回火
材料科学
碳化物
降水
成核
合金
晶界
冶金
粒度
延伸率
沉淀硬化
极限抗拉强度
复合材料
微观结构
物理
有机化学
气象学
化学
作者
Wei Zhao,Hongwei Zhou,Liangwei Fang,Fengmei Bai,Hailong Yi,Naqash Ali,Liqiang Zhang,Zhen Guang-wen
标识
DOI:10.1002/srin.202000723
摘要
Herein, the precipitation and mechanical properties of high‐strength low‐alloy steel (Q960E) under different tempering temperatures from 560 to 640 °C are investigated. Diversified precipitations (including MC, M 3 C, M 23 C 6 , and M 7 C 3 ) are formed during tempering. The size of the M 3 C, M 23 C 6 , and M 7 C 3 precipitates increases, as the temperature increases, and the precipitates are gradually spheroidized with an average size of less than 100 nm. MC‐type precipitates (where M = Nb and Ti) are produced at different tempering temperatures. When tempered at 600 °C, Q960E steel exhibits excellent mechanical properties, including a high strength and elongation with a good impact performance. At 600 °C, a large number of fine MC carbides with an average size of less than 25 nm are formed. MC and matrix exhibit the Baker–Nutting orientation relationship. Edge dislocations exist in the transition region between the MC nanophase and the matrix. These dislocations reduce the mismatch degree between the MC nanophase and the matrix and promote MC nucleation. Meanwhile, the steel retains many low‐angle grain boundaries when tempered at 600 °C, which is beneficial to its high strength.
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