[1]吴少洋,张建伟,卢凤强,等.18CrNiMo7-6 合金钢J-C 损伤模型失效参数研究[J].郑州大学学报(工学版),2023,44(01):70-76.[doi:10.13705/j.issn.1671-6833.2022.04.015]
 WU S Y,ZHAWu Shaoyang,Zhang Jianwei,et al.Investigation on Failure Parameters of J-C Damage Model of 18CrNiMo7-6 Alloy Steel[J].Journal of Zhengzhou University (Engineering Science),2023,44(01):70-76.[doi:10.13705/j.issn.1671-6833.2022.04.015]
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18CrNiMo7-6 合金钢J-C 损伤模型失效参数研究()
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《郑州大学学报(工学版)》[ISSN:1671-6833/CN:41-1339/T]

卷:
44卷
期数:
2023年01期
页码:
70-76
栏目:
出版日期:
2022-12-06

文章信息/Info

Title:
Investigation on Failure Parameters of J-C Damage Model of 18CrNiMo7-6 Alloy Steel
作者:
吴少洋1 张建伟2 卢凤强1 李元鑫2 秦瑾鸿1
1.郑州大学机械与动力工程学院,河南郑州 450001, 2.郑州大学力学与安全工程学院,河南郑州 450001

Author(s):
WU S Y1 ZHAWu Shaoyang2 Zhang Jianwei1 Lu Fengqiang2 wait.
School of Mechanical and Power Engineering, Zhengzhou University, 450001, Zhengzhou, Henan, School of Mechanics and Safety Engineering, Zhengzhou University, 450001, Zhengzhou, Henan

关键词:
Keywords:
分类号:
O346. 5
DOI:
10.13705/j.issn.1671-6833.2022.04.015
文献标志码:
A
摘要:
针对高速冲击、机械成型加工等数值模拟中广泛应用的Johnson-Cook ( J-C) 损伤模型失效参数求取问题,对18CrNiMo7-6 合金钢材料开展了3 个系列的力学实验。通过缺口试样准静态拉伸实验和有限元模拟,确定了既考虑空间分布效应,又考虑应变累积效应的应力三轴度的计算方法。结果表明:失效应变随应力三轴度的增大而减小;通过10-3 、10、103 s-1 应变率下的拉伸实验与霍普金森拉杆( SHTB) 冲击实验,发现随着应变率的增大,材料屈服强度有所增加,表明了材料有明显的应变率强化效应,并且失效应变随着应变率的增大而增大;在25、200、300、400 ℃ 的拉伸实验中发现随着温度的升高,材料屈服强度逐渐降低,但材料的抗拉强度在300 ℃ 时要高于200 ℃ 下的结果,并且随着温度的升高失效应变逐渐减小。根据上述实验结果拟合得到了J-C 损伤模型失效参数,从拟合优度可以看出拟合所得参数的可靠性。最后通过Taylor 冲击实验与有限元模拟进行验证,结果表明,当冲击速度为430 m / s 时,实验与仿真得到的冲击试样均发生了破坏,并且有限元模拟得到的试样破坏形态与实验结果最大误差为6. 3%,结果吻合良好,验证了所选用的J-C 损伤模型的合理性以及实验所得参数的有效性。
Abstract:
In this study, three series of mechanical tests were carried out on 18CrNiMo7-6 alloy steel materials to determine the damage parameters of the Johnson-Cook (J-C) damage model, which could be widely used in numerical simulations such as high-speed impact and mechanical forming. Through the quasi-static tensile test and finite element simulation of notched specimens, the calculation method of stress triaxiality considering both spatial distribution effect and strain accumulation effect was determined. The results showed that the failure strain decreased with the increase of stress triaxiality. Through the tensile test at 10-3 s-1 , 10 s-1 and 103 s-1 strain rates and the impact test of SHTB, it was found that the yield strength of the material increased with the increase of strain rate, indicating that the material had obvious strain rate strengthening effect, and the failure strain increased with the increase of strain rate. In the tensile tests at 25 ℃ , 200 ℃ , 300 ℃ and 400 ℃ , it was found that the yield strength of the material decreased gradually with the increase of temperature, but the tensile strength of the material at 300 ℃ was higher than that at 200 ℃ , and the failure strain decreased gradually with the increase of temperature. According to the above experimental results, the parameters of J-C damage model were fitted, and the reliability of the fitted parameters could be seen from the goodness of fit. Finally, experimental results and finite element results of Taylor test were compared. The results showed that when the impact speed was 430 m / s, the impact samples obtained from the experiment and simulation were damaged, and the maximum error between the failure mode of the samples obtained by finite element simulation and the experimental results was 6. 3%. The rationality of the J-C damage model selected in this study and the effectiveness of the experimental parameters were verified.

