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| Naji, M. |
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| Motta, Antonella |
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| Aletan, Dirar |
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| Mohamed, Tarek |
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| Ertürk, Emre |
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| Taccardi, Nicola |
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| Kononenko, Denys |
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| Petrov, R. H. | Madrid |
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| Alshaaer, Mazen | Brussels |
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| Bih, L. |
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| Casati, R. |
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| Muller, Hermance |
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| Kočí, Jan | Prague |
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| Šuljagić, Marija |
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| Kalteremidou, Kalliopi-Artemi | Brussels |
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| Azam, Siraj |
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| Ospanova, Alyiya |
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| Blanpain, Bart |
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| Ali, M. A. |
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| Popa, V. |
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| Rančić, M. |
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| Ollier, Nadège |
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| Azevedo, Nuno Monteiro |
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| Landes, Michael |
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| Rignanese, Gian-Marco |
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Mohanty, Sankhya
Technical University of Denmark
in Cooperation with on an Cooperation-Score of 37%
Topics
Publications (31/31 displayed)
- 2024Quantifying Intra-Tow Fiber Volume Fraction in GFRP::A Comparison of 3D Non-Destructive X-ray Computed Tomography and Destructive Optical Microscopy
- 2023Holistic computational design within additive manufacturing through topology optimization combined with multiphysics multi-scale materials and process modellingcitations
- 2022Increasing the productivity of selective laser sintering workflow by integrating cooling channels in the printing powder matrixcitations
- 2021Towards a digital twin of laser powder bed fusion with a focus on gas flow variablescitations
- 2020Resolving the effects of local convective heat transfer via adjustment of thermo-physical properties in pure heat conduction simulation of Laser Powder Bed Fusion (L-PBF)citations
- 2020Numerical investigation into the effect of different parameters on the geometrical precision in the laser-based powder bed fusion process Chaincitations
- 2020Numerical investigation into the effect of different parameters on the geometrical precision in the laser-based powder bed fusion process Chaincitations
- 2020Multi-metal additive manufacturing process chain for optical quality mold generationcitations
- 2020Laser polishing of additively manufactured Ti-6Al-4V: Microstructure evolution and material propertiescitations
- 2020Realistic design of laser powder bed fusion channelscitations
- 2020Microstructural modelling of above β-transus heat treatment of additively manufactured Ti-6Al-4V using cellular automatacitations
- 2020X-ray CT and image analysis methodology for local roughness characterization in cooling channels made by metal additive manufacturingcitations
- 2019Roughness Investigation of SLM Manufactured Conformal Cooling Channels Using X-ray Computed Tomography
- 2019Roughness Investigation of SLM Manufactured Conformal Cooling Channels Using X-ray Computed Tomography
- 2019Multi-material additive manufacturing of steels using laser powder bed fusion
- 2019A systematic investigation of the effects of process parameters on heat and fluid flow and metallurgical conditions during laser-based powder bed fusion of Ti6Al4V alloycitations
- 2019Build orientation effects on the roughness of SLM channels
- 2018Multiphysics modelling of manufacturing processes: A reviewcitations
- 2018Multiphysics modelling of manufacturing processes: A reviewcitations
- 2018Thermo-fluid-metallurgical modelling of laser-based powder bed fusion process
- 2018Modelling of the microstructural evolution of Ti6Al4V parts produced by selective laser melting during heat treatment
- 2018Thermo-fluid-metallurgical modelling of the selective laser melting process chaincitations
- 2018Numerical modelling and parametric study of grain morphology and resultant mechanical properties from selective laser melting process of Ti6Al4V
- 2018Defects investigation in additively manufactured steel products for injection moulding
- 2017Multi-objective optimization of cellular scanning strategy in selective laser meltingcitations
- 2017Laser additive manufacturing of multimaterial tool inserts: a simulation-based optimization studycitations
- 2016Improving accuracy of overhanging structures for selective laser melting through reliability characterization of single track formation on thick powder bedscitations
- 2016Reducing residual stresses and deformations in selective laser melting through multi-level multi-scale optimization of cellular scanning strategycitations
- 2015Cellular scanning strategy for selective laser melting: Generating reliable, optimized scanning paths and processing parameterscitations
- 2014Numerical Model based Reliability Estimation of Selective Laser Melting Processcitations
- 2013A finite volume alternate direction implicit approach to modeling selective laser melting
Places of action
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document
Thermo-fluid-metallurgical modelling of laser-based powder bed fusion process
Abstract
Selective laser melting (SLM) is a type of additive manufacturing (AM) technique where the parts are produced in a layer-wised manner. In this process, first a layer of fine metallic spherical particles, with sizes spanning from 20-50 µm, is distributed over a rigid building platform whose elevation can be readily adjusted while the part is being manufactured [1]. When the first powder layer is distributed, a laser with a typical spot size of about 30-100 µm starts scanning it. The input heat imposed from the laser is sufficiently high to melt down and subsequently fuse these discrete particles together. After the first layer has been scanned, the building table (containing the part) moves one increment down and then another powder layer will be distributed with the same coating mechanism. This process is repeated until the final part is manufactured [2]. <br/>SLM has many advantages over other conventional production methods such has casting, milling, forging, etc. These are the possibility of complex designs, low material waste and short total manufacturing process time [3]. Although SLM is regarded as a superior technique to some of the existing conventional manufacturing processes, it still needs to be modified to an extent that it becomes more predictable. To address this issue and predict the quality of the parts produced by SLM, one can make use of numerical modelling.<br/>Numerical models, especially if validated with experimental measurements, can be used as an easy and cheap way to predict the feature and quality of the SLM parts. In this respect, different numerical models containing different physics have been developed for the SLM process, ranging from pure thermal models [4], [5] to thermo-mechanical models [6] and the more advanced meso-scale thermo-fluid models [7], [8]. Consideration of just the conductive heat transfer is a proven and well-tested way of SLM modelling. In this type of models, a moving heat source or heat flux, resembles the laser-material interaction. On the other hand, thermal models including the fluid flow, despite incurring much more computational time, will give detailed information about the actual melt pool thermal history, its morphology and even its eventual microstructure [7], [9].<br/>In this work, a thermo-fluid-metallurgical model of the SLM process for a titanium alloy has been developed to analyze the thermal and fluid behavior of the molten metal inside the melt pool. The model takes into account the Marangoni effect caused by the change in shear stresses. To thermally and fluid-mechanically model the solidification phenomenon, the enthalpy-porosity method and solidification drag forces in the porous medium are implemented respectively. Furthermore, an additional microstructural model has been developed and subsequently coupled to the mentioned model to investigate the solidification behavior of the melt pool. In this respect, the important solidification data, such as solidification cooling rate, morphology factor, growth velocity and solidification thermal gradient are calculated during the solidification as well.