The aim of this thesis is to study the Lattice Boltzmann method for fluid dynamics
by using moment based boundary condition to implement no-slip and partial slip boundary conditions in two and three dimensions. The main topics are the theory of the Lattice Boltzmann method, an examination of boundary conditions and the application of the Lattice Boltzmann method to a variety of
fluid flows. We developed and successfully implemented combinations of no-slip,
Navier-slip, pressure boundaries and inlet conditions in two and three dimensions
using moment-based boundary conditions including careful treatments of conditions
along edges and at corners. A useful advantage of the use of moment based
boundary conditions is that it allows for Navier-slip conditions to be implemented
exactly i.e. without the use of arbitrary coefficients required in some other methods.
The first application of the method is pulsatile fluid flow with no-slip and Navierslip
boundary conditions in two and three dimensions. The results are in good
agreement with exact solutions and some interesting results related to non-convergence of acoustic scaling for the two dimensions are found. The next application is three-dimensional laminar flow in a square duct driven by a body force. The results agree well with the analytical solution. Next, a study is presented of the rarefaction and compressibility effect on laminar flow between two parallel plates
and in a three-dimensional micro-duct which are driven by differential pressures
at the inlet and outlet. The results are again compatible with those found in the
literature. Finally, we investigate the developing three-dimensional laminar flow in
the entrance region of a rectangular channel. Results demonstrate some interesting
Reynolds number dependence and are found to be in line with the literature
for high Reynolds number.
Date of Award | 2020 |
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Original language | English |
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Awarding Institution | |
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Supervisor | David Graham (Other Supervisor) |
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- Lattice Boltzmann method
- moment based boundary condition
- three dimensions
Lattice Boltzmann Method For 2D and 3D Flows in Channels and Ducts with Slip and no-Slip Walls
Bu sinnah, Z. A. (Author). 2020
Student thesis: PhD