Your search keyword '"spatter monitoring"' showing total 3 results

1. Heterogeneous sensor data fusion for multiscale, shape agnostic flaw detection in laser powder bed fusion additive manufacturing

Author

Benjamin Bevans, Christopher Barrett, Thomas Spears, Aniruddha Gaikwad, Alex Riensche, Ziyad Smoqi, Harold (Scott) Halliday, and Prahalada Rao

Subjects

additive manufacturing, sensor data fusion, thermal imaging, spatter monitoring, shape agnostic monitoring, porosity, Science, Manufactures, TS1-2301

Abstract

We developed and applied a novel approach for shape agnostic detection of multiscale flaws in laser powder bed fusion (LPBF) additive manufacturing using heterogenous in-situ sensor data. Flaws in LPBF range from porosity at the micro-scale (< 100 µm), layer related inconsistencies at the meso-scale (100 µm to 1 mm) and geometry-related flaws at the macroscale (> 1 mm). Existing data-driven models are primarily focused on detecting a specific type of LPBF flaw using signals from one type of sensor. Such approaches, which are trained on data from simple cuboid and cylindrical-shaped coupons, have met limited success when used for detecting multiscale flaws in complex LPBF parts. The objective of this work is to develop a heterogenous sensor data fusion approach capable of detecting multiscale flaws across different LPBF part geometries and build conditions. Accordingly, data from an infrared camera, spatter imaging camera, and optical powder bed imaging camera were acquired across separate builds with differing part geometries and orientations (Inconel 718). Spectral graph-based process signatures were extracted from this heterogeneous thermo-optical sensor data and used as inputs to simple machine learning models. The approach detected porosity, layer-level distortion, and geometry-related flaws with statistical fidelity exceeding 93% (F-score).

Published

2023

2. Heterogeneous sensor data fusion for multiscale, shape agnostic flaw detection in laser powder bed fusion additive manufacturing.

Author

Bevans, Benjamin, Barrett, Christopher, Spears, Thomas, Gaikwad, Aniruddha, Riensche, Alex, Smoqi, Ziyad, Halliday, Harold (Scott), and Rao, Prahalada

Subjects

*MULTISENSOR data fusion, *MACHINE learning, *ELECTRIC furnaces, *INFRARED cameras, *DETECTORS, *POWDERS, *SIMPLE machines

Abstract

We developed and applied a novel approach for shape agnostic detection of multiscale flaws in laser powder bed fusion (LPBF) additive manufacturing using heterogenous in-situ sensor data. Flaws in LPBF range from porosity at the micro-scale (< 100 µm), layer related inconsistencies at the meso-scale (100 µm to 1 mm) and geometry-related flaws at the macroscale (> 1 mm). Existing data-driven models are primarily focused on detecting a specific type of LPBF flaw using signals from one type of sensor. Such approaches, which are trained on data from simple cuboid and cylindrical-shaped coupons, have met limited success when used for detecting multiscale flaws in complex LPBF parts. The objective of this work is to develop a heterogenous sensor data fusion approach capable of detecting multiscale flaws across different LPBF part geometries and build conditions. Accordingly, data from an infrared camera, spatter imaging camera, and optical powder bed imaging camera were acquired across separate builds with differing part geometries and orientations (Inconel 718). Spectral graph-based process signatures were extracted from this heterogeneous thermo-optical sensor data and used as inputs to simple machine learning models. The approach detected porosity, layer-level distortion, and geometry-related flaws with statistical fidelity exceeding 93% (F-score). [ABSTRACT FROM AUTHOR]

Published

2023

3. Virtual and Physical Prototyping

Author

Bevans, Benjamin, Barrett, Christopher, Spears, Thomas, Gaikwad, Aniruddha, Riensche, Alex, Smoqi, Ziyad, Halliday, Harold (Scott), and Rao, Prahalada

Subjects

porosity, Additive manufacturing, sensor data fusion, Modeling and Simulation, Signal Processing, thermal imaging, spatter monitoring, Computer Graphics and Computer-Aided Design, shape agnostic monitoring, Industrial and Manufacturing Engineering

Abstract

We developed and applied a novel approach for shape agnostic detection of multiscale flaws in laser powder bed fusion (LPBF) additive manufacturing using heterogenous in-situ sensor data. Flaws in LPBF range from porosity at the micro-scale (< 100 mu m), layer related inconsistencies at the meso-scale (100 mu m to 1 mm) and geometry-related flaws at the macroscale (> 1 mm). Existing data-driven models are primarily focused on detecting a specific type of LPBF flaw using signals from one type of sensor. Such approaches, which are trained on data from simple cuboid and cylindrical-shaped coupons, have met limited success when used for detecting multiscale flaws in complex LPBF parts. The objective of this work is to develop a heterogenous sensor data fusion approach capable of detecting multiscale flaws across different LPBF part geometries and build conditions. Accordingly, data from an infrared camera, spatter imaging camera, and optical powder bed imaging camera were acquired across separate builds with differing part geometries and orientations (Inconel 718). Spectral graph-based process signatures were extracted from this heterogeneous thermo-optical sensor data and used as inputs to simple machine learning models. The approach detected porosity, layer-level distortion, and geometry-related flaws with statistical fidelity exceeding 93% (F-score). Department of Energy (DOE), Office of Science [DE-SC0021136]; National Science Foundation (NSF) [CMMI 1752069, CMMI 2309483, CMMI-1719388, CMMI-1920245, CMMI-1739696, PFI-TT 2044710, ECCS 2020246]; NSF [1840138] Published version Prahalada Rao acknowledges funding from the Department of Energy (DOE), Office of Science, under Grant number DE-SC0021136, and the National Science Foundation (NSF) [Grant numbers CMMI 1752069/CMMI 2309483,CMMI-1719388, CMMI-1920245, CMMI-1739696, PFI-TT 2044710, ECCS 2020246] for funding his research programme. H. Scot Halliday acknowledges funding from the NSF for Award #1840138 funding the NTU Center for Advanced Manufacturing.

Published

2023