MATHEMATICAL MODELING OF LAMINAR SYMMETRICAL FLOW WITH VISCOSITY

Article Sidebar

Yevrosiyo matematik nazariya va kompyuter fanlari jurnali
PDF (English)
Выпуск: Том 212 : Eurasian Journal of Mathematical Theory and Computer Sciences
Раздел: Статьи
Опубликован:

Main Article Content

Intern researcher at the Institute of Seismic Strength of Mechanical Structures of the Academy of Sciences of the Republic of Uzbekistan
info@in-academy.uz
Fergana Polytechnic Institute, Fergana, Uzbekistan
ibroximov-2022@mail.ru

Аннотация:

Until now, there are many works dedicated to the drastic simplification of the Nave-Stokes equations and finding their particular solutions that are very relevant for practice. These studies have generally been based on either symmetry considerations or dimensionality and dimension theory. In this article, a mathematical model of the motion of an incompressible fluid in a diffusion nozzle was created and numerical results were obtained. For this, the Nave-Stokes equation was reduced to a parabolic equation with Mises substitutions. The radial and axial velocities of the liquid were determined using the obtained numerical results.

Article Details

Как цитировать:

Abduxamidov , S. ., & Ibrokhimov , A. . (2022). MATHEMATICAL MODELING OF LAMINAR SYMMETRICAL FLOW WITH VISCOSITY. Евразийский журнал математической теории и компьютерных наук, 2(12), 9–14. извлечено от https://in-academy.uz/index.php/EJMTCS/article/view/5586

Библиографические ссылки:

[1]. Loitsyansky L.G. The mechanics of fluid and gas, Moscow, Science. p. 840, Mexanika jidkocti i gaza, Moscow, Nauka, (1987)

[2]. Андерсон Д., Таннехил Дою., Плетчер Р. Вычислительная гидромеханика и теплообмен //- М.: Мир, 1990.- Т.1- 384с.; Т.2 - 392с

[3]. Kolmogorov A.N. Equations of turbulent motion of an incompressible fluid. Izvestia Academy of Sciences, USSR; 1942, Physics 6: – P. 56-58.

[4]. Patankar S.V. Numerical Heat Transfer and Fluid Flow. Taylor&Francis. ISBN 978-0-89116-522-4, 1980.

[5]. Самарский А.А,, Николаев Е.С. Методы решения сеточных уравнений. М.: Наука, 1978. – 592 с.

[6]. Ibrokhimov A. R. U. et al. Numerical Simulation of Two-Phase Flux in Centrifugal Separator //CENTRAL ASIAN JOURNAL OF THEORETICAL & APPLIED SCIENCES. – 2021. – Т. 2. – №. 12. – С. 238-243.

[7].Erkinjonovich A. Z. et al. Water Consumption Control Calculation In Hydraulic Ram Device //E-Conference Globe. – 2021. – С. 119-122.

[8].Madaliev M. E. U. et al. Modeling of Deformation Processes and Flow of Highly Concentrated Suspensions in Cylindrical Pipelines //Middle European Scientific Bulletin. – 2021. – Т. 18. – С. 128-136.

[9].Madaliev E. U. et al. Comparison of Turbulence Models for the Problem of an Asymmetric Two-Dimensional Plane Diffuser //Middle European Scientific Bulletin. – 2021. – Т. 18. – С. 119-127.

[10].Madaliev E. U. et al. Investigation of the Spalart-Allmares Turbulence Model for Calculating a Centrifugal Separator //Middle European Scientific Bulletin. – 2021. – Т. 18. – С. 137-147.

[11].Madaliev M. E. U. et al. Investigation of the Influence of the Computational Grid for Turbulent Flow //Middle European Scientific Bulletin. – 2021. – Т. 18. – С. 111-118.

[12].Ibrokhimov A. R. U. et al. Comparison of Numerical Results of Turbulence Models for Excessive Speed and Temperature in Waterflow //CENTRAL ASIAN JOURNAL OF THEORETICAL & APPLIED SCIENCES. – 2021. – Т. 2. – №. 12. – С. 202-208.

[13]. Маликов З. М. и др. ЧИСЛЕННОЕ ИССЛЕДОВАНИЕ ТЕЧЕНИЯ В ПЛОСКОМ ВНЕЗАПНО РАСШИРЯЮЩЕМСЯ КАНАЛЕ НА ОСНОВЕ ДВУХЖИДКОСТНОЙ МОДЕЛИ ТУРБУЛЕНТНОСТИ И МОДЕЛИ УИЛКОКСА //Проблемы машиноведения. – 2021. – С. 204-211.

[14]. Abduxamidov S. K. et al. Loss of Napor in Cylinder Pipe Flow //International Journal of Development and Public Policy. – 2021. – Т. 1. – №. 7. – С. 27-30.

[15]. Kaxarboyevich A. S., Turg’unboyevna C. L. SUYUQLIK OQIMINING BARQAROR ILGARILANMA HARAKATIGA OID TUSHUNCHALAR //Современные научные решения актуальных проблем. – 2022. – №. January.