Numerical simulation of precipitate evolution in ferritic–martensitic power plant steels

Abstract

Thermo-kinetic simulation of precipitate evolution during long-term thermal exposure in ferritic–martensitic heat-resistant power plant steels (P91 and P92) is carried out using MatCalc software, in combination with a Gibbs energy database and a mobility database for steels that come with MatCalc. MX and M23C6 are predicted to remain as major precipitates during long-term thermal exposure in these steels. Average size of MX precipitate is found to vary between 10 and 50 nm in both steels, while M23C6 exceeds 100 nm in the case of P91 after 1000,000 h of thermal exposure at 600 °C. The simulated precipitation sequence and precipitate size evolution during thermal exposure are in good agreement with available experimental data. It is expected that the calculations presented here give insight into long-term microstructural stability of ferritic–martensitic steels under service conditions, which is otherwise difficult to establish by experiments alone.