A numerical technique to solve a problem of the fluid motion in a straight plane rigid duct with two axisymmetric rectangular constrictions-Reference-Cited by-同舟云学术

A numerical technique to solve a problem of the fluid motion in a straight plane rigid duct with two axisymmetric rectangular constrictions

Published:2022-03-30 Issue:1 Volume: Page:48-57
ISSN:2518-153X
Container-title:Reports of the National Academy of Sciences of Ukraine
language:
Short-container-title:Dopov. Nac. akad. nauk Ukr.

Author:

Borysyuk A.O.^ORCID

Abstract

A second-order numerical technique is developed to study the steady laminar fluid motion in a straight two-dimensional hard-walled duct with two axisymmetric rectangular constrictions. In this technique, the governing relations are solved via deriving their integral analogs, performing a discretization of these analogs, simplifying the obtained (after making the discretization) coupled nonlinear algebraic equations, and the final solution of the resulting (after making the simplification) uncoupled linear ones. The discretization consists of the spatial and temporal parts. The first of them is performed with the use of the TVD-scheme and a two-point scheme of discretization of the spatial derivatives, whereas the second one is made on the basis of the implicit three-point asymmetric backward differencing scheme. The above-noted uncoupled linear algebraic equations are solved by an appropriate iterative method, which uses the deferred correction implementation technique and the technique of conjugate gradients, as well as the solvers ICCG and Bi-CGSTAB.

Publisher

National Academy of Sciences of Ukraine (Co. LTD Ukrinformnauka) (Publications)

Reference5 articles.

1. Borysyuk, A. O. (2019). Flow modelling in a straight rigid-walled duct with two rectangular axisymmetric narrowings. Part 1. A theory. Bulletin of V. N. Karazin Kharkiv National University, series "Mathematical Modeling. Information Technology. Automated Control Systems", 44, pp. 4-15. https: //doi. org/10. 26565/2304-6201-2019-44-01

2. Borysyuk, A. O. & Borysyuk, Ya. A. (2017). Wall pressure fluctuations behind a pipe narrowing of various shapes. Science-Based Technologies, 32, No. 2, pp. 162-170. https: //doi. org/10. 18372/2310-5461. 34. 11615

3. Brujatckij, E. V., Kostin, A. G. & Nikiforovich, E. V. (2011). Numerical investigation of the velocity and pressure fields in a flat channel having a square-shape obstacle on the wall. Appl. Hydromech., 13, No. 3, pp. 33-47 (in Russian).

4. Fluid mechanics of arterial stenosis;Young;J Biomech Eng 101 No 3,1979

5. Ferziger, J. H. & Peri'c, M. (2002). Computational methods for fluid dynamics, 3rd ed. Berlin: Springer.