Modeling of pipe flows

被引：0

作者：

Pavlovsky, V. A. ^{[1
]}

Chistov, A. L. ^{[2
]}

Kuchinsky, D. M. ^{[1
]}

机构：

[1] St Petersburg State Marine Tech Univ, 3 Locmanskaya Ul, St Petersburg 190121, Russia

[2] St Petersburg State Univ, 7-9 Univ Skaya Nab, St Petersburg 199034, Russia

来源：

VESTNIK SANKT-PETERBURGSKOGO UNIVERSITETA SERIYA 10 PRIKLADNAYA MATEMATIKA INFORMATIKA PROTSESSY UPRAVLENIYA | 2019年 / 15卷 / 01期

关键词：

pipe flow; viscosity; f-model of turbulence; Reynolds number; pressure difference; differential equations; boundary conditions; velocity profile; resistance coefficient;

D O I：

10.21638/11702/spbu10.2019.107

中图分类号：

O1 [数学];

学科分类号：

0701 ; 070101 ;

摘要：

Lots of technical devices use flows in pipes and channels caused by pressure drop, along with one's axis, which is energy consuming and has to be estimated. For the estimation resistant coefficient, dependent on flow regime and streamlined surface roughness, is required. Turbulence f-model applicable for calculation for both laminar and turbulent flow and smooth and rough walls is used for investigation. The problem of incompressible viscous liquid steady flow in a smooth round pipe is considered for different Reynolds numbers. First integrals for velocity profile and turbulence measure are obtained in form of transcendental equations and solved by Newton's method for algebraic equation system. Calculated results are compared with data from alternative theoretical approaches and experiments.

引用

页码：93 / 106

页数：14

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