Flow modelling in a straight hard-walled duct with two rectangular axisymmetric narrowings
Abstract
A method for modelling the flow in a rigid-walled duct with two narrowings has been developed. It has the second order of accuracy in the spatial and the first order of accuracy in the temporal coordinates, provides high stability of the solution, and compared to the similar methods requires much less computational time to obtain a result. According to the method, the stream function and the vorticity are introduced initially, and consequently the transition from the governing equations, as well as the initial and boundary conditions to the proper relationships for the introduced variables is performed. The obtained relationships are rewritten in a non-dimensional form. After that a computational domain and a uniform computational mesh are chosen, and the corresponding discretization of the non-dimensional relationships is performed. Finally, the linear algebraic equations obtained as a result of the discretization are solved.
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Seo J.H., Mittal R. A coupled flow-acoustic computational study of bruits from a modeled stenosed artery. Medical and Biological Engineering and Computing. 2012. Vol. 50. P. 1025-1035.
Varghese S.S., Frankel S.H. Numerical modeling of pulsatile turbulent flow in stenotic vessels. Journal of Biomechanical Engineering. 2013. Vol. 125. P. 445-460.
Jahangiri M., Saghafian M., Sadeghi M.R. Numerical study of turbulent pulsatile blood flow through stenosed artery using fluid-solid interaction. Computational and Mathematical Methods in Medicine. 2015. Vol. 15. P. 1-10.
Tabe R., Ghalichi F., Hossainpour S., Ghasemzadeh K. Laminar-to-turbulence and relaminarization zones detection by simulation of low Reynolds number turbulent blood flow in large stenosed arteries. Biomedical Materials and Engineering. 2016. Vol. 27. P. 119-129.
Borisyuk A.O. Experimental study of wall pressure fluctuations in rigid and elastic pipes behind an axisymmetric narrowing. Journal of Fluids and Structures. 2010. Vol. 26. P. 658–674.
Garcia J., Marrufo O.R., Rodriguez A.O., Larose E., Pibarot P., Kadem L. “Cardiovascular magnetic resonance evaluation of aortic stenosis severity using single plane measurement of effective orifice area. Journal of Cardiovascular Magnetic Resonance. 2012. Vol. 12. P. 1-12.
Garcia J., Markl M., Schnell S., Allen B., Entezari P., Mahadevia P., Malaisrie S.C., Pibarot P., Carr J., Barker A.J. Evaluation of aortic stenosis severity using 4D flow jet shear layer detection for the measurement of valve effective orifice area. Magnetic Resonance Imaging. 2014. Vol. 32. P. 891-898.
Srivastava N. Analysis of flow characteristics of the blood flowing through an inclined tapered porous artery with mild stenosis under the Influence of an inclined magnetic field. Journal of Biophysics. 2014. Vol. 14. P. 1-9.
Reddy J.V., Srikanth D. The polar fluid model for blood flow through a tapered artery with overlapping stenosis: effects of catheter and velocity slip. Applied Bionics and Biomechanics. 2015. Vol. 15. P.1-12.
Zaman A., Ali N., Beg O.A. Numerical simulation of unsteady micropolar hemodynamics in a tapered catheterized artery with a combination of stenosis and aneurysm. Medical and Biological Engineering and Computing. 2016. Vol. 54. P. 1423-1436.
Ali N., Zaman A., Sajid M., Nieto J.J., Torres A. Unsteady non-Newtonian blood flow through a tapered overlapping stenosed catheterized vessel. Mathematical Biosciences. 2015. Vol. 269. P. 94-103.
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