122

In the article, generalized formulas for determining the hydrodynamic characteristics of a fluid flow in axisymmetric channels are obtained. As an example, analytical expressions for the pressure and average flow velocity are obtained when fluid flows out of a cylindrical channel of a constant cross section and from a channel of a hyperbolic form. In perspective, by introducing an arbitrary arithmetic expression of the axisymmetric section of the channel, it is possible to determine the hydrodynamic characteristics of the flow. Research methods are based on Newton's rheological law; the continuity equation and the Navier-Stokes equation, which are the basic equations of fluid flow; the method of mathematical modeling and the analytical method of its solutions

  • Web Address
  • DOI
  • Date of creation in the UzSCI system 08-09-2022
  • Read count 122
  • Date of publication 30-08-2022
  • Main LanguageIngliz
  • Pages213-219
English

In the article, generalized formulas for determining the hydrodynamic characteristics of a fluid flow in axisymmetric channels are obtained. As an example, analytical expressions for the pressure and average flow velocity are obtained when fluid flows out of a cylindrical channel of a constant cross section and from a channel of a hyperbolic form. In perspective, by introducing an arbitrary arithmetic expression of the axisymmetric section of the channel, it is possible to determine the hydrodynamic characteristics of the flow. Research methods are based on Newton's rheological law; the continuity equation and the Navier-Stokes equation, which are the basic equations of fluid flow; the method of mathematical modeling and the analytical method of its solutions

Author name position Name of organisation
1 Khasanov B.. teacher Almalyk Branch, Tashkent State Technical University
Name of reference
1 S. Dogan. Numerical comparison of thermal and hydraulic performances for heat exchangers having circular and elliptic cross-section. “International journal of hear and mass transfer”, 2019
2 S.M.A. Navqi. Numerical analysis on performances of shell side in segmental baffles and novel clamping anti-vibration baffles with square twisted tubes shell and tube heat exchangers. “Energy prosedia”, 2019. 5770
3 K. Karimov., M.K. Khudjaev., E. Nematov., D. Khurramov. Simulation of fluid outflow from a channel with complex geometry. “Journal E3S web of conferences”, 2020. 224
4 K. Karimov., M. Khudjaev., A. Akhmedov. Modeling fluid outflow froma cannel consisting of three different segments. “Journal E3S web of conferences”, 2021. 258
5 C.K. Selvi., A.N. Srinivas. “Pulsatile flow of Jeffrey fluid in a porous elastic tube with variable cross-section under the effect of magnetic field”, 2018. 439
6 Sh. Jasmeen., S. Asghar. “Peristaltic motion of magneto hydrodynamic viscous fluid in a curved circular tube. results in physics”, 2017. 3307
7 M. Khudjaev. Analytical solution of the Navier-Stokes equations reduced to the thirdorder equation for the problem of fluid motion in a round pipe. “Journal of physics: conference series”, 2020
8 L.G. Loitsyansky. “Mechanics of fluid and gas”, 2003. 840
9 A. Dubinov., V. Selemir. Hydrodynamic and physio-chemical phenomena in liquid droplets under the action of nanosecond spark discharges. “Review. advances in colloid and interface science”, 2019. 271
10 S.M. Korobeynikov., V.B. Yassinskiy. Study of partial discharges in liquids. “Journal of electrostatics”, 2020. 103
Waiting