| People | Locations | Statistics |
|---|---|---|
| Naji, M. |
| |
| Motta, Antonella |
| |
| Aletan, Dirar |
| |
| Mohamed, Tarek |
| |
| Ertürk, Emre |
| |
| Taccardi, Nicola |
| |
| Kononenko, Denys |
| |
| Petrov, R. H. | Madrid |
|
| Alshaaer, Mazen | Brussels |
|
| Bih, L. |
| |
| Casati, R. |
| |
| Muller, Hermance |
| |
| Kočí, Jan | Prague |
|
| Šuljagić, Marija |
| |
| Kalteremidou, Kalliopi-Artemi | Brussels |
|
| Azam, Siraj |
| |
| Ospanova, Alyiya |
| |
| Blanpain, Bart |
| |
| Ali, M. A. |
| |
| Popa, V. |
| |
| Rančić, M. |
| |
| Ollier, Nadège |
| |
| Azevedo, Nuno Monteiro |
| |
| Landes, Michael |
| |
| Rignanese, Gian-Marco |
|
Luckabauer, Martin
University of Twente
in Cooperation with on an Cooperation-Score of 37%
Topics
Publications (19/19 displayed)
- 2025Simulating induction heating of fabric based thermoplastic composites using measured electrical conductivitiescitations
- 2024Post aging heat treatment effect on AA6060 produced by Friction Screw Extrusion Additive Manufacturing
- 2024The effect of the laser beam intensity profile in laser-based directed energy depositioncitations
- 2023Solid-State Additive Manufacturing of AA6060 Employing Friction Screw Extrusion Additive Manufacturingcitations
- 2023Melting-Free Metal Production: Solid-State Additive Manufacturing of an Al-Mg-Si Alloy Using FSEAM
- 2023The Influence of the Deposition Speed during Friction Screw Extrusion Additive Manufacturing of AA6060
- 2023Friction screw extrusion additive manufacturing of an Al-Mg-Si alloycitations
- 2023Determination of the anisotropic electrical conductivity of carbon fabric reinforced composites by the six-probe methodcitations
- 2023A Feasibility Study on Friction Screw Extrusion Additive Manufacturing of AA6060citations
- 2023Laser intensity profile as a means to steer microstructure of deposited tracks in Directed Energy Depositioncitations
- 2023Thermo-fluid modeling of influence of attenuated laser beam intensity profile on melt pool behavior in laser-assisted powder-based direct energy deposition
- 2022Thermo-fluidic behavior to solidification microstructure texture evolution during laser-assisted powder-based direct energy deposition
- 2022A feasibility study on friction screw extrusion additive manufacturing of AA6060
- 2020Evolution of microstructure and variations in mechanical properties accompanied with diffusionless isothermal ω transformation in β -titanium alloyscitations
- 2019Decreasing activation energy of fast relaxation processes in a metallic glass during agingcitations
- 2017In situ real-time monitoring of aging processes in an aluminum alloy by high-precision dilatometrycitations
- 2015Thermophysical properties of manganin (Cu86Mn12Ni2) in the solid and liquid statecitations
- 2014Specific volume study of a bulk metallic glass far below its calorimetrically determined glass transition temperaturecitations
- 2013Self- and solute diffusion, interdiffusion and thermal vacancies in the system iron-aluminiumcitations
Places of action
| Organizations | Location | People |
|---|
document
Thermo-fluidic behavior to solidification microstructure texture evolution during laser-assisted powder-based direct energy deposition
Abstract
In laser-based metal processing techniques, the intensity profile of the laser beam plays an essential role in the cyclic temperature evolution of the process. On the other hand, the microstructure and the resulting mechanical properties of the part follow the temperature profile during solidification. One way to control the microstructure and mechanical properties of a part, is the manipulation of the laser beam intensity profile using the so-called laser beam shaping method. Since finding a suitable laser beam intensity profile based on the required microstructure and mechanical properties is an expensive iterative trial and error process, the use of high-fidelity models is preferable to experiments.<br/><br/>In this research, a thermo-fluid model is developed for the Laser-assisted powder-based Direct Energy Deposition (L-DED) process based on the Computational Fluid Dynamics (CFD) method, where the powder particle flow is simulated using the Discrete Element Method (DEM) and the governing equations are solved using the Finite Volume Method (FVM). Also the<br/>Volume of Fluid (VOF) method is used to track the metal and gas interface. With high accuracy, this model includes arbitrary laser beam intensity profiles, powder particle stream and particle size distribution, powder particle and laser beam interaction, addition of powder particles to the molten pool, temperature- and incident angle- dependent laser beam<br/>absorption, Marangoni effects due to surface tension, buoyancy flow, evaporation, solidification, shrinkage, and heat transfer in the substance and to the surroundings. On the other hand, a solidification microstructure texture model is developed and one-way coupled to the thermo-fluid model. The microstructure model is based on the Cellular Automata (CA) method and includes the grain nucleation and columnar-equiaxed grain growth competition to simulate the crystallographic texture changes of 316L austenitic stainless steel. In this model, the crystallographic orientation of the nuclei is selected randomly, but the grain growth with the preferred crystallographic orientation is followed based on a dendrite growth kinetics model. With the aid of experiments, both the thermo-fluid and the solidification microstructure models are validated. The thermo-fluid model has a high agreement with the experiments in terms of the geometry of the molten pool and clad. The microstructure model also predicts the size and crystallographic orientation of the grains after solidification in excellent agreement with the EBSD results.<br/>