Laminar Pulsating Flow at the Initial Segment of a Flat Channel

E. P. Valueva; Валуева Е. П.; V. S. Zukin; Зюкин В. С.

doi:10.31857/S0040364423040166

Laminar Pulsating Flow at the Initial Segment of a Flat Channel

作者: Valueva E.P.¹, Zukin V.S.¹
隶属关系:
1. National Research University Moscow Power Engineering Institute
期: 卷 61, 编号 5 (2023)
页面: 723-729
栏目: Heat and Mass Transfer and Physical Gasdynamics
URL: https://journals.rcsi.science/0040-3644/article/view/252365
DOI: https://doi.org/10.31857/S0040364423040166
ID: 252365

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详细

A method is proposed for solving the problem of a pulsating quasistationary flow in a channel, based on the use of calculation results for stationary flow. This approach is applicable at low relative oscillation frequencies (for Womersley numbers less than one). The solution to the system of stationary equations of motion and continuity in the initial section of a flat channel was carried out by the finite difference method using an iterative implicit unconditionally stable scheme. The hydrodynamic characteristics of a developing pulsating laminar flow in a flat channel have been studied. The results of calculating the longitudinal velocity component and the Poiseuille and Euler numbers are presented as a function of the relative amplitude of the oscillation of the cross-sectional average velocity A and dimensionless length of the channel. It was found that for A values exceeding unity, the period-averaged coefficients of hydraulic resistance and friction resistance near the inlet to the channel are significantly higher than these values for a stationary flow. It has been shown that in order to achieve a pulsating flow with large amplitudes of oscillations, it is necessary to create a time-average pressure drop approximately three times higher (at A = 5) than for a stationary flow.

作者简介

E. Valueva

National Research University Moscow Power Engineering Institute

Email: ep.valueva@gmail.com
111250, Moscow, Russia

V. Zukin

National Research University Moscow Power Engineering Institute

编辑信件的主要联系方式.
Email: ep.valueva@gmail.com
111250, Moscow, Russia

参考

Валуева Е.П., Пурдин М.С. Гидродинамика и теплообмен при пульсирующем с большими амплитудами ламинарном течении в каналах // Теплофизика и аэромеханика. 2018. Т. 25. № 5. С. 735.
Валуева Е.П., Пурдин М.С. Теплообмен при ламинарном течении в прямоугольных каналах // Теплофизика и аэромеханика. 2016. Т. 23. № 6. С. 893.
Ray S., Ünsal B., Durst F. Development Length of Sinusoidally Pulsating Laminar Pipe Flows in Moderate and High Reynolds Number Regimes // Int. J. Heat Fluid Flow. 2012. V. 37. P. 167.
Валуева Е.П., Зюкин В.С. Теплообмен на начальном гидродинамическом участке плоского канала с граничными условиями первого рода при ламинарном пульсирующем течении // ТВТ. 2022. Т. 60. № 1. С. 56.
Валуева Е.П., Гаряев А.Б., Клименко А.В. Особенности гидродинамики и теплообмена при течении в микроканальных технических устройствах. М.: Изд. дом МЭИ, 2016. 138 с.
Валуева Е.П., Пурдин М.С. Пульсирующее ламинарное течение в прямоугольном канале // Теплофизика и аэромеханика. 2015. Т. 22. № 6. С. 761.
Bodoia J.R., Osterle J.F. Finite Difference Analysis of Plane Poiseulle and Coutte Flow Developments // Appl. Sci. Res. 1961. V. 10. P. 265.
Durst F., Ray S., Ünsal B., Bayoumi O.A. The Development Lengths of Laminar Pipe and Channel Flows // ASME J. Fluids Eng. 2005. V. 127. P. 1154.
Joshi Y., Vinoth B.R. Entry Lengths of Laminar Pipe and Channel Flows // J. Fluids Eng. 2018. V. 140. № 6. P. 061203.
Atkinson B., Brocklebank M.P., Card C.H., Smith J.M. Low Reynolds Number Developing Flows // AlChE J. 1969. V. 15. № 4. P. 548.