Effect of vanadium on the microstructure and mechanical properties of 7Mn steel during cold rolling process
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摘要: 在7Mn中锰钢的基础上,向其添加不同含量的V元素,通过冷轧及退火处理,初步探究0.1%~0.3% V添加量对其组织和力学性能的影响规律。结果表明,当V添加量为0.3%时,试验钢的综合力学性能最优,屈服强度为993.96 MPa,抗拉强度为1164.56 MPa,伸长率为37.55%,强塑积为43.73 GPa·%,这是由于V在钢中形成细小弥散的第二相,在细晶强化、第二相强化和TRIP效应的共同作用下提高了试验钢的综合力学性能。Abstract: On the basis of 7Mn medium manganese steel, different contents of V element were added. Through cold rolling and annealing treatment, the influence of 0.1%~0.3% V addition on the microstructure and mechanical properties of the steel was preliminarily explored. The experimental results show that when the content of V is 0.3%, the comprehensive mechanical properties of the experimental steel are the best. The yield strength is 993.96 MPa, with the tensile strength 1164.56 MPa, the elongation 37.55%, and the strength and elongation product 43.73 GPa·%. This is because V forms a fine and dispersed second phase in the steel, which improves the comprehensive mechanical properties of the experimental steel under the combined effects of fine grain strengthening, second phase strengthening and TRIP effect.
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Key words:
- medium manganese steel /
- V microalloying /
- TRIP effect /
- mechanical properties
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图 1 7 Mn钢相组成模拟计算结果
Figure 1. Simulation results of the phase composition of 7 Mn steel
图 3 不同V添加量的冷轧态7Mn钢在650 ℃下退火1 h后空冷的SEM图像
Figure 3. SEM images of cold-rolled 7 Mn steels with different V additions after annealing at 650 ℃ for 1 h and air cooling
(a)0.1V; (b)0.2V; (c)0.3V
图 4 冷轧态7Mn钢不同V添加量下的TEM图像
(a)0.1V; (b)0.2V; (c)0.3V; (d)析出物的EDS谱图
Figure 4. TEM images of cold-rolled 7Mn steel with different V additions
图 5 不同V添加量的7Mn钢的XRD图谱及奥氏体含量与转化率计算情况
(a)拉伸试样断裂前XRD图谱;(b)拉伸试样断裂后XRD图谱; (c)奥氏体百分含量和奥氏体转变率
Figure 5. XRD diffraction patterns of 7Mn steel with different V additions and the calculation of austenite contents and conversion rates
图 6 不同V添加量的7 Mn钢的真应力应变曲线和加工硬化曲线
(a)真应力应变曲线; (b)加工硬化曲线
Figure 6. True stress-strain and work hardening rate curves of 7 Mn steels with different V additions
图 7 拉伸试样断口形貌
Figure 7. Fracture morphology of the specimen after tensile tests
(a)0.1V; (b)0.2V; (c)0.3V
表 1 试验钢化学成分
Table 1. Chemical compositions of the testing steels
% 编号 V C Mn Al Si Fe 0.1 V 0.06 0.19 7.3 1.10 0.09 余量 0.2 V 0.22 0.19 7.3 1.20 0.04 余量 0.3 V 0.33 0.19 7.3 1.20 0.04 余量 
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表 2 不同V添加量的7Mn钢的力学性能
Table 2. Mechanical properties of 7Mn steel with different V additions
试验钢 屈服强度/MPa 抗拉强度/MPa 延伸率/% 强塑积/(GPa·%) 0.1 V 818.15 1086.40 26.20 28.46 0.2 V 909.60 1162.84 35.39 41.15 0.3 V 993.96 1164.56 37.55 43.73
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