Rebound Law and Precision Compensation Method of Three-dimensional Laser Cutting of High Strength Steel Hot Stamping Structural Parts

doi:10.3969/j.issn.1004-132X.2022.22.012

China Mechanical Engineering ›› 2022, Vol. 33 ›› Issue (22): 2741-2747.DOI: 10.3969/j.issn.1004-132X.2022.22.012

Previous Articles Next Articles

Rebound Law and Precision Compensation Method of Three-dimensional Laser Cutting of High Strength Steel Hot Stamping Structural Parts

LI Shougang1,2,3；LIU Peng4；LIU Xiang4；HU Zhili1,2,3

1.Hubei Key Laboratory of Advanced Technology for Automotive Components,Wuhan University of Technology,Wuhan,430070
2.Hubei Collaborative Innovation Center for Automotive Components Technology,Wuhan University of Technology,Wuhan,430070
3.Hubei Engineering Center of Material Green Precision Forming Technology and Equipment,Wuhan,430070
4.Dongfeng(Wuhan) Industrial Co.,Ltd.,Wuhan,430040

Online:2022-11-25 Published:2022-12-22

高强钢热冲压结构件三维激光切割回弹规律及精度补偿方法

李守港1,2,3；刘鹏4；刘祥4；胡志力1,2,3

1.武汉理工大学现代汽车零部件技术湖北省重点实验室，武汉，430070
2.武汉理工大学汽车零部件技术湖北协同创新中心，武汉，430070
3.武汉理工大学材料绿色成形技术与装备湖北省工程中心,武汉，430070
4.东风（武汉）实业有限公司，武汉，430040

通讯作者: 胡志力(通信作者),男,1983年生,教授、博士研究生导师。研究方向为轻量化技术。E-mail:zhilihuhit@163.com。
作者简介:李守港,男,1997年生,硕士研究生。研究方向为三维激光切割。
基金资助:
国家重点研发计划（2019YFB1704500）；国家自然科学基金（52075400）；湖北省重点研发计划（2020BAB140）

Abstract

Abstract: In order to reduce the influences of springback defects on the cutting accuracy in the three-dimensional laser cutting of high-strength steel body structures, the rebound characteristics was studied by applying three-dimensional laser cutting of hot stamped high-strength steel body components.For high-strength steel car body structure A-pillar, hot stamping and laser cutting finite element models were established respectively by the finite element simulation software AUTOFORM and ABAQUS respectively. The rebound value distribution diagram was obtained through numerical simulation, and the rebound law of the contour of the body structures after cutting was found. The optimal cutting contour was determined according to the direct compensation method based on rebound prediction. The compensation method was validated by cutting the A-pillar semi-finished products. The results show that the contour may be controlled within the tolerance range, the contour errors are decreased by about 28.5%, and the profile rebound is decreased by about 38.3%，by the proposed compensation method,which verify the effectiveness of the compensation method.

Key words: , three-dimensional laser cutting, contour accuracy, rebound, high-strength steel

摘要： 为了减小高强钢车身结构件三维激光切割过程中回弹缺陷对切割精度的影响，将热冲压后的高强钢车身构件应用于三维激光切割，研究其回弹特性。以某车型的高强钢车身结构件A柱为研究对象，利用有限元仿真软件AUTOFORM与ABAQUS分别建立了热冲压和激光切割有限元模型，通过数值模拟得到回弹值分布图，揭示了车身结构件在切割后轮廓的回弹规律。根据基于回弹预测的直接补偿方法对轮廓进行补偿以确定最佳切割轮廓，对A柱冲压半成品进行切割试验验证，试验结果表明，所提补偿方法能够将轮廓误差控制在公差范围内，轮廓误差减小约28.5%，型面回弹减小约38.3%，验证了该补偿方法的有效性。

关键词: 三维激光切割, 轮廓精度, 回弹, 高强钢

CLC Number:

TG156

LI Shougang, LIU Peng, LIU Xiang, HU Zhili, . Rebound Law and Precision Compensation Method of Three-dimensional Laser Cutting of High Strength Steel Hot Stamping Structural Parts[J]. China Mechanical Engineering, 2022, 33(22): 2741-2747.

李守港, 刘鹏, 刘祥, 胡志力, . 高强钢热冲压结构件三维激光切割回弹规律及精度补偿方法[J]. 中国机械工程, 2022, 33(22): 2741-2747.

