Measurements of wall shear stress with the lattice Boltzmann method and staircase approximation of boundaries

Measurements of wall shear stress with the lattice Boltzmann method and staircase approximation of boundaries

We analyze the accuracy of wall shear stress measurements in lattice Boltzmann simulations that are based on a voxel representation of the geometry and staircase approximation of boundaries. Such approximations are commonly used in the context of lattice Boltzmann simulations, because they favor the...

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Bibliographic Details
Published in:Computers & fluids Vol. 39; no. 9; pp. 1625 - 1633
Main Authors: Stahl, B., Chopard, B., Latt, J.
Format: Journal Article
Language:English
Published: Kidlington Elsevier Ltd 01-10-2010
Elsevier
Subjects:
Accuracy
Approximation
Biological and medical sciences
Blood and lymphatic vessels
Boundaries
Cardiology. Vascular system
CFD
Computational methods in fluid dynamics
Computer simulation
Diseases of the peripheral vessels. Diseases of the vena cava. Miscellaneous
Exact sciences and technology
Flows in ducts, channels, nozzles, and conduits
Fluid dynamics
Fundamental areas of phenomenology (including applications)
Lattice Boltzmann
Lattices
Mathematical analysis
Medical sciences
Physics
Voxel geometry
Wall shear stress
Wall shear stresses
Walls
CFD
Lattice Boltzmann
Wall shear stress
Voxel geometry
Boltzmann equation
Pipe flow
Computational fluid dynamics
Digital simulation
Aneurysm
Cardiovascular disease
Vascular disease
Blood circulation
Voxel
Lattice model
Curved pipe
Shear stress
Modelling
Inclined pipe
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Description
Summary:We analyze the accuracy of wall shear stress measurements in lattice Boltzmann simulations that are based on a voxel representation of the geometry and staircase approximation of boundaries. Such approximations are commonly used in the context of lattice Boltzmann simulations, because they favor the use of simple and highly efficient data structures. We show on several two- and three-dimensional simulations that this low-order approximation of the boundary affects the accuracy of wall shear stress measurements in areas directly adjacent to the wall. A few lattice nodes apart from the wall, the accuracy is however largely improved, and can be considered to be compatible with the overall accuracy of a simulation at a given coarseness level of the grid. This result is interpreted as a justification for the use of walls with staircase shape, even in simulations with high expectations regarding the level of accuracy. Furthermore, we propose a novel method for establishing the direction of the wall normal, a quantity which is required for the computation of the wall shear stress. With this method, the wall normal is computed from local data that is extracted from the results of the fluid flow simulation. Owing to the nature of the flow dynamics, which tends to smooth out the asperities of the wall, the information on the wall orientation obtained in this way is observed to be of high quality.
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ISSN:0045-7930
1879-0747
DOI:10.1016/j.compfluid.2010.05.015