Numerical Analysis of Laser Pattern Effects to Residual Stress on Metal 3D Printing

In this study, a metal 3D printing process was simulated using finite elements methods (FEM), and the specimens were printed under the same conditions. Subsequently, residual stress was measured to validate the results. The thermal-structure two-way coupled analysis confirmed the phenomenon that occ...

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Bibliographic Details
Published inApplied sciences Vol. 12; no. 9; p. 4611
Main Authors Jung, Chang-ho, Lee, Moon Gu, Nam, Chanhyuk, Jeon, Yongho
Format Journal Article
LanguageEnglish
Published Basel MDPI AG 04.05.2022
Subjects
3-D printers
Computed tomography
Deformation
finite element method
Hatching
Heat transfer
Lasers
metal 3D printing
Numerical analysis
Pattern analysis
Physical properties
Printing
Process parameters
Residual stress
Simulation
Solidification
Solids
structure-thermal coupled analysis
Yield stress
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Summary:In this study, a metal 3D printing process was simulated using finite elements methods (FEM), and the specimens were printed under the same conditions. Subsequently, residual stress was measured to validate the results. The thermal-structure two-way coupled analysis confirmed the phenomenon that occurred during the additive process, thereby allowing the residual stress to be calculated more realistically. In addition, to simulate the printing process, a subroutine was configured to account for the laser heat input path and layer. The process of stacking and hatching in a snake pattern for an area measuring 5 mm × 5 mm was simulated. Four cases with different rotation angles of the layer pattern were calculated using FEM. The specimens were printed compared with the analysis results. To verify the printed condition of the specimen, computed tomography was performed to confirm the appearance of pores and cracks in the specimen. Cracks appeared in the 180° specimen, and the cause was analyzed based on the analysis results. Subsequently, the residual stress was measured by an X-ray diffractometer and compared; it was confirmed that the average error of the specimen without cracks is 8.86%, which is similar to the analysis results. These results confirm that the FEM model conducted in this study can be used to analyze residual stress and cracks in a material, which are difficult to analyze in previous studies. The FEM model constructed in this study is expected to facilitate investigations into 3D printing phenomena as well as enable a more efficient process design.
ISSN:2076-3417
2076-3417
DOI:10.3390/app12094611