Modeling of Microstructure Formation in Additively Manufactured IN718 with Emphasis on Porosity Prediction

We developed a model for microstructure development during solidification in laser powder bed fusion of metals. The model was developed within the open source kinetic Monte Carlo code sparks that is supported by Sandia National Laboratories. The key new development is the capability to simulate growth of solidifying grains into the fusion zone with crystallographic texture. This enables texture development to be included in the simulation of microstructural evolution. The model was verified via tests with simple semi-circular melt pools and was further validated through comparisons with texture and microstructure in 3D printed Ni-based alloy 718. CMU collaborated with Langley to transfer the new capability to NASA researchers, who also helped with experimental characterization. An important scientific conclusion was that melt pool shape must be described precisely for accurate modeling of texture development. This experimental collaboration extended also to investigations of porosity, melt pool shape, surface grooving, micro-cracking, high-speed imaging of laser melting with synchrotron x-rays, machine learning and precipitation. The original aim of validating the model for lack-of-fusion porosity developed at CMU for aluminum printing was successfully demonstrated for alloy 718. The modeling of surface grooving was derived from this work and good agreement with experimental data was found. The analysis of micro-cracking suggested a sensitivity to minor interstitial elements such as boron, which should be further investigated. Although useful results were obtained for the modeling of precipitation and the prediction of hardness, we concluded that accurate modeling in this area remains an active topic for investigation.