Please use this identifier to cite or link to this item: http://hdl.handle.net/11452/25415
Title: Hydrodynamic-thermal boundary layer development and mass transfer characteristics of a circular cylinder in confined flow
Authors: Dinçer, İbrahim
Uludağ Üniversitesi/Mühendislik Fakültesi/Makine Mühendisliği Bölümü.
0000-0002-4976-9027
Özalp, Abdurrahman Alper
ABI-6888-2020
6506131689
Keywords: Blockage
Boundary layer
Separation
Wall shear
Heat transfer
Mass transfer
Low-reynolds number
Literature data compilation
Convection heat-transfer
Forced-convection
Square cylinder
Fluid-flow
Moisture diffusivity
Numerical-simulation
Horizontal annulus
Mixed convection
Thermodynamics
Engineering
Boundary layers
Circular cylinders
Fluid dynamics
Heat exchangers
Hydrodynamics
Moisture
Alternating direction implicit method
Flow and heat transfer
Front face
Heat transfer value
Mass transfer coefficient
Moisture distribution
Stagnation points
Thermal activity
Thermal boundary layer
Thermal field
Vortex systems
Issue Date: Sep-2010
Publisher: Elsevier
Citation: Özalp, A. A. ve Dinçer, İ. (2010). "Hydrodynamic-thermal boundary layer development and mass transfer characteristics of a circular cylinder in confined flow". International Journal of Thermal Sciences, 49(9), 1799-1812.
Abstract: The effects of blockage on the hydrodynamic, thermal and mass transfer characteristics of a circular cylinder (CC) and their association with each other are investigated numerically, by considering the influence of blockage (beta=0.333-0.800) on the flow and heat transfer mechanisms in conjunction with moisture diffusivity (D=1 x 10(-8)-1 x 10(-5) m(2)/s) to show how much mass transfer behavior and phenomena are affected. As some comprehensive ANSYS-CFX runs are performed in the hydrodynamic and thermal fields around the CC, the moisture distributions within the CC are evaluated by Alternating Direction implicit method. It is determined that blockage causes thinner hydrodynamic and thermal boundary layers, rises the frictional and thermal activities, and shifts the separation locations (theta(s)) downstream to theta(s)=50.20 degrees, 41.98 degrees and 37.30 degrees for beta=0.333, 0.571 and 0.800. In the complete blockage scenario set, stagnation point heat transfer values are evaluated to be above those of the back-face, signifying the superior heat transfer enhancing capability of the stagnation point momentum activity when compared with the impact of downstream vortex system. The influence of moisture diffusivity on the overall drying times is determined to advance with stronger blockage. As the back face mass transfer coefficients (h(m-bf)) rise with a high beta, the contrary is valid for front face values (h(m-ff)), with the interpreting ratios of (h) over bar (m-bf)/(h) over bar (m)=0.51 and 0.57 and (h) over bar (m-ff)/(h) over bar (m)=1.49 and 1.43 for beta=0.333 and 0.800.
URI: https://doi.org/10.1016/j.ijthermalsci.2010.04.016
https://www.sciencedirect.com/science/article/pii/S1290072910001158
http://hdl.handle.net/11452/25415
ISSN: 1290-0729
Appears in Collections:Scopus
Web of Science

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