论文信息 - Influence of different cooling rates on the microstructure of the HAZ and welding CCT diagram of CLAM steel

Influence of different cooling rates on the microstructure of the HAZ and welding CCT diagram of CLAM steel

Abstract The evolution of microstructure in the weld HAZ (Heat Affected Zone) under welding thermal cycle was simulated by Gleeble-1500. The microstructures and properties of HAZ at different cooling rates were investigated by optical microscopy (OM), scanning electron microscopy (SEM) and microhardness test. The results showed that when the cooling rates ranged from 3600 K/min to 60 K/min, fully martensitic transformations were achieved, and the cooling rates had little influence on the microstructure and microhardness of martensite. The maximum cooling rate to form ferrite was 60 K/min. When the cooling rates ranged from 60 K/min to 1 K/min, the microhardness of the HAZ began to decrease due to the presence of ferrite, and the lath sizes grew up to 0.13–0.15 μm. The critical cooling rate to gain fully ferrite was found to be slower than 1 K/min. The welding CCT diagram of CLAM steel was constructed and it showed that there were ferrite and martensite transformation regions only. The diagram made it possible to predict the microstructures and properties of HAZ and became an important tool to evaluate weldability of CLAM steel.

[1] Liqin Hu,et al. Conceptual design of the fusion-driven subcritical system FDS-I , 2006 .

[2] Yican Wu,et al. Conceptual design and testing strategy of a dual functional lithium–lead test blanket module in ITER and EAST , 2007 .

[3] Qunying Huang,et al. Progress in development of China Low Activation Martensitic steel for fusion application , 2007 .

[4] Huang Qunying,et al. Activation Characteristics of Fuel Breeding Blanket Module in Fusion Driven Subcritical System , 2004 .

[5] Yican Wu,et al. Design status and development strategy of China liquid lithium-lead blankets and related material technology , 2007 .

[6] A. Álamo,et al. Physical metallurgy and mechanical behaviour of FeCrWTaV low activation martensitic steels: Effects of chemical composition , 1998 .

[7] Qunying Huang,et al. Study of irradiation effects in China low activation martensitic steel CLAM , 2004 .

[8] Yican Wu,et al. Conceptual design activities of FDS series fusion power plants in China , 2006 .

[9] David S. Gelles,et al. Status of reduced activation ferritic/martensitic steel development , 2007 .

[10] E. Diegele,et al. The development of EUROFER reduced activation steel , 2003 .

[11] M. Schirra,et al. First results on the characterisation of the reduced-activation-ferritic-martensitic steel EUROFER , 2001 .

[12] Yixue Chen,et al. Activation analysis of structural materials irradiated by fusion and fission neutrons , 2002 .