Local prediction of Laser Powder Bed Fusion porosity by short-wave infrared imaging thermal feature porosity probability maps

Local thermal history can significantly vary in parts during metal Additive Manufacturing (AM), leading to local defects. However, the sequential layer-by-layer nature of AM facilitates in-situ part voxelmetric observations that can be used to detect and correct these defects for part qualification...

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Bibliographic Details
Published in:Journal of materials processing technology 2022-04, Vol.302, p.117473, Article 117473
Main Authors: Lough, Cody S., Liu, Tao, Wang, Xin, Brown, Ben, Landers, Robert G., Bristow, Douglas A., Drallmeier, James A., Kinzel, Edward C.
Format: Article
Language:English
Subjects:
Computed tomography
Defects
Infrared cameras
Infrared imaging
Laser Powder Bed Fusion
Porosity
Porosity detection
Powder beds
Quality control
Receiver operating characteristic
Short wave radiation
SWIR
Thermal imaging
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Summary:Local thermal history can significantly vary in parts during metal Additive Manufacturing (AM), leading to local defects. However, the sequential layer-by-layer nature of AM facilitates in-situ part voxelmetric observations that can be used to detect and correct these defects for part qualification and quality control. The challenge is to relate this local radiometric data with local defect information to estimate process error likelihood in future builds. This paper uses a Short-Wave Infrared (SWIR) camera to record the temperature history for parts manufactured with Laser Powder Bed Fusion (LPBF) processes. The porosity from a cylindrical specimen is measured by ex-situ micro-computed tomography (μCT). Specimen data from the SWIR camera, combined with the μCT data, are used to generate thermal feature-based porosity probability maps. The porosity predictions made by various SWIR thermal feature-porosity probability maps of a specimen with a complex geometry are scored against the true porosity obtained via μCT. The receiver operating characteristic curves constructed from the predictions for the complex sample demonstrate the porosity probability mapping methodology’s potential for in-situ based porosity detection.
ISSN:0924-0136
1873-4774
DOI:10.1016/j.jmatprotec.2021.117473