Details
| Original language | English |
|---|---|
| Article number | 112576 |
| Number of pages | 17 |
| Journal | Computational materials science |
| Volume | 231 |
| Early online date | 4 Nov 2023 |
| Publication status | Published - 5 Jan 2024 |
Abstract
Additive manufacturing (AM) of metallic components has recently become a viable option for series production. In this, the powder of various metallic materials such as steel and aluminum can be processed layer-by-layer to produce dense parts with excellent properties. One of the major challenges in this process is the occurrence of residual stresses, which negatively affect the strength and functionality of the produced components. Understanding the mechanism of distribution of these stresses and the detrimental deformations is one of the main themes covered in this work. In the numerical treatment with the finite element method, a phase-field model (PFM) for phase-change materials is utilized together with a thermo-elastoplastic model to simulate the multi-layer AM process and to evaluate the occurring residual stresses. Using the PFM allows tracking the diffusive melting front and, thus, distinguishing between the melted (soft) and the unmelted (hard) states of the material. One of the novel contributions is the definition of a phase-field history variable, which can capture the irreversible process of metallic powder melting. Additionally, phase-field-dependent material properties are proposed. The coupled governing equations are solved in the open-source FE package FEniCS Project, where three-dimensional initial-boundary-value problems are introduced and the results are compared with reference data from the literature.
Keywords
- Additive manufacturing, FEniCS Project, Phase-field modeling, Residual stresses, Selective laser melting, Thermo-elastoplastic model
ASJC Scopus subject areas
Cite this
- Standard
- Harvard
- Apa
- Vancouver
- BibTeX
- RIS
In: Computational materials science, Vol. 231, 112576, 05.01.2024.
Research output: Contribution to journal › Article › Research › peer review
}
TY - JOUR
T1 - Predicting residual stresses in SLM additive manufacturing using a phase-field thermomechanical modeling framework
AU - Ali, Baharin
AU - Heider, Yousef
AU - Markert, Bernd
N1 - Funding Information: The first author would gratefully acknowledge the German Academic Exchange Service (DAAD) for the support via the doctoral research grant number 57214224 . The support from the Iraqi Ministry of Oil is also gratefully acknowledged.
PY - 2024/1/5
Y1 - 2024/1/5
N2 - Additive manufacturing (AM) of metallic components has recently become a viable option for series production. In this, the powder of various metallic materials such as steel and aluminum can be processed layer-by-layer to produce dense parts with excellent properties. One of the major challenges in this process is the occurrence of residual stresses, which negatively affect the strength and functionality of the produced components. Understanding the mechanism of distribution of these stresses and the detrimental deformations is one of the main themes covered in this work. In the numerical treatment with the finite element method, a phase-field model (PFM) for phase-change materials is utilized together with a thermo-elastoplastic model to simulate the multi-layer AM process and to evaluate the occurring residual stresses. Using the PFM allows tracking the diffusive melting front and, thus, distinguishing between the melted (soft) and the unmelted (hard) states of the material. One of the novel contributions is the definition of a phase-field history variable, which can capture the irreversible process of metallic powder melting. Additionally, phase-field-dependent material properties are proposed. The coupled governing equations are solved in the open-source FE package FEniCS Project, where three-dimensional initial-boundary-value problems are introduced and the results are compared with reference data from the literature.
AB - Additive manufacturing (AM) of metallic components has recently become a viable option for series production. In this, the powder of various metallic materials such as steel and aluminum can be processed layer-by-layer to produce dense parts with excellent properties. One of the major challenges in this process is the occurrence of residual stresses, which negatively affect the strength and functionality of the produced components. Understanding the mechanism of distribution of these stresses and the detrimental deformations is one of the main themes covered in this work. In the numerical treatment with the finite element method, a phase-field model (PFM) for phase-change materials is utilized together with a thermo-elastoplastic model to simulate the multi-layer AM process and to evaluate the occurring residual stresses. Using the PFM allows tracking the diffusive melting front and, thus, distinguishing between the melted (soft) and the unmelted (hard) states of the material. One of the novel contributions is the definition of a phase-field history variable, which can capture the irreversible process of metallic powder melting. Additionally, phase-field-dependent material properties are proposed. The coupled governing equations are solved in the open-source FE package FEniCS Project, where three-dimensional initial-boundary-value problems are introduced and the results are compared with reference data from the literature.
KW - Additive manufacturing
KW - FEniCS Project
KW - Phase-field modeling
KW - Residual stresses
KW - Selective laser melting
KW - Thermo-elastoplastic model
UR - http://www.scopus.com/inward/record.url?scp=85175542392&partnerID=8YFLogxK
U2 - 10.1016/j.commatsci.2023.112576
DO - 10.1016/j.commatsci.2023.112576
M3 - Article
AN - SCOPUS:85175542392
VL - 231
JO - Computational materials science
JF - Computational materials science
SN - 0927-0256
M1 - 112576
ER -