参考文献/References:

[1] 陈刚, 陈忠富, 徐伟芳, 等. 45 钢的 J-C 损伤失效参 量研究[ J] . 爆炸与冲击, 2007, 27(2) : 131-135. 

CHEN G, CHEN Z F, XU W F, et al. Investigation on the J-C ductile fracture parameters of 45 steel[ J] . Explosion and shock waves, 2007, 27(2) : 131-135. 
[2] 张松, 李斌训, 李取浩, 等. 切削过程有限元仿真研 究进展[ J] . 航空制造技术, 2019, 62(13) : 14-28. 
ZHANG S, LI B X, LI Q H, et al. Research deve-lopment of application of finite element method on cutting process [ J ] . Aeronautical manufacturing technology, 2019, 62(13) : 14-28. 
[3] JOHNSON G R, COOK W H. Fracture characteristics of three metals subjected to various strains, strain rates, temperatures and pressures[ J] . Engineering fracture mechanics, 1985, 21(1) : 31-48. 
[4] 李成, 马志垒, 王永涛. 冲击荷载下防弹钢板三维损 伤分析[ J] . 郑州大学学报( 工学版) , 2010, 31( 4) : 85-88. 
LI C, MA Z L, WANG Y T. Three-dimensional da-mage analysis of bullet-proof steel plate under impact loading [ J] . Journal of Zhengzhou university ( engineering science) , 2010, 31(4) : 85-88. 
[5] VASU C, THAWARE A, TIWARI G, et al. Experimental and numerical analysis of orthogonal cutting of high strength aluminium alloy Al7075-T6[ J] . IOP conference series: materials science and engineering, 2021, 1185 (1) : 012010. 
[6] 门建兵, 卢易浩, 蒋建伟, 等. 杆式 EFP 用钽钨合金 JC 失效模型参数[ J] . 高压物理学报, 2020, 34( 6) : 136-143. 
MEN J B, LU Y H, JIANG J W, et al. Johnson-Cook failure model parameters of tantalum-tungsten alloy for rod-shaped EFP [ J ] . Chinese journal of high pressure physics, 2020, 34(6) : 136-143. 
[7] HU X, XIE L J, GAO F N, et al. On the development of material constitutive model for 45CrNiMoVA ultra-highstrength steel[ J] . Metals, 2019, 9(3) : 374. 
[8] 刘治华, 张天增, 杨孟俭, 等. 超声滚压 18CrNiMo7-6 齿轮钢表面变质层性能分析[ J] . 郑州大学学报( 工 学版) , 2020, 41(2) : 44-49, 79. 
LIU Z H, ZHANG T Z, YANG M J, et al. Perfor-mance analysis of surface modification layer of 18CrNiMo7-6 gear steel treated by ultrasonic rolling [ J] . Journal of Zhengzhou university ( engineering science ) , 2020, 41 ( 2 ) : 44-49, 79. 
[9] 张银 霞, 刘 修 武, 原 少 帅, 等. 硬 态 车 削 工 艺 对 18CrNiMo7-6 钢表层硬度及微观组织的影响[ J] . 郑州 大学学报(工学版) , 2022, 43(5) : 59-64.
 ZHANG Y X, LIU X W, YUAN S S, et al. Impact of hard turning process on surface hardness and microstructure of 18CrNiMo7-6 steel[ J] . Journal of Zhengzhou university ( engineering science) , 2022, 43(5) : 59-64.
[10] BRIDGMAN P W. Studies in large plastic flow and fracture[M] . London: Harvard University Press, 1964. 
[11] 高玉龙, 孙晓红. 高速列车用 6008 铝合金动态变形 本构与损伤模型参数研究[ J] . 爆炸与冲击, 2021, 41 (3) : 118-129. 
