Development of non-boundary-fitted Cartesian grid method for numerical simulation of mechanical heart valve and the potential for blood clotting
Computational fluid dynamics (CFD) simulations are becoming a reliable tool in understanding disease progression, investigating blood flow patterns and evaluating medical device performance such as mechanical heart valves (MHV). Previous studies indicated that the non-physiological flow patter...
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| Format: | Thesis |
| Language: | English |
| Published: |
2018
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| Subjects: | |
| Online Access: | http://psasir.upm.edu.my/id/eprint/71429/1/FK%202018%2095%20-%20IR.pdf http://psasir.upm.edu.my/id/eprint/71429/ |
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| Institution: | Universiti Putra Malaysia |
| Language: | English |
| Summary: | Computational fluid dynamics (CFD) simulations are becoming a reliable tool in understanding
disease progression, investigating blood flow patterns and evaluating medical device
performance such as mechanical heart valves (MHV). Previous studies indicated that
the non-physiological flow pattern (i.e. recirculation, stagnation, and vortex) might cause
a trapped platelet and be responsible for the formation of blood clots in MHV. Accurate
simulation of this flow requires a high order accuracy numerical scheme together with
a scale resolving turbulence model such as large eddy simulation (LES). This requires
the use of uniform orthogonal grids for the descretisation process, which is not able to
handle complex branching arterial domains that contain MHV, where the generation are
usually boundary-fitted (BF) grid with non-orthogonality and distortions. Therefore, nonboundary
fitted (NBF) Cartesian grid method is an alternative solution. The objective of
this study is to develop a new NBF method based on the volume of fluid (VOF), containing
the colour function, namely NBF-VOF Cartesian grid method. A single set of governing
equation is used for both solid and fluids identified by unity colour function and zero
colour function respectively. The solid was treated as a fluid with very high viscosity to
theoretically reduce its deformability, and subsequently satisfy a no-slip condition at the
boundary. In the first attempt, we found that in prior, the treatment was not satisfied. To
suppress the fluid velocities in the solid, we introduced the artificial term derived from
the colour function into an algebraic system of momentum equations, which had a significant
impact on the originality of this study. The developed solver, NBF-VOF, is then
thoroughly validated using a variety of numerical and experimental results available in the
literature which is Hagen-Poiseuille flow, lid-driven cavity, flow over a cylinder, 90o tube
flow, and pulsatile flow through the real anatomic aorta. Opensource CFD software was
used as our simulation platform. Although the second order method degenerates the spatial
accuracy of convergence rate as function of the grid size from 2 to 1.5, an agreement
was found for all cases qualitative and quantitatively. The grid uncertainty obtained was less than 5%, which was within the acceptable range. The computational time was lower
when the viscosity of solid was higher. However, higher solid viscosity gives lagging in
the result for transient cases. Despite this, using higher time step, until the maximum
Courant number of 4.0, can speed up the simulation time and preserved the stability. Finally,
another breakthrough in this study was the application of the solver to simulate
pulsatile blood flow of MHV placed in an axisymmetric and real patient anatomic aorta
with the sinus, which reveals complex blood flow patterns, shear stress loading, and history
of particles age in the local domain, that consequently can identified the potential of
blood clotting. |
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