Please use this identifier to cite or link to this item: http://hdl.handle.net/11452/24087
Title: 1st and 2nd law characteristics in a micropipe: Integrated effects of surface roughness, heat flux and reynolds number
Authors: Uludağ Üniversitesi/Mühendislik Fakültesi/Makine Mühendisliği Bölümü.
0000-0002-4976-9027
Özalp, A. Alper
ABI-6888-2020
6506131689
Keywords: Laminar forced-convection
Entropy generation
Numerical-analysis
Pressure-drop
Flow
Microchannels
Wall
Friction
Simulation
Channels
Thermodynamics
Engineering
Mechanics
Entropy
Heat flux
Metal analysis
Navier Stokes equations
Surface properties
Surface roughness
Centerline
Computational studies
Distribution ratio
Energy equation
Entropy generation
Heat transfer rate
Integrated effects
Intermittency
Low Reynolds number
Lower limits
Mean temperature
Micropipe
Navier Stokes
Total entropy
Transitional flow
Variable fluid properties
