EFFECT OF SECOND-ORDER VELOCITY SLIP AND TEMPERATURE JUMP CONDITIONS ON ROTATING DISK FLOW IN THE CASE OF BLOWING AND SUCTION WITH ENTROPY GENERATION

The energy crisis in the last two decades has turned the attention of scientific and engineering communities to redesigned and developed heat-fluid interaction systems. All of the details in analyses are reconsidered to reduce energy consumption. The present work examines the effects of temperature and velocity jump conditions on heat transfer, fluid flow over a single rotating disk. The flow due to rotating disks is of great interest in thermal engineering as it appears in many industrial and engineering applications such as gas turbine engines and micropumps. The related equation of flow, which is nonlinear and coupled, and heat transfer governing equations are reduced to ordinary differential equations by applying the so-called classical approach which was first introduced by Von Karman. Instead of this approach, a pure numerical one, the recently developed popular semi numerical analytical technique differential transform method (DTM), with Benton transformation, is employed to solve the reduced governing equations under the assumptions of velocity-slip and temperature jump conditions on the disk surface. The solution is valid for continuum and slip-flow regime which has a Knudsen number smaller than 0.1. The results attained for various physical cases are interpreted by using non-dimensional parameters related to flow and temperature fields. Velocity and temperature profiles are presented graphically. The effect of various parameters such as the Knudsen Number (Kn), Reynolds Number (Re) and Nusselt Numbers (Nu) are examined. The observed physical consequences are the velocity slip and temperature jump at the wall becoming strongly dependant on the Knudsen number. It is also observed that the temperature jump and velocity jump conditions have nonlinear effects on slip; these effects are investigated with great details and presented graphically.

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Algebraic solutions of flow and heat for some nanofluids over deformable and permeable surfaces

International Journal of Numerical Methods for Heat &amp Fluid Flow ◽

10.1108/hff-09-2016-0358 ◽

2017 ◽

Vol 27 (10) ◽

pp. 2259-2267 ◽

Cited By ~ 3

Author(s):

Mustafa Turkyilmazoglu

Keyword(s):

Heat Transfer ◽

Design Methodology ◽

Temperature Jump ◽

Volume Fraction ◽

Velocity Slip ◽

Jump Conditions ◽

Content Type ◽

Layer Flow ◽

Working Out ◽

Algebraic Solutions

Purpose This paper aims to working out exact solutions for the boundary layer flow of some nanofluids over porous stretching/shrinking surfaces with different configurations. To serve to this aim, five types of nanoparticles together with the water as base fluid are under consideration, namely, Ag, Cu, CuO, Al2O3 and TiO2. Design/methodology/approach The physical flow is affected by the presence of velocity slip as well as temperature jump conditions. Findings The knowledge on the influences of nanoparticle volume fraction on the practically significant parameters, such as the skin friction and the rate of heat transfer, for the above considered nanofluids, is easy to gain from the extracted explicit formulas. Originality/value Particularly, formulas clearly point that the heat transfer rate is not only dependent on the thermal conductivity of the material but it also highly relies on the heat capacitance as well as the density of the nanofluid under consideration.

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Entropy generation for microscale forced convection: Effects of different thermal boundary conditions, velocity slip, temperature jump, viscous dissipation, and duct geometry

International Communications in Heat and Mass Transfer ◽

10.1016/j.icheatmasstransfer.2007.05.019 ◽

2007 ◽

Vol 34 (8) ◽

pp. 945-957 ◽

Cited By ~ 70

Author(s):

K. Hooman

Keyword(s):

Boundary Conditions ◽

Forced Convection ◽

Viscous Dissipation ◽

Entropy Generation ◽

Temperature Jump ◽

Velocity Slip ◽

Thermal Boundary Conditions ◽

Duct Geometry

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Combined Effects of Temperature and Velocity Jump on the Heat Transfer, Fluid Flow, and Entropy Generation Over a Single Rotating Disk

Journal of Heat Transfer ◽

10.1115/1.4002098 ◽

2010 ◽

Vol 132 (11) ◽

Cited By ~ 9

Author(s):

A. Arikoglu ◽

G. Komurgoz ◽

I. Ozkol ◽

A. Y. Gunes

Keyword(s):

Heat Transfer ◽

Fluid Flow ◽

Entropy Generation ◽

Rotating Disk ◽

Heat Transfer Fluid ◽

Combined Effects ◽

Jump Conditions ◽

Governing Equations ◽

Velocity Jump ◽

Effects Of Temperature

The present work examines the effects of temperature and velocity jump conditions on heat transfer, fluid flow, and entropy generation. As the physical model, the axially symmetrical steady flow of a Newtonian ambient fluid over a single rotating disk is chosen. The related nonlinear governing equations for flow and thermal fields are reduced to ordinary differential equations by applying so-called classical approach, which was first introduced by von Karman. Instead of a numerical method, a recently developed popular semi numerical-analytical technique; differential transform method is employed to solve the reduced governing equations under the assumptions of velocity and thermal jump conditions on the disk surface. The combined effects of the velocity slip and temperature jump on the thermal and flow fields are investigated in great detail for different values of the nondimensional field parameters. In order to evaluate the efficiency of such rotating fluidic system, the entropy generation equation is derived and nondimensionalized. Additionally, special attention has been given to entropy generation, its characteristic and dependency on various parameters, i.e., group parameter, Kn and Re numbers, etc. It is observed that thermal and velocity jump strongly reduce the magnitude of entropy generation throughout the flow domain. As a result, the efficiency of the related physical system increases. A noticeable objective of this study is to give an open form solution of nonlinear field equations. The reduced recurative form of the governing equations presented gives the reader an opportunity to see the solution in open series form.

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Analysis of gaseous flow in a micropipe with second order velocity slip and temperature jump boundary conditions

Heat and Mass Transfer ◽

10.1007/s00231-014-1368-3 ◽

2014 ◽

Vol 50 (12) ◽

pp. 1649-1659 ◽

Cited By ~ 11

Author(s):

Hari Mohan Kushwaha ◽

S. K. Sahu

Keyword(s):

Boundary Conditions ◽

Temperature Jump ◽

Velocity Slip ◽

Second Order ◽

Gaseous Flow

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Modeling and theoretical investigation of curved parabolized surface of second-order velocity slip flow: Combined analysis of entropy generation and activation energy

Modern Physics Letters B ◽

10.1142/s0217984920503832 ◽

2020 ◽

Vol 34 (33) ◽

pp. 2050383

Author(s):

Sumaira Qayyum ◽

M. Ijaz Khan ◽

Wathek Chammam ◽

W. A. Khan ◽

Zulfiqar Ali ◽

...

Keyword(s):

Activation Energy ◽

Entropy Generation ◽

Fluid Velocity ◽

Slip Flow ◽

Mhd Flow ◽

Velocity Slip ◽

Second Order ◽

Bejan Number ◽

Biot Numbers ◽

Chemical Reaction Parameter

Here our purpose is to explore the entropy generation in nanofluid MHD flow by curved stretching sheet; second-order slip is considered. Additional effects of viscous dissipation, Joule heating, and activation energy are taken. Temperature and concentration boundary conditions are considered convectively. For convergence of series solution NDSolve MATHEMATICA is used. Velocity, Bejan number, concentration, temperature, and entropy generation graphs are sketched for important parameters. For greater estimations of first- and second-order velocity slip parameters fluid velocity reduces. The thermal and solutal Biot numbers enhance the temperature and concentration, respectively. The concentration also has direct relation with activation energy. Entropy generation reduces for chemical reaction parameter and first- and second-order slip parameters.

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