-2995.
［6］LIANG Jicai， GAO Song， TENG Fei， et al. Flexible 3D Stretch-Bending Technology for Aluminum Profile［J］. The International Journal of Advanced Manufacturing Technology， 2014， 71：1939-1947.
［7］李恒，杨合，詹梅，等. 薄壁件塑性成形失稳起皱的国内外研究进展［J］. 机械科学与技术， 2004， 23（7）：837-842.
LI Heng， YANG He， ZHAN Mei， et al. A Review of the Research on Wrinkling in Thin-walled Parts Plastic Forming Processes［J］. Mechanical Science and Technology， 2004， 23（7）：837-842.
［8］LIU Nan， YANG He， LI Heng， et al. Plastic Wrinkling Prediction in Thin-walled Part Forming Process：a Review［J］. Chinese Journal of Aeronautics， 2016， 29（1）：1-14.
［9］CORONA E， VAZE S P. Buckling of Elastic-plastic Square Tubes under Bending［J］. International Journal of Damage Mechanics， 1996， 38（7）：753-775.
［10］BARDI F C， KYRIAKIDES S. Plastic Buckling of Circular Tubes under Axial Compression—Part I：Experiments［J］. International Journal of Mechanical Sciences， 2006， 48（8）：830-841.
［11］YUAN S J， CUI X L， WANG X S. Investigation into Wrinkling Behavior of Thin-walled 5A02 Aluminum Alloy Tubes under Internal and External Pressure［J］. International Journal of Mechanical Sciences， 2015， 92：245-258.
［12］CUI X L， WANG X S， YUAN S J. Effects of Mechanical Property Parameters on Wrinkling Behavior of Thin-walled Tubes in Hydroforming Process［J］. The International Journal of Advanced Manufacturing Technology， 2019， 100：729-740.
［13］TIAN Shan， LIU Yuli， YANG He. Effects of Geometrical Parameters on Wrinkling of Thin-walled Rectangular Aluminum Alloy Wave-guide Tubes in Rotary-draw Bending［J］. Chinese Journal of Aeronautics， 2013， 26（1）：242-248.
［14］LI H， YANG H， ZHAN M. A Studyon Plastic Wrinkling in Thin-walled Tube Bending via an Energy-based Wrinkling Prediction Model［J］. Modelling and Simulation in Materials Science and Engineering， 2009， 17（3）：035007.
［15］FENG H， HAN C. Study on Wrinkling Behavior in Hydroforming of Large Diameter Thin-walled Tube through Local Constraints［J］. The International Journal of Advanced Manufacturing Technology， 2018， 99：1329-1340.
［16］LI H， YANG H， ZHAN M， et al. Deformation Behaviorsof Thin-walled Tube in Rotary Draw Bending under Push Assistant Loading Conditions［J］. Journal of Materials Processing Technology， 2010， 210（1）：143-158.
［17］CAO Jian， WANG Xi. An Analytical Model for Plate Wrinkling under Tri-axial Loading and Its Application［J］. International Journal of Mechanical Sciences， 2000， 42（3）：617-633.
［18］CAO Jian. Prediction of Plastic Wrinkling Using the Energy Method［J］. Journal of Applied Mechanics， 1999， 66（3）：646-652.
［19］WANG Xi， CAO Jian. Wrinkling Limit in Tube Bending［J］. Journal of Engineering Materials and Technology， 2001， 123（4）：430-435.
［20］YANG He， LIN Yan. Wrinkling Analysis for Forming Limit of Tube Bending Processes［J］. Journal of Materials Processing Technology， 2004， 152（3）：363-369.
［21］YAN Jing. Plastic Wrinkling Model and Characteristics of Shear Enforced Ti-Alloy Thin-walled Tubes under Combination Die Constraints and Differential Temperature Fields［J］. Chinese Journal of Aeronautics， 2016， 29（6）：1815-1829.
［22］TIMOSHENKO S P， GERE J M. Theory of Elastic Stability［M］. 2nd ed. New York：McGraw-Hill， 1985.
［23］ZHAO G Y， LIU Y L， DONG C S， et al. Analysis of Wrinkling Limit of Rotary-draw Bending Process for Thin-walled Rectangular Tube［J］. Journal of Materials Processing Technology， 2010， 210：1224-1231.

[1]	杜冰1, 2, 李扬1, 2, 刘凤华1, 2, 董明鑫1, 2, 万宇凡1, 2, 钟庆帅1, 2. 考虑厚向应力的板材临界起皱判据建立及影响[J]. 中国机械工程, 2025, 36(05): 1074-1082.
[2]	高文斌1, 2, 占庆元1, 2. 基于位形相似性聚类的机器人参数标定研究[J]. 中国机械工程, 2024, 35(07): 1168-1177，1187.
[3]	高嵩, 孙荧力, 李奇涵, 盈亮, 郝兆朋, 张邦成. 钛合金型材多点三维热拉弯成形工艺及其微观组织演化[J]. 中国机械工程, 2023, 34(24): 2986-2995,3014.
[4]	刘衡, 汪志能, 宾光富, 林伟明, 林姚辰, 马雁翔. 考虑周向波形特性的航空管路弯曲成形起皱理论建模与临界成形半径分析[J]. 中国机械工程, 2023, 34(16): 1982-1990.
[5]	文彦臻, 邓云华, 贾震. 气凝胶填充金属蜂窝夹层结构隔热性能试验与模拟[J]. 中国机械工程, 2023, 34(05): 556-562.
[6]	詹梅, 雷煜东, 郑泽邦, . [成形过程仿真优化与集成计算材料工程]集成计算材料工程在精确塑性成形中的应用现状与发展趋势[J]. 中国机械工程, 2020, 31(22): 2663-2677.
[7]	戚向东, 连家创, 董志奎. 拉弯矫直延伸率的计算及试验分析[J]. 中国机械工程, 2016, 27(08): 1113-1116.
[8]	谭靓, 张定华, 姚倡锋, 任军学. 刀具几何参数对钛合金铣削力和表面完整性的影响[J]. 中国机械工程, 2015, 26(6): 737-742.
[9]	孔晓华, 秦泗吉, 陆宏, 郑星. 圆锥形凹模径向分块压边拉深工艺实验研究[J]. 中国机械工程, 2015, 26(18): 2528-2532,2538.
[10]	刘迪辉, 林成业. 温度对薄板抗起皱性能的影响[J]. 中国机械工程, 2015, 26(10): 1395-1398.
[11]	秦泗吉, 杨莉, 盖玢玢. 平面应力条件下轴对称拉深成形法兰区起皱和破裂分析[J]. 中国机械工程, 2014, 25(23): 3221-3226.
[12]	秦泗吉, 梁韶伟, 张树栋. 轴对称拉深成形法兰区起皱失稳变形能及临界压边力[J]. 中国机械工程, 2013, 24(23): 3244-3248.
[13]	秦泗吉1, 2, 黄晓忠3, 王婧4. 径向分块双压边圈轴对称拉深成形工艺研究 [J]. 中国机械工程, 2011, 22(14): 1741-1744.
[14]	张华. 等效拉深筋精细数值化模型与起皱模拟应用 [J]. 中国机械工程, 2010, 21(21): 2624-2627.
[15]	吴红兵;刘刚;毕运波;董辉跃. 刀具几何参数对钛合金Ti6Al4V切削加工的影响[J]. J4, 2008, 19(20): 0-2399.