Controlling Factor for Maximum Tensile Stress and Elongation of Aluminum Alloy during Partial Solidification

抄録

To predict hot tearing of direct chill casting ingot, both the tensile constitutive behavior and elongation of alloy are inevitable during partial solidification. For predicting both the maximum true stress σ_ss and the elongation ε_elong regardless of alloy systems, their dominant factor was examined in terms of the solidification microstructure. For an Al–Mg and an Al–Cu alloys, (i) temperature T dependences of the maximum true stress and elongation (σ_ss = f(T) and ε_elong = f(T)) and (ii) dihedral angle θ of liquid phase formed at grain boundary were measured experimentally. Then, fraction of solid cohesion C was determined by the Campbell’s model using the angle.

Firstly, the solid fraction dependence of the tensile properties (σ_ss = f(f_s) and ε_elong = f(f_s)) were compared between the two alloys. The two dependences differ with each other. Secondly, the fraction of solid cohesion dependences of the tensile properties (σ_ss = f(C) and ε_elong = f(C)) were compared and the result shows that the two dependences were consistent with each other. The fraction of solid cohesion enables to explain the difference in solid fraction dependence of the tensile properties for the two alloys. The result demonstrates that the dihedral angle should be essential to predict the two tensile properties of alloy during partial solidification.

 

This Paper was Originally Published in Japanese in J. JILM 69 (2019) 255–262.

Fig. 8 Solid cohesion dependence of tensile properties for two alloys in partially solidified state: (a) normalized stress and (b) elongation.