Evolution of Microstructures of a Low Carbon Bainitic Steel Held at High Service Temperature

doi:10.1007/s40195-014-0078-7

Abstract

Abstract:

Low carbon bainitic steel derives the high strength mainly from high density of dislocations rather than carbon and alloy element content, so it tends to evolve into equilibrium microstructure with low density of dislocations under thermal disturbance. In the present investigation, granular bainite and lath-like bainitic ferrite were produced respectively in Mo-free low-carbon steels by changing cooling rate. It has been found that granular bainite possesses a lower strength at room temperature than bainitic ferrite, but it exhibits a slower decrease of strength with temperature increasing. Dislocation density in both granular bainite and bainitic ferrite decreases via recovery and recrystallization at high temperature. However, when reheating of bainite is carried out at temperature below 600 °C, a long time will be needed for incubation of recrystallization, during which the hardness of bainite maintains stable. The property makes bainite, especially granular bainite, become a potential microstructure for matrix of high strength fire-resistant steel.

Key words: Low carbon bainitic steel, High temperature strength, Microstructure evolution, Recrystallization, Bainite

Chao Sun, Shanwu Yang, Guoliang Liu. Evolution of Microstructures of a Low Carbon Bainitic Steel Held at High Service Temperature[J]. Acta Metallurgica Sinica (English Letters), 2014, 27(3): 436-443.

Figures/Tables 11

Fig. 1 CCT curves of the experimental steel. Cooling rates are labeled beside cooling curves, and Vickers hardness values of the samples are labeled in circles at the ends of cooling curves

Fig. 2 Microstructures of GB-steel, BF-steel, and PF-steel: a optical metallograph of GB-steel; b secondary electron image of GB-steel; c optical metallograph of BF-steel; d secondary electron image of BF-steel

Fig. 3 Force-displacement curves and energy-displacement curves of the GB-steel and the BF-steel measured through instrumented Charpy V-notch pendulum impact tests at room temperature

Fig. 4 Optical metallograph of PF-steel

Fig. 5 Variations in the strength of experimental steels with temperature and holding time: a proof strength Rp0.2 with temperature; b ratio of Rp0.2 at high temperature to Rp0.2 at room temperature with temperature; c remained strengthening effect of bainitic transformation with temperature; dRp0.2 with holding time during isothermal holding at 600 °C

Fig. 6 TEM images showing granular bainite a bainitic ferrite b

Fig. 7 Evolution of dislocation configuration during isothermal holding at 600 °C by TEM: a before reheating; b after holding for 1 h; c, d after holding for 12 h

Fig. 8 Partial disappearance of lath boundary in the steel after isothermal holding at 600 °C for 6 h by TEM

Fig. 9 Optical metallographic observation of granular bainite a bainitic ferrite b in the steel after holding at 600 °C for 48 h

Fig. 10 Hardness variation of BF-steel during isothermal holding at 600 and 650 °C

Fig. 11 Optical metallographic observation of BF-steel after isothermal holding at 600 °C for different times of 15 min a, 16 h b, 64 h c, 192 h d

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