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Numerical Study of the Effect of a Power-law Fluid Flow Structures on Levels of Mixing in a Taylor Couette Configuration

Publish place: Journal of Applied Fluid Mechanics، Vol: 16، Issue: 6
Publish Year: 1402
نوع سند: مقاله ژورنالی
زبان: English
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https://civilica.com/doc/1624873

شناسه ملی سند علمی:

JR_JAFM-16-6_011

تاریخ نمایه سازی: 12 فروردین 1402

Abstract:

This work is a numerical study on the effects of the flow structures of the power-law fluid between two concentric cylinders with an upward laminar axial flow on levels of mixing and mean residence time through the Taylor Couette system. The cylindrical annular duct presents a radius ratio of ۰.۵ and an aspect ratio of ۸. The inner cylinder is rotating while the outer one is kept at rest. The residence time distributions (R.T.D.) method and the mean residence time (Tm) are used to determine the number of tanks in series and the dispersion coefficient to evaluate levels of mixing. To this end, a pulsed input injection of a tracer is computing at the outlet of the annulus. As a main objective of this study, is to analyze the effect of the flow structure of a power-law fluid between two concentric cylinders on the mixing level and mean residence time in a Taylor Couette system. The novelty of our work is the use of power-law fluids as particles-carrying fluids. Several parameters, such as the axial Reynolds number (Re), the Taylor number (Ta), and the power-law index behavior (n), are used to show their impact on levels of mixing. It is shown that when n increases, the number of stirred tanks in series N increases for pseudoplastic fluids (n<۱), indicating low levels of mixing while the parameter (N) decreases for dilatants fluids (n>۱), revealing high levels of mixing. The increase of the power-law index in the range of ۰.۶۱ increases the dispersion coefficient points to the well-mixing.

Keywords:

Poiseuille-Taylor-Couette flow , Residence time distribution , Meantime , Lattice Boltzmann method , Non-Newtonians fluids

Authors

S. Khali

USTHB – Faculty of Mechanical and Process Engineering (FGMGP), Laboratory of Multiphase Transport and Porous Media (LTPMP), B.P.۳۲, El Alia Bab Ezzouar ۱۶۱۱۱, Algiers, Algeria

R. Nebbali

USTHB – Faculty of Mechanical and Process Engineering (FGMGP), Laboratory of Multiphase Transport and Porous Media (LTPMP), B.P.۳۲, El Alia Bab Ezzouar ۱۶۱۱۱, Algiers, Algeria

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