冷加工316L不锈钢裂尖力学分析
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摘要
为了研究冷加工对316L不锈钢裂尖力学特性的影响,采用有限元模拟分析了单轴拉伸和冷轧-拉伸不锈钢应力腐蚀裂尖应力-应变状态。结果表明:随着拉伸变形量的增加,单轴拉伸和冷轧-拉伸裂尖Mises应力、等效塑性应变、拉伸应力和拉伸应变均有不同程度的增大。预冷轧改变了316 L钢的力学参量,因而影响了裂尖应力-应变状态,拉伸变形量相同时,冷轧-拉伸裂尖应力应变均不同程度地大于单轴拉伸裂尖应力、应变,但随着拉伸变形量的增加,冷轧-拉伸和单轴拉伸裂尖应力差逐渐减小,应变差有所增加。
In order to study the effect of cold working on the mechanical properties of 316 L stainless steel, the stress-strain state of stress corrosion cracking tip of stainless steel in uniaxial tension and cold rolling-tension was analyzed by finite element simulation. The results show that with the increase of tensile deformation amount, the Mises stress, equivalent plastic strain, tensile stress and tensile strain of uniaxial tensile and cold rolling tension crack tip increase in different degrees.The mechanical parameters of 316 L steel are changed by pre-cold rolling, which affects the stress-strain state of the crack tip.When the tensile deformation amount is the same, the stress and strain of cold rolling-tension crack tip are higher than those of uniaxial tension in different degree. However, with the increase of tensile deformation, the stress difference of crack tip between cold rolling-tension tension specimens decreases gradually, and the strain difference increases.
In order to study the effect of cold working on the mechanical properties of 316 L stainless steel, the stress-strain state of stress corrosion cracking tip of stainless steel in uniaxial tension and cold rolling-tension was analyzed by finite element simulation. The results show that with the increase of tensile deformation amount, the Mises stress, equivalent plastic strain, tensile stress and tensile strain of uniaxial tensile and cold rolling tension crack tip increase in different degrees.The mechanical parameters of 316 L steel are changed by pre-cold rolling, which affects the stress-strain state of the crack tip.When the tensile deformation amount is the same, the stress and strain of cold rolling-tension crack tip are higher than those of uniaxial tension in different degree. However, with the increase of tensile deformation, the stress difference of crack tip between cold rolling-tension tension specimens decreases gradually, and the strain difference increases.
引文
[1] Yang Hongliang, Xue He, Yang Fuqiang, et al.Effect of film-induced stress on mechanical properties at stress corrosion cracking tip[J].Rare Metal Materials and Engineering,2017,46(12):3595-3600.
[2] Ahmed I I, Grant B, Sherry A H, et al.Deformation path effects on the internal stress development in cold worked austenitic steel deformed in tension[J].Materials Science&Engineering A,2014,614:326-337.
[3]侯娟,彭群家,庄子哲雄,等.镍基合金焊接过渡区微观结构及应力腐蚀行为研究[J].金属学报,2010,46(10):1258-1266.
[4] Du Donghai, Chen Kai, Lu Hui, et al.Effects of chloride and oxygen on stress corrosion cracking of cold worked 316/316L austenitic stainless steel in high temperature water[J].Corrosion Science,2016,110:134-142.
[5] Hou J, Shoji T, Lu Z P, et al.Residual strain measurement and grain boundary characterization in the heat affected zone of a weld joint between alloy 690TT and alloy 52[J].Journal of Nuclear Materials,2010,397:109-115.
[6] Xue He, Li Yongqiang.Micro-mechanical state at tip of environmentally assisted cracking in nickel-based alloy[J].Rare Metal Materials and Engineering,2016,45(3):0537-0541.
[7] Masayuki Kamaya.Elastic-plastic failure assessment of cold worked stainless steel pipes[J].International Journal of Pressure Vessels and Piping,2015,131:45-51.
[8] Masayuki Kamaya, Masahiro Kawakubo.True stress-strain curves of cold worked stainless steel over a large range of strains[J].Journal of Nuclear Materials,2014,451:264-275.
[9] Masayuki Kamaya, Takumi Haruna.Crack initiation model for sensitized 304 stainless steel in high temperature water[J].Corrosion Science,2006,48:2442-2456.
[10]杨宏亮,薛河,赵凌燕,等.氧化膜形状对镍基合金应力腐蚀裂尖应力应变的影响[J].热加工工艺,2016,45(20):58-60.
[2] Ahmed I I, Grant B, Sherry A H, et al.Deformation path effects on the internal stress development in cold worked austenitic steel deformed in tension[J].Materials Science&Engineering A,2014,614:326-337.
[3]侯娟,彭群家,庄子哲雄,等.镍基合金焊接过渡区微观结构及应力腐蚀行为研究[J].金属学报,2010,46(10):1258-1266.
[4] Du Donghai, Chen Kai, Lu Hui, et al.Effects of chloride and oxygen on stress corrosion cracking of cold worked 316/316L austenitic stainless steel in high temperature water[J].Corrosion Science,2016,110:134-142.
[5] Hou J, Shoji T, Lu Z P, et al.Residual strain measurement and grain boundary characterization in the heat affected zone of a weld joint between alloy 690TT and alloy 52[J].Journal of Nuclear Materials,2010,397:109-115.
[6] Xue He, Li Yongqiang.Micro-mechanical state at tip of environmentally assisted cracking in nickel-based alloy[J].Rare Metal Materials and Engineering,2016,45(3):0537-0541.
[7] Masayuki Kamaya.Elastic-plastic failure assessment of cold worked stainless steel pipes[J].International Journal of Pressure Vessels and Piping,2015,131:45-51.
[8] Masayuki Kamaya, Masahiro Kawakubo.True stress-strain curves of cold worked stainless steel over a large range of strains[J].Journal of Nuclear Materials,2014,451:264-275.
[9] Masayuki Kamaya, Takumi Haruna.Crack initiation model for sensitized 304 stainless steel in high temperature water[J].Corrosion Science,2006,48:2442-2456.
[10]杨宏亮,薛河,赵凌燕,等.氧化膜形状对镍基合金应力腐蚀裂尖应力应变的影响[J].热加工工艺,2016,45(20):58-60.