References

［1］MEKNASSI R F, TISZA M. Recent Third Generations of Advanced High Strength Sheet Steels:Processing Routes and Properties［C］∥EJONS 11th International Conference on Mathematics, Engineering, Natural & Medical Science. Karak,2021.
［2］华林, 魏鹏飞, 胡志力.高强轻质材料绿色智能成形技术与应用［J］. 中国机械工程, 2020, 31(22):2753-2762.
HUA Lin, WEI Pengfei, HU Zhili. Green and Intelligent Forming Technology and Its Applications for High Strength Lightweight Materials［J］. China Mechanical Engineering, 2020, 31(22):2753-2762.
［3］TAHIR A, AQIDA S N. An Investigation of Laser Cutting Quality of 22MnB5 Ultra High Strength Steel Using Response Surface Methodology［J］. Optics & Laser Technology, 2017, 92:142-149.
［4］NAKAGAWA Y, MORI K I, MAENO T, et al. Delayed Cracking in Hot Stamping with Hot Trimming for Ultra-high Strength Steel Components［J］. The International Journal of Advanced Manufacturing Technology, 2019, 105(2):5081-5090.
［5］薛克敏, 孙大智, 李萍, 等. 22MnB5超高强钢热冲压成形工艺及试验［J］. 中国机械工程, 2017, 28(12):1498-1503.
XUE Kemin, SUN Dazhi, LI Ping, et al. Staming Forming Processes and Experiments of 22MnB5 Ultra-high Strength Steels［J］. China Mechanical Engineering,2017, 28(12):1498-1503.
［6］谢延敏, 张飞, 王子豪, 等.基于渐变凹模圆角半径的高强钢扭曲回弹补偿［J］. 机械工程学报, 2019, 55(2):91-97.
XIE Yanmin, ZHANG Fei, WANG Zihao, et al. Compensation of Twist Springback in High-strength Steel Based on Gradient Die Radius［J］. Journal of Mechanical Engineering, 2019, 55(2):91-97.
［7］段磊, 夏磊, 李庆宝, 等. 汽车前梁后部零件全工序成形回弹仿真及模面补偿研究［J］. 锻压技术, 2020, 45(8):62-69.
DUAN Lei, XIA Lei, LI Qingbao, et al. Research on Whole Process Forming Springback Simulation and Die Surface Compensation for Rear Part of Automobile Front Member［J］. Forging & Stamping Technology, 2020, 45(8):62-69.
［8］聂昕, 肖兵兵, 申丹凤, 等. 考虑变形热和摩擦热效应的热力耦合冲压研究［J］. 中国机械工程, 2020, 31(16):2005-2015.
NIE Xin, XIAO Bingbing, SHEN Danfeng, et al. Research on Thermal-mechanical Stamping Forming Considering Deformation Heat and Friction Heat Effects［J］. China Mechanical Engineering, 2020, 31(16):2005-2015.
［9］HAN Fei, MO Jianhua, QI Hongwei,et al. Springback Prediction for Incremental Sheet Forming Based on FEM-PSONN Technology［J］. Transactions of Nonferrous Metals Society of China, 2013, 23(4):1061-1071.
［10］WANG G, LI W L, CHENG J, et al. Trajectory Planning and Optimization for Robotic Machining Based on Measured Point Cloud［J］. IEEE Transactions on Robotics, 2021, 38(3):1621-1637.
［11］HUANG Z, CHEN J, TU Y. A Two-step Feedrate Planning of Polygonal Path for Micro Laser-cutting Machines［J］. International Journal of Advanced Manufacturing Technology, 2019, 103(2):4135-4145.
［12］谢晖, 孟腾逸, 钟志华. 针对激光切割实时回弹的修边线的研究［J］. 锻压技术, 2016, 41(7):27-33.
XIE Hui, MENG Tengyi, ZHONG Zhihua. Research on Trimming Line of Real-time Springback in Laser Cutting［J］. Forging & Stamping Technology, 2016,41(7):27-33.
［13］MAEDA A , JIN Y, KUBOKI T. Light Press of Sheet Metal Edge for Reducing Residual Stress Generated by Laser Cutting Considering Mechanical Properties and Intensity of Residual Stress［J］. Journal of Materials Processing Technology, 2015, 225:178-184.
［14］LIU Y, FU W, LI M , et al. Research on Cutting Path Optimization of Trimming Process［J］. Journal of Physics Conference Series, 2020, 1549:042112.
［15］李亚敏, 咬登治, 范福杰. 激光熔覆718合金工艺参数优化的数值模拟研究［J］.应用激光, 2018, 38(6):920-926.
LI Yamin, YAO Dengzhi, FAN Fujie. Numerical Simulation Study on Process Parameters Optimization of 718 Alloy induced by Laser Cladding［J］. Applied Laser, 2018, 38(6):920-926.

