高强度双相钢薄板拉弯成形试验及数值模拟

上海交通大学学报（自然版） ›› 2013, Vol. 47 ›› Issue (05): 760-765.

高强度双相钢薄板拉弯成形试验及数值模拟

谢震，李萌，王武荣，韦习成

（上海大学材料科学与工程学院，上海 200072）

收稿日期:2012-08-10 出版日期:2013-05-28 发布日期:2013-05-28
基金资助:
国家自然科学基金项目（51005144），上海市汽车工业科技发展基金(1009)，上海市数字化汽车车身工程重点实验室开放基金项目（2012002）资助

Stretch Bending Limit of Dual Phase Sheet and Its Numerical Simulation

XIE Zhen,LI Meng,WANG Wurong,WEI Xicheng

(School of Materials Science and Engineering, Shanghai University, Shanghai 200072, China)

Received:2012-08-10 Online:2013-05-28 Published:2013-05-28

摘要/Abstract

摘要：

在不同凸模圆角半径下对800 MPa级双相钢板进行了拉弯成形试验，观察了不同凸模圆角半径下板材极限拉弯深度及板材的断裂位置和断口形貌，对试验结果进行数值模拟，并分析了采用屈服准则Hill、Barlat和BBC的模拟结果.结果表明：对于较大凸模圆角半径（Rp≥2.5 mm）的拉弯试验，在经典成形极限曲线（FLC）判据下，采用Hill准则能够准确预测800 MPa级双相钢板的极限拉弯破裂情况；而对于较小凸模圆角半径（Rp=1.0 mm）的拉弯试验，在FLC判据下，3种屈服准则都无法准确预测双相钢板的破裂情况.

关键词: 高强度双相钢, 数值模拟, 屈服准则, 剪切断裂

Abstract:

The stretch bending limit, fracture location and fracture morphology of 800 MPa dual phase (DP) steel sheets under different punch radii was determined through series of U-shape stretching bending tests. The limit bending test was numerically simulated and three yielding models: Hill, Barlat and BBC were compared in the numerical simulation. For those tests with bigger punch radii (Rp≥2.5 mm), the fracture of limit bending can be predicted using the Hill yielding model, using the traditional forming limit curve (FLC) as fracture criterion. However, the fracture of limit bending can’t be predicted using the same criterion with smaller punch radius (Rp=1.0 mm); the reason is that the necking based traditional FLC neglects the bending effect with smaller punch radii while the bending of 800 MPa DP steel sheets under this condition shows no obvious necking shear fracture, the actual fracture limit is lower than the traditional FLC.

Key words: dual phase sheet, numerical simulation, yielding model, shear fracture

中图分类号:

TG 115.5

谢震，李萌，王武荣，韦习成. 高强度双相钢薄板拉弯成形试验及数值模拟[J]. 上海交通大学学报（自然版）, 2013, 47(05): 760-765.

XIE Zhen,LI Meng,WANG Wurong,WEI Xicheng. Stretch Bending Limit of Dual Phase Sheet and Its Numerical Simulation[J]. Journal of Shanghai Jiaotong University, 2013, 47(05): 760-765.

参考文献

［1］马鸣图, 吴宝榕. 双相钢——物理和力学冶金［M］. 2版. 北京: 冶金工业出版社, 2009.

［2］马鸣图, SHI M F. 先进的高强度钢及其在汽车工业中的应用［J］. 钢铁, 2004, 39 (7): 6872.

MA Mingtu,SHI M F.Advanced high strength steel and its application in automotive industry ［J］. Iron and Steel, 2004, 39(7): 6872.

［3］Mehmet F. A finite element modeling and prediction of stamping formability of a dualphase steel in cup drawing ［J］. Materials and Design, 2012, 34 (12): 3239.

［4］Luo M, Wierzbicki T. Numerical failure analysis of a stretchbending test on dualphase steel sheets using a phenomenological fracture model ［J］. International Journal of Solids and Structures, 2010, 47 (2223): 30843102.

［5］Wang W R, He C W, Zhao Z H, et al. ［J］. Materials and Design, 2011, 32（24）: 33203327.

