Litcius/Paper detail

Multi-Phase Field Method for Solidification Microstructure Evolution for a Ni-Based Alloy in Wire Arc Additive Manufacturing

Sukeharu Nomoto, Masahiro Kusano, Houichi Kitano, Makoto Watanabe

2022Metals19 citationsDOIOpen Access PDF

Abstract

Wire arc additive manufacturing achieves high efficiency and low costs by using a melting wire for directional depositions. Thermal analyses and the finite element method have been applied to predict residual stress and the deformation of fabricated parts. For Ni-based alloy production, a method for predicting solidification microstructure evolution with segregation is needed in order to design precise heat treatment procedures. In this study, a multi-phase field method coupled with a CALPHAD database is developed to simulate the solidification microstructure evolution of a practical Ni-based alloy. Thermal analyses of a wire arc additive manufacturing model were performed by the process modeling of multi-pass depositions with a running cyclic arc. Solidification microstructure evolution was obtained using the temperature profile in each deposited layer by the multi-phase field method. These predicted microstructures are compared with experimental measurements. It is confirmed that the multi-phase field method coupled with the CALPHAD database is effective for predicting solidification microstructure and segregation in the engineering of Ni-based alloys.

Topics & Concepts

MicrostructureMaterials scienceCALPHADAlloyResidual stressMetallurgyPhase (matter)ThermalPhase diagramThermodynamicsPhysicsOrganic chemistryChemistryAdditive Manufacturing Materials and ProcessesHigh Entropy Alloys StudiesSolidification and crystal growth phenomena