Numerical simulation of dendrite growth in Ni-based superalloy casting during directional solidification process
(1. Key Laboratory for Advanced Materials Processing Technology, Ministry of Education, School of Materials Science and Engineering, Tsinghua University, Beijing 100084, China;
2. Dongfang Turbine Co., Ltd., Deyang 618000, China;
3. Long-life High Temperature Materials State Key Laboratory, Deyang 618000, China)
2. Dongfang Turbine Co., Ltd., Deyang 618000, China;
3. Long-life High Temperature Materials State Key Laboratory, Deyang 618000, China)
Abstract: An understanding of dendrite growth is required in order to improve the properties of castings. For this reason, cellular automaton-finite difference (CA-FD) method was used to investigate the dendrite growth during directional solidification (DS) process. The solute diffusion model combined with macro temperature field model was established for predicting the dendrite growth behavior. Model validation was performed by the DS experiment, and the cooling curves and grain structures obtained by the experiment presented a reasonable agreement with the simulation results. The competitive growth of dendrites was also simulated by the proposed model, and the competitive behavior of dendrites with different misalignment angles was also discussed in detail. Subsequently, 3D dendrites growth was also investigated by experiment and simulation, and both were in good accordance. The influence on dendrites growth of initial nucleus was investigated by three simulation cases, and the results showed that the initial nuclei just had an effect on the initial growth stage of columnar dendrites, but had little influence on the final dendritic morphology and the primary dendrite arm spacing.
Key words: numerical simulation; directional solidification; dendrite growth; Ni-based superalloy