［6］Hill R. A theory of the yielding and plastic flow of anisotropic metals ［C］∥Proceedings of the Royal Society of Series A: Mathematical and Physical Sciences. London: Royal Society, 1948, 193: 181197.

［7］Barlat F, Lian J. Plastic behavior and stretch ability of sheet metals: Part I. A yield function for or thotropicsheets under plane stress conditions ［J］. International Journal of Plasticity, 1989, 5 (1): 5166.

［8］Banabic D, Comsa D S, Balan T. A new yield criterion for or thotropic sheet metals under plane stress conditios ［C］∥The 7th Conference TPR 2000. Romania, ClujNapoca: Manufacturing in Engineering Division, 2000: 21724.

［9］Stoughton T B, Yoon J W. A new approach for failure criterion for sheet metals ［J］. International Journal of Plasticity, 2011, 27(3): 440459.

[1]	金韬, 高斌, 王强强, 周行, 何文, 冯少孔. 拟共震源高密度面波法数据反演模拟算法及应用[J]. 上海交通大学学报, 2025, 59(7): 1029-1040.
[2]	张强, 陈振华, 王文龙, 苏怀维, 迟德建. 炸点控制对钢筋混凝土T梁桥的毁伤特性数值模拟研究[J]. 空天防御, 2025, 8(5): 83-90.
[3]	巩超, 侯远杭, 张宇骐, 刘殿勇, 万跃进. 畸形波浪环境下的埋首式无人艇水面运动特性[J]. 上海交通大学学报, 2025, 59(4): 447-457.
[4]	王子阳 , 王晓华, 郭冲霄, 等. 串油工艺研究及方法优化[J]. 海洋工程装备与技术, 2025, 12(4): 104-115.
[5]	武晓龙, 夏凯龙, 孟德君, 郝晟淳, 朱铭敏. 非轴对称布局压气机试验与数值模拟研究[J]. 上海交通大学学报, 2025, 59(12): 1916-1928.
[6]	李易, 欧树彦, 梁伟栋, 董佳宝, 庄至栋. 飞行器低空大动压整流罩旋抛分离数值模拟[J]. 空天防御, 2025, 8(1): 102-108.
[7]	徐浩东, 余童真, 樊伟, 李明广, 刘念武. 顶管施工过程中浆液扩散对减阻效果影响[J]. 上海交通大学学报, 2024, 58(7): 1067-1074.
[8]	邓贺方, 夏凯龙, 滕金芳, 羌晓青, 朱铭敏, 卢少鹏. 不同转速下沟槽型机匣对跨声速压气机性能的影响[J]. J Shanghai Jiaotong Univ Sci, 2024, 29(6): 1151-1160.
[9]	刘羿伯1, 毕羽琴1, 马强2, 3, 肖华平1, 刘书海1. 水下螺旋轴流混输泵叶轮的结构设计与优化[J]. 海洋工程装备与技术, 2024, 11(4): 14-20.
[10]	冯漾漾, 丁浩亮, 胡平山, 严波. 注塑模稳态温度场的有限体积法模拟[J]. 上海交通大学学报, 2024, 58(4): 461-467.
[11]	王慧, 杜登轩, 刘海超, 喻国良, 张民曦. 均匀来流中带环翼的复合桩墩的局部冲刷数值试验研究[J]. 海洋工程装备与技术, 2024, 11(3): 1-9.
[12]	郭同彪, 张吉, 李新亮. 压缩拐角强激波边界层干扰直接数值模拟研究[J]. 空天防御, 2024, 7(2): 29-35.
[13]	李树勋，沈恒云，刘斌才，胡迎港，马廷前. 高温熔盐止回阀受熔盐颗粒冲击的压力脉动响应[J]. J Shanghai Jiaotong Univ Sci, 2024, 29(2): 271-279.
[14]	洪蕾1，肖皓1，叶佳2，马国红1. 径向超声波辅助MIG焊电弧的数值模拟[J]. J Shanghai Jiaotong Univ Sci, 2024, 29(2): 330-338.
[15]	张念凡, 肖龙飞, 陈刚. 海洋结构物波浪砰击的数值研究综述[J]. 上海交通大学学报, 2024, 58(2): 127-140.