GAO Y L, SUN X H. On the parameters of dynamic deformation and damage models of aluminum alloy 6008-T4 used for high-speed railway vehicles [ J] . Explosion and shock waves, 2021, 41(3) : 118-129.
[12] 余万 千, 郁 锐, 崔 世 堂. 考 虑 应 力 三 轴 度 影 响 的 30CrMnSiNi2A 钢 韧 性 断 裂 研 究 [ J ] . 爆 炸 与 冲 击, 2021, 41(3) : 47-54. 
YU W Q, YU R, CUI S T. On ductile fracture of 30CrMnSiNi2A steel considering effects of stress triaxiality [ J ] . Explosion and shock waves, 2021, 41 ( 3 ) : 47-54.
[13] GOTO D M, KOSS D A, JABLOKOV V. The influence of tensile stress states on the failure of HY-100 steel[ J] . Metallurgical and materials transactions A, 1999, 30 (11) : 2835-2842. 
[14] 徐广涛, 孙博, 陈海宽, 等. 表面变质层硬度的压痕 表征方 法 [ J] . 郑 州 大 学 学 报 ( 工 学 版) , 2021, 42 (4) : 58-62. 
XU G T, SUN B, CHEN H K, et al. Indentation characterization method for hardness of surface-modified layer [ J] . Journal of Zhengzhou university ( engineering science) , 2021, 42(4) : 58-62. 
[15] 贾东, 黄西成, 莫军. 基于应变路径和分布效应的应 力三轴度确定方法[ J] . 科学技术与工程, 2013, 13 (10) : 2625-2629, 2634. JIA D, HUANG X C, MO J. A method to determine stress triaxiality based on strain path and distribution effect[ J] . Science technology and engineering, 2013, 13 (10) : 2625-2629, 2634.
[16] 国家质量监督检验检疫总局, 中国国家标准化管理委 员会. 金属材料 高应变速率拉伸试验 第 2 部分:液压 伺服型 与 其 他 类 型 试 验 系 统: GB / T 30069. 2—2016 [ S] . 北京: 中国标准出版社, 2016. 
General Administration of Quality Supervision, Inspection and Quarantine of the People′s Republic of China, Stand- ardization Administration of the People′s Republic of China. Metallic materials—tensile testing at high strain rates—part 2: servo-hydraulic and other test systems: GB / T 30069. 2—2016 [ S] . Beijing: Standards Press of China, 2016.
[17] GUPTA N K, IQBAL M A, SEKHON G S. Experimental and numerical studies on the behavior of thin aluminum plates subjected to impact by blunt-and hemisphericalnosed projectiles[ J] . International journal of impact engineering, 2006, 32(12) : 1921-1944. 
[18] DOLZHENKOV I E. The nature of blue brittleness of steel[ J] . Metal science and heat treatment, 1971, 13 (3) : 220-224.
[19] YUSHKEVICH P M, MANANKOVA L V, STEPANOVICH V E. Blue brittleness of steel[ J] . Metal science and heat treatment, 1974, 16(4) : 344-345. 
[20] XIAO X K, MU Z C, PAN H, et al. Effect of the Lode parameter in predicting shear cracking of 2024-T351 aluminum alloy Taylor rods[ J] . International journal of impact engineering, 2018, 120: 185-201

更新日期/Last Update: 2022-12-07