The microstructure formation processes in HK40 and HH40 alloys were investigated through JmatP ro calculations and quenching performed during directional solidification. The phase transition routes of HK40 and HH40 al...The microstructure formation processes in HK40 and HH40 alloys were investigated through JmatP ro calculations and quenching performed during directional solidification. The phase transition routes of HK40 and HH40 alloys were determined as L → L + γ→ L + γ + M_7C_3 →γ + M_7C_3 →γ + M_7C_3 + M_(23)C_6→γ + M_(23)C_6 and L → L + δ→ L + δ + γ→ L + δ + γ + M_(23)C_6→δ + γ + M_(23)C_6, respectively. The solidification mode was determined to be the austenitic mode(A mode) in HK40 alloy and the ferritic–austenitic solidification mode(FA mode) in HH40 alloy. In HK40 alloy, eutectic carbides directly precipitate in a liquid and coarsen during cooling. The primary γ dendrites grow at the 60° angle to each other. On the other hand, in HH40 alloy, residual δ forms because of the incomplete transformation from δ to γ. Cr_(23)C_6 carbide is produced in solid delta ferrite δ but not directly in liquid HH40 alloy. Because of carbide formation in the solid phase and no rapid growth of the dendrite in a non-preferential direction, HH40 alloy is more resistant to cast defect formation than HK40 alloy.展开更多
基金he financial support provided by the National High-Tech Research and Development Program of China (No. 2012AA03A511)
文摘The microstructure formation processes in HK40 and HH40 alloys were investigated through JmatP ro calculations and quenching performed during directional solidification. The phase transition routes of HK40 and HH40 alloys were determined as L → L + γ→ L + γ + M_7C_3 →γ + M_7C_3 →γ + M_7C_3 + M_(23)C_6→γ + M_(23)C_6 and L → L + δ→ L + δ + γ→ L + δ + γ + M_(23)C_6→δ + γ + M_(23)C_6, respectively. The solidification mode was determined to be the austenitic mode(A mode) in HK40 alloy and the ferritic–austenitic solidification mode(FA mode) in HH40 alloy. In HK40 alloy, eutectic carbides directly precipitate in a liquid and coarsen during cooling. The primary γ dendrites grow at the 60° angle to each other. On the other hand, in HH40 alloy, residual δ forms because of the incomplete transformation from δ to γ. Cr_(23)C_6 carbide is produced in solid delta ferrite δ but not directly in liquid HH40 alloy. Because of carbide formation in the solid phase and no rapid growth of the dendrite in a non-preferential direction, HH40 alloy is more resistant to cast defect formation than HK40 alloy.
