Thermal analysis of laser additive manufacturing of aluminium alloys: Experiment and simulation
Research output: Contributions to collected editions/works › Article in conference proceedings › Research › peer-review
Standard
Thermal analysis of laser additive manufacturing of aluminium alloys: Experiment and simulation. / Bock, Frederic E.; Frönd, Martin; Herrnring, Jan et al.
Proceedings of the 21st International ESAFORM Conference on Material Forming, ESAFORM 2018: ESAFORM 2018. ed. / Gianluca Buffa; Livan Fratini; Giuseppe Ingarao; Rosa Di Lorenzo. American Institute of Physics Inc., 2018. 140004 (AIP Conference Proceedings; Vol. 1960, No. 1).Research output: Contributions to collected editions/works › Article in conference proceedings › Research › peer-review
Harvard
APA
Vancouver
Bibtex
}
RIS
TY - CHAP
T1 - Thermal analysis of laser additive manufacturing of aluminium alloys: Experiment and simulation
AU - Bock, Frederic E.
AU - Frönd, Martin
AU - Herrnring, Jan
AU - Enz, Josephin
AU - Kashaev, Nikolai
AU - Klusemann, Benjamin
N1 - Conference code: 21
PY - 2018/5/2
Y1 - 2018/5/2
N2 - Laser additive manufacturing (LAM) has become increasingly popular in industry in recent decades because it enables exceptional degrees of freedom regarding the structural design of lightweight components compared to subtractive manufacturing techniques. Laser metal deposition (LMD) of wire-fed material shows in particular the advantages such as high process velocity and efficient use of material compared to other LAM processes. During wire-based LMD, the material is deposited onto a substrate and supplemented by successive layers allowing a layer-wise production of complex three-dimensional structures. Despite the increased productivity of LMD, regarding the ability to process aluminium alloys, there is still a lack in quality and reproducibility due to the inhomogeneous temperature distribution during the process, leading to undesired residual stresses, distortions and inconsistent layer geometries and poor microstructures. In this study, the aluminium alloy AA5087 as wire and AA5754 as substrate material were utilized for LMD. In order to obtain information about the temperature field during LMD, thermocouple and thermography measurements were performed during the process. The temperature measurements were used to validate a finite element model regarding the heat distribution, which will be further used to investigate the temperature field evolution over time. To consider the continuous addition of material within the FE-model, an inactive/active element approach was chosen, where initially deactivated elements are activated corresponding to the deposition of material. The first results of the simulation and the experiments show good agreement. Therefore, the model can be used in the future for LMD process optimization, e.g., in terms of minimizing local variations of the thermal load for each layer
AB - Laser additive manufacturing (LAM) has become increasingly popular in industry in recent decades because it enables exceptional degrees of freedom regarding the structural design of lightweight components compared to subtractive manufacturing techniques. Laser metal deposition (LMD) of wire-fed material shows in particular the advantages such as high process velocity and efficient use of material compared to other LAM processes. During wire-based LMD, the material is deposited onto a substrate and supplemented by successive layers allowing a layer-wise production of complex three-dimensional structures. Despite the increased productivity of LMD, regarding the ability to process aluminium alloys, there is still a lack in quality and reproducibility due to the inhomogeneous temperature distribution during the process, leading to undesired residual stresses, distortions and inconsistent layer geometries and poor microstructures. In this study, the aluminium alloy AA5087 as wire and AA5754 as substrate material were utilized for LMD. In order to obtain information about the temperature field during LMD, thermocouple and thermography measurements were performed during the process. The temperature measurements were used to validate a finite element model regarding the heat distribution, which will be further used to investigate the temperature field evolution over time. To consider the continuous addition of material within the FE-model, an inactive/active element approach was chosen, where initially deactivated elements are activated corresponding to the deposition of material. The first results of the simulation and the experiments show good agreement. Therefore, the model can be used in the future for LMD process optimization, e.g., in terms of minimizing local variations of the thermal load for each layer
KW - Engineering
KW - Additive manufacturing technology
KW - Simulation
KW - Experiment
UR - http://www.scopus.com/inward/record.url?scp=85047313588&partnerID=8YFLogxK
U2 - 10.1063/1.5034996
DO - 10.1063/1.5034996
M3 - Article in conference proceedings
T3 - AIP Conference Proceedings
BT - Proceedings of the 21st International ESAFORM Conference on Material Forming, ESAFORM 2018
A2 - Buffa, Gianluca
A2 - Fratini, Livan
A2 - Ingarao, Giuseppe
A2 - Di Lorenzo, Rosa
PB - American Institute of Physics Inc.
T2 - 21st International Conference on Material Forming - ESAFORM 2018
Y2 - 23 April 2018 through 25 April 2018
ER -