TY - JOUR
T1 - Processing windows for Al-357 by LPBF process
T2 - a novel framework integrating FEM simulation and machine learning with empirical testing
AU - Mahmood, Muhammad Arif
AU - Khraisheh, Marwan
AU - Popescu, Andrei C.
AU - Liou, Frank
N1 - Publisher Copyright:
© 2024, Emerald Publishing Limited.
PY - 2024/10/24
Y1 - 2024/10/24
N2 - Purpose: This study aims to develop a holistic method that integrates finite element modeling, machine learning, and experimental validation to propose processing windows for optimizing the laser powder bed fusion (LPBF) process specific to the Al-357 alloy. Design/methodology/approach: Validation of a 3D heat transfer simulation model was conducted to forecast melt pool dimensions, involving variations in laser power, laser scanning speed, powder bed thickness (PBT) and powder bed pre-heating (PHB). Using the validated model, a data set was compiled to establish a back-propagation-based machine learning capable of predicting melt pool dimensional ratios indicative of printing defects. Findings: The study revealed that, apart from process parameters, PBT and PHB significantly influenced defect formation. Elevated PHBs were identified as contributors to increased lack of fusion and keyhole defects. Optimal combinations were pinpointed, such as 30.0 µm PBT with 90.0 and 120.0 °C PHBs and 50.0 µm PBT with 120.0 °C PHB. Originality/value: The integrated process mapping approach showcased the potential to expedite the qualification of LPBF parameters for Al-357 alloy by minimizing the need for iterative physical testing.
AB - Purpose: This study aims to develop a holistic method that integrates finite element modeling, machine learning, and experimental validation to propose processing windows for optimizing the laser powder bed fusion (LPBF) process specific to the Al-357 alloy. Design/methodology/approach: Validation of a 3D heat transfer simulation model was conducted to forecast melt pool dimensions, involving variations in laser power, laser scanning speed, powder bed thickness (PBT) and powder bed pre-heating (PHB). Using the validated model, a data set was compiled to establish a back-propagation-based machine learning capable of predicting melt pool dimensional ratios indicative of printing defects. Findings: The study revealed that, apart from process parameters, PBT and PHB significantly influenced defect formation. Elevated PHBs were identified as contributors to increased lack of fusion and keyhole defects. Optimal combinations were pinpointed, such as 30.0 µm PBT with 90.0 and 120.0 °C PHBs and 50.0 µm PBT with 120.0 °C PHB. Originality/value: The integrated process mapping approach showcased the potential to expedite the qualification of LPBF parameters for Al-357 alloy by minimizing the need for iterative physical testing.
KW - Additive manufacturing
KW - Al-357
KW - FEM framework
KW - Laser powder bed fusion process
KW - Machine learning
KW - Process optimization
KW - Processing windows
UR - http://www.scopus.com/inward/record.url?scp=85200655315&partnerID=8YFLogxK
U2 - 10.1108/RPJ-01-2024-0057
DO - 10.1108/RPJ-01-2024-0057
M3 - Article
AN - SCOPUS:85200655315
SN - 1355-2546
VL - 30
SP - 1846
EP - 1858
JO - Rapid Prototyping Journal
JF - Rapid Prototyping Journal
IS - 9
ER -