- Author
- Tom Bultreys (UGent) , Stefanie Van Offenwert (UGent) , Wannes Goethals (UGent) , Matthieu Boone (UGent) , Jan Aelterman (UGent) and Veerle Cnudde (UGent)
- Organization
- Project
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- A new data-assisted modelling paradigm for flow in rocks at the pore scale
- 3D X-ray velocimetry to explain fluid flow dynamics inside porous materials
- MoCCHa-CT: Model-coupled 4D-uCT for advanced material characterisation
- Joint deformation estimation and Computerized Tomographic reconstruction for studying dynamic processes
- UGCT – Ghent University Centre for X-ray Tomography
- Abstract
- Fluid flow through intricate confining geometries often exhibits complex behaviors, certainly in porous materials, e.g., in groundwater flows or the operation of filtration devices and porous catalysts. However, it has remained extremely challenging to measure 3D flow fields in such micrometer-scale geometries. Here, we introduce a new 3D velocimetry approach for optically opaque porous materials, based on time-resolved x-ray micro-computed tomography (CT). We imaged the movement of x-ray tracing micro-particles in creeping flows through the pores of a sandpack and a porous filter, using laboratory-based CT at frame rates of tens of seconds and voxel sizes of 12 μm. For both experiments, fully three-dimensional velocity fields were determined based on thousands of individual particle trajectories, showing a good match to computational fluid dynamics simulations. Error analysis was performed by investigating a realistic simulation of the experiments. The method has the potential to measure complex, unsteady 3D flows in porous media and other intricate microscopic geometries. This could cause a breakthrough in the study of fluid dynamics in a range of scientific and industrial application fields.
- Keywords
- Porous media, flow visualization, computational fluid dynamics, velocimetry, laminar flows, computed tomography, PARTICLE TRACKING, FLOW, FLUID, DISPLACEMENT, TRANSPORT, GLYCEROL, CAPTURE
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Citation
Please use this url to cite or link to this publication: http://hdl.handle.net/1854/LU-8749516
- MLA
- Bultreys, Tom, et al. “X-Ray Tomographic Micro-Particle Velocimetry in Porous Media.” PHYSICS OF FLUIDS, vol. 34, no. 4, 2022, doi:10.1063/5.0088000.
- APA
- Bultreys, T., Van Offenwert, S., Goethals, W., Boone, M., Aelterman, J., & Cnudde, V. (2022). X-ray tomographic micro-particle velocimetry in porous media. PHYSICS OF FLUIDS, 34(4). https://doi.org/10.1063/5.0088000
- Chicago author-date
- Bultreys, Tom, Stefanie Van Offenwert, Wannes Goethals, Matthieu Boone, Jan Aelterman, and Veerle Cnudde. 2022. “X-Ray Tomographic Micro-Particle Velocimetry in Porous Media.” PHYSICS OF FLUIDS 34 (4). https://doi.org/10.1063/5.0088000.
- Chicago author-date (all authors)
- Bultreys, Tom, Stefanie Van Offenwert, Wannes Goethals, Matthieu Boone, Jan Aelterman, and Veerle Cnudde. 2022. “X-Ray Tomographic Micro-Particle Velocimetry in Porous Media.” PHYSICS OF FLUIDS 34 (4). doi:10.1063/5.0088000.
- Vancouver
- 1.Bultreys T, Van Offenwert S, Goethals W, Boone M, Aelterman J, Cnudde V. X-ray tomographic micro-particle velocimetry in porous media. PHYSICS OF FLUIDS. 2022;34(4).
- IEEE
- [1]T. Bultreys, S. Van Offenwert, W. Goethals, M. Boone, J. Aelterman, and V. Cnudde, “X-ray tomographic micro-particle velocimetry in porous media,” PHYSICS OF FLUIDS, vol. 34, no. 4, 2022.
@article{8749516,
abstract = {{Fluid flow through intricate confining geometries often exhibits complex behaviors, certainly in porous materials, e.g., in groundwater flows or the operation of filtration devices and porous catalysts. However, it has remained extremely challenging to measure 3D flow fields in such micrometer-scale geometries. Here, we introduce a new 3D velocimetry approach for optically opaque porous materials, based on time-resolved x-ray micro-computed tomography (CT). We imaged the movement of x-ray tracing micro-particles in creeping flows through the pores of a sandpack and a porous filter, using laboratory-based CT at frame rates of tens of seconds and voxel sizes of 12 μm. For both experiments, fully three-dimensional velocity fields were determined based on thousands of individual particle trajectories, showing a good match to computational fluid dynamics simulations. Error analysis was performed by investigating a realistic simulation of the experiments. The method has the potential to measure complex, unsteady 3D flows in porous media and other intricate microscopic geometries. This could cause a breakthrough in the study of fluid dynamics in a range of scientific and industrial application fields.}},
articleno = {{042008}},
author = {{Bultreys, Tom and Van Offenwert, Stefanie and Goethals, Wannes and Boone, Matthieu and Aelterman, Jan and Cnudde, Veerle}},
issn = {{1070-6631}},
journal = {{PHYSICS OF FLUIDS}},
keywords = {{Porous media,flow visualization,computational fluid dynamics,velocimetry,laminar flows,computed tomography,PARTICLE TRACKING,FLOW,FLUID,DISPLACEMENT,TRANSPORT,GLYCEROL,CAPTURE}},
language = {{eng}},
number = {{4}},
pages = {{13}},
title = {{X-ray tomographic micro-particle velocimetry in porous media}},
url = {{http://doi.org/10.1063/5.0088000}},
volume = {{34}},
year = {{2022}},
}
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