4.2 Article

Microstructure and mechanical properties of 1000 MPa grade steel plate for hydropower station in different quenching processesGefuge und mechanische Eigenschaften einer 1000 MPa-Stahlplatte fur Wasserkraftwerke nach verschiedenen Warmebehandlungsprozessen

期刊

MATERIALWISSENSCHAFT UND WERKSTOFFTECHNIK
卷 53, 期 5, 页码 564-575

出版社

WILEY-V C H VERLAG GMBH
DOI: 10.1002/mawe.202100282

关键词

Hydropower station; 1000 MPa grade steel; Quenching; Strength; Toughness; Microstructure

资金

  1. Baowu Steel Group Co., Ltd. [U1660205]
  2. National Natural Science Foundation of China

向作者/读者索取更多资源

The strength and toughness of ferrum-1.2manganese-1.4nickel steel plates in the DQT and DQQT processes were investigated. It was found that the DQT process resulted in flat prior austenite grains and nano-scaled precipitates, while the DQQT process led to growth of grains and precipitates and a decrease in dislocation density. Furthermore, the DQT process exhibited higher yield strength compared to the DQQT process, but the DQQT process showed superior impact energy.
Strength and toughness of the ferrum-1.2manganese-1.4nickel steel plates in the DQT (direct quenching -> tempering) and DQQT (direct quenching -> reheated quenching -> tempering) processes were investigated. This ferrum-1.2manganese-1.4nickel which possessed a relatively low alloy content and improved purity was used as the 1000 MPa grade high-strength steel plates for hydropower station. The flat prior austenite grains with the dislocation density of 4.86x10(14) m(-2) and nano-scaled precipitates were acquired in the DQT process. The grains and precipitates grew up and the dislocation density decreased to 4.26x10(14) m(-2) as a result of reheated quenching in the DQQT process. After tempering, the yield strength of the specimen treated by the DQT process was similar to 996 MPa, which was similar to 34 MPa higher than that of the DQQT sample. The difference of yield strength between these two quenching processes was primarily ascribed to grain boundary strengthening and partly caused by dislocation strengthening or precipitation strengthening. Due to the circular propagation path of cracks and matrix softening, the impact energy at -60 degrees C in the DQQT process was superior to that of the DQT process.

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