Transactions of Materials and Heat Treatment

Title：Research on rotary-torsion low-stress precision blanking mechanism based on coupled meso-damage model

Authors： Li Pengwei1 Wang Zhe1 Yu Zhengyang2

Unit： 1.Xi′an Aeronautical Polytechnic Institute 2.Xi′an University of Science and Technology

KeyWords： rotary-torsion low-stress precision blanking coupled meso-damage model damage evolution 304 stainless steel

ClassificationCode：TG316

year,vol(issue):pagenumber：2024,49(6):260-268

Abstract：

Rotary-torsion low-stress precision blanking has the characteristics of low consumption, high efficiency and high quality, and accurate damage prediction can lay a theoretical foundation for the selection of near-net shape forming process parameters for rotary-torsion low-stress precision blanking. Therefore, a coupled meso-damage model based on meso-damage mechanical theory and equivalent critical fracture strain-stress triaxiality theory was applied to predict the damage evolution during precision blanking, and the coupled meso-damage model parameters of 304 stainless steel were calibrated by the methods of microscopic analysis, theoretical analysis and reverse solution. Then, by comparing and analyzing the load-displacement curves obtained by coupled meso-damage model and uniaxial tensile experiment, the rationality of the coupled meso-damage model and its parameters was verified. Furthermore, the damage evolution process of rotary-torsion low-stress precision blanking under different loading speeds was numerically analyzed, and the precision blanking experiments were conducted to verify the correctness of numerical simulation results. The results show that the reasonable blanking efficiency and cross-section accuracy of blank can be obtained when the loading speed is 3 mm·s-1 depending on the comprehensive evaluation index of blanking quality as cross-section flatness and blanking time. Thus, the coupled meso-damage model can be used to predict the damage evolution of near-net shape forming method for rotary-torsion low-stress precision blanking, which provides the theoretical support for the reasonable selection of subsequent precision blanking process parameters.

Funds：

陕西省教育厅科学研究计划项目 (22JK0428）

作者简介：李鹏伟（1992-），男，硕士，讲师，E-mail：625813219@qq.com

Reference：

[1]钟斌,李雪伍,于正洋，等.304不锈钢棒气动式可控旋弯下料工艺及试验[J].机械工程学报, 2018, 54(22): 47-54.

Zhong B, Li X W, Yu Z Y, et al. Process and experimental research of controllable pneumatic rotary bending cropping of 304 stainless steel bar[J]. Journal of Mechanical Engineering, 2018,54(22):47-54.

[2]赵升吨,任芋见,杨昌群,等.低应力疲劳裂纹可控式精密分离技术[J].塑性工程学报,2020,27(12):1-8.

Zhao S D, Ren Y J, Yang C Q, et al. Low-stress fatigue crack controllable precision cropping technology[J]. Journal of Plasticity Engineering, 2020,27 (12):1-8.

[3]Gurson A L. Continuum theory of ductile rupture by void nucleation and growth: Part I-Yield criteria and flow rules for porous ductile media[J]. Journal of Engineering Materials and Technology, 1977, 99(1): 2-15.

[4]Tvergaard V. Influence of voids on shear band instabilities under plane-strain conditions[J].International Journal of Fracture, 1981, 17(4): 389-407.

[5]Needleman A, Tvergaard V. An analysis of ductile rupture in notched bars[J]. Journal of the Mechanics and Physics of Solids, 1984, 32(6): 461-490.

[6]Wu H, Xu W C, Shan D B, et al. An extended GTN model for low stress triaxiality and application in spinning forming[J]. Journal of Materials Processing Technology, 2019, 263: 112-128.

[7]Wang S, Chen Z H, Dong C F. Tearing failure of ultra-thin sheet-metal involving size effect in blanking process: Analysis based on modified GTN model[J]. International Journal of Mechanical Sciences, 2017, 133: 288-302.

[8]Zhao P J, Chen Z H, Dong C F. Investigation and prediction of tearing failure during extrusion based on a modified shear damage model[J]. Mechanics of Materials, 2017, 112:28-39.

[9]Jiang W, Li Y Z, Su J. Modified GTN model for a broad range of stress states and application to ductile fracture[J]. European Journal of Mechanics-A/Solids, 2016, 57: 132-148.

[10]Bao Y B, Wierzbicki T. On fracture locus in the equivalent strain and stress triaxiality space[J]. International Journal of Mechanical Sciences, 2004, 46(1): 81-98.

[11]Xue L. Constitutive modeling of void shearing effect in ductile fracture of porous materials [J]. Engineering Fracture Mechanics, 2008, 75(11): 3343-3366.

[12]Nahshon K, Hutchinson J W. Modification of the Gurson model for shear failure[J]. European Journal of Mechanics-A/Solids, 2008, 27(1): 1-17.

[13]Malcher L, Pires F M A, Sá J M A C. An extended GTN model for ductile fracture under high and low stress triaxiality[J]. International Journal of Plasticity, 2014, 54(2): 193-228.

[14]Zhou J, Gao X S, Sobotka J C, et al. On the extension of the Gurson-type porous plasticity models for prediction of ductile fracture under shear-dominated conditions[J]. International Journal of Solids and Structures, 2014, 51(18): 3273-3291.

[15]Oh C S, Kim N H, Kim Y J, et al. A finite element ductile failure simulation method using stress-modified fracture strain model[J]. Engineering Fracture Mechanics,2011,78(1):124-137.

[16]Kim N H, Oh C S, Kim Y J, et al. Comparison of fracture strain based ductile failure simulation with experimental results[J]. International Journal of Pressure Vessels and Piping, 2011,88(10): 434-447.

[17]Gardner L. Stability and design of stainless steel structures-Review and outlook[J]. Thin-Walled Structures,2019,141: 208-216.

[18]Swift H W. Plastic instability under plane stress[J]. Journal of the Mechanics and Physics of Solids,1952,1(1): 1-18.

[19]Hooputra H, Metzmacher G, Werner H. Fracture criteria for crashworthiness simulation of wrought aluminum alloy components[A]. Proceedings of the 11th Annual European Conference[C]. Heidelberg, 2001.

[20]Hooputra H, Gese H, Dell H, et al. A comprehensive failure model for crashworthiness simulation of aluminum extrusions[J]. International Journal of Crashworthiness, 2004, (5): 449-463.

[21]Abendroth M, Kuna M. Determination of deformation and failure properties of ductile materials by means of the small punch test and neural networks[J]. Computational Materials Science, 2003, 28(3-4):633-644.

[22]钟斌,王攀,于正洋,等.新型低应力下料工艺实验研究与数值模拟[J]. 精密成形工程, 2022, 14 (7):58-63.

Zhong B, Wang P, Yu Z Y, et al. Experimental research and numerical simulation of new low-stress cropping process[J]. Journal of Netshape Forming Engineering, 2022, 14 (7):58-63.

[23]于正洋, 钟斌, 李进,等. 新型低应力致裂精密下料装置试验研究[J.]. 锻压技术, 2022,47 (3):125-130.

Yu Z Y, Zhong B, Li J, et al. Test study on new type low stress cracking precision blanking device[J]. Forging & Stamping Technology, 2022,47 (3):125-130.

[24]唐勇, 赵升吨, 王振伟. 金属棒料精密下料新工艺及实验研究[J]. 中国机械工程, 2010, 21(3): 359-363.

Tang Y, Zhao S D, Wang Z W. Experimental study on new precision cropping process for metal bars[J]. China Mechanical Engineering, 2010, 21(3):359-363.

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