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Meeting MS&T21: Materials Science & Technology
Symposium Additive Manufacturing of Metals: ICME Gaps: Material Property and Validation Data to Support Certification
Presentation Title Capturing and Analyzing In-situ Data within the Directed Energy Deposition Process with DEDSmart
Author(s) Michael Juhasz, Melanie Lang
On-Site Speaker (Planned) Michael Juhasz
Abstract Scope Within the various AM processes, there are several process parameters that determine the resultant geometry and part quality of a build. In certain systems, the data from the builds remain locked away in a closed box. But can this data be useful for the end-users? At FormAlloy, we know so. Along with developing and integrating their fleet of in-process sensors and closed loop control features, FormAlloy internally developed their data logging capability known as DEDSmartTM for their directed energy deposition systems. All DEDSmartTM data is automatically generated post build and contains all the parameters and process signatures on a time scale. The data sets provided can be linked to post-process evaluations to enable machine learning possibilities and defect detection algorithms. Join FormAlloy as they discuss how their DEDSmartTM data was used to link defects that were observed post-build to anomalies that were found within the process parameters and their signatures.

OTHER PAPERS PLANNED FOR THIS SYMPOSIUM

An Analysis of the Dislocation Density of Inconel 718 Additive Manufacturing Powder
An ICME Approach for Designing Appropriate Heat Treatments in Additively Manufactured Nitrogen Atomized 17-4PH Stainless Steel
Capturing and Analyzing In-situ Data within the Directed Energy Deposition Process with DEDSmart
CFD Modelling for AM Processes
Critical Issues and Gaps in Testing and Characterization Data for Computational Materials in Qualification and Certification of Additively Manufactured Metallic Materials
Determining Data Requirements to Quantify Porosity in the Laser Powder Bed Fusion Process
Enabling Quality Assurance by Completing the Process-Property-Performance Paradigm for Additive Manufacturing
Experimental and Numerical Investigation of Pressureless Sintering for Binder Jetted Metal Parts
High Temperature Material Properties Measurement Capabilities of the NASA MSFC Electrostatic Levitation (ESL) Laboratory
High Temperature Material Property Data and Challenges to Thermal Process Model Predictions and In-Situ/Ex-Situ Measurements for Metallic Additive Manufacturing
ICME Gap Analysis for Materials Design and Process Optimization in Additive Manufacturing
ICME Gaps for Additive Manufacturing of Metals
Laser Energy Coupling during Metal Additive Manufacturing
Lessons Learned from Calibration and Validation of Process Models for Laser Powder Bed Fusion
Methods for Improved Part-scale Thermal Process Simulations in Laser Powder Bed Fusion
On Scan Path Knowledge for Model Informed Process Planning and Material Quality Predictions
Phase Field Informed Monte Carlo Texture Evolution Models for Additive Manufacturing Microstructure Simulation and the Need for Experimental Grain Competition Data
Predicting Melt Properties Using Atomistic Simulations with a Highly Accurate Physically Informed Neural Network Interatomic Potential
Providing a Rigorous Measurement Foundation for Modeling-Informed Qualification and Certification of Metal AM Components
Transferability of Terrestrial Development of Metal Additive to Extraterrestrial Applications

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