[1]	LI Yingchun, NIE Aonan, YANG Mingxuan, ZHU Dingkang, QIU Ming, YANG Gengsheng. Research on Thermal Characteristics of Auxiliary Bearing in AMBs and Friction Reduction Design [J]. China Mechanical Engineering, 2024, 35(04): 646-655.
[2]	LIANG Yongbin, FU Guang, LIN Zhigui, HE Zhicheng, ZHANG Jialuo, CHEN Tao. Design of Lane Keeping Assist Systems Based on Improved Preview Control Model [J]. China Mechanical Engineering, 2024, 35(03): 548-558.
[3]	HUANG Wei, CHI Cheng. Analysis for Aero -elastic Characteristics of Prop-Rotor in Hover with a Swept Tip [J]. China Mechanical Engineering, 2024, 35(02): 191-200.
[4]	XU Zuolin, HUANG Chuanzhen, LIU Huanlian, LIU Dun. Coating Technology and Mechanism of Modified Diamond Powder by Surface Coating of WC Powders [J]. China Mechanical Engineering, 2024, 35(02): 208-214.
[5]	YUE Jianfeng, LONG Xinyu, HUANG Yunlong, GUO Jialong, LIU Wenji. On-line Identification of Narrow Gap P-GMAW Sidewall Fusion States Based on Arc Acoustic Signals [J]. China Mechanical Engineering, 2024, 35(02): 244-250，259.
[6]	DU Xu, CHANG Zexin, ZHENG Junqiang, REN Pengfei. A Real-time Tool Path Smoothing Algorithm Considering Joint Jerk Constraints [J]. China Mechanical Engineering, 2024, 35(02): 280-286.
[7]	SUN Yuxiang, CHEN Li, LONG Bo, WANG Yanping, LIU Shihua, JIA Kun. Intelligent Layout for Pipeline Supports of Nuclear Power Plant under Complex Load [J]. China Mechanical Engineering, 2024, 35(02): 317-323，336.
[8]	LI Mozhi, ZHU Wenfeng, WANG Shunchao. Roller Pose Compensation in Automotive Body Roll-hemming Forming Process with Adhesive for Dimensional Deviation [J]. China Mechanical Engineering, 2024, 35(02): 364-370.
[9]	WANG Weijun, YANG Guilin, DU Qinghao, CHEN Qingying, . Design of 3K Planetary Gear Reducers with No Backlash [J]. China Mechanical Engineering, 2024, 35(01): 36-44,55.
[10]	GAO Jin, CUI Haibing, FAN Tao, LI Ang, DU Zunfeng. A Structural Reliability Calculation Method Based on Adaptive Kriging Ensemble Model [J]. China Mechanical Engineering, 2024, 35(01): 83-92.
[11]	SUN Haitao, ZHAN Mei, FAN Xiaoguang, GUO Jing, HAN Chao, ZHANG Jun. Research Progresses and Prospects of Compression Molding of High-performance PBX [J]. China Mechanical Engineering, 2024, 35(01): 160-180.
[12]	ZHU Fuxian, QIU Gang, ZHU Xingmin, XU Xianyi, ZHOU Jinyu. Failure Mode and Progressive Damage Analyses of Carbon-glass Hybrid Composite Single Nail and Single Shear Bolted Joints [J]. China Mechanical Engineering, 2023, 34(23): 2781-2793.
[13]	HAO Zhuangzhuang, ZHANG Qingchun, HU Yunbo, GUO Yibin, WANG Donghua, LI Wanyou. Research on Influences of Tooth Friction and Geometric Eccentricity Errors on Mesh Stiffness of Profile Shifted Spur Gear Pairs [J]. China Mechanical Engineering, 2023, 34(23): 2812-2823.
[14]	YU Shubo, LIU Zhansheng, ZHAO Chen. Dynamics Simulation Data Driven Domain Adaptive Intelligent Fault Diagnosis [J]. China Mechanical Engineering, 2023, 34(23): 2832-2841.
[15]	LIU Xiaobao, YAN Qingxiu, YI Bin, YAO Tingqiang, GU Wenjuan. Optimization of Process Parameters in Process Manufacturing Based on Ensemble Learning and Improved Particle Swarm Optimization Algorithm [J]. China Mechanical Engineering, 2023, 34(23): 2842-2853.

Rebound Law and Precision Compensation Method of Three-dimensional Laser Cutting of High Strength Steel Hot Stamping Structural Parts

高强钢热冲压结构件三维激光切割回弹规律及精度补偿方法

PDF

Knowledge

Abstract

Cite this article

share this article

References

Related Articles 15

Recommended Articles

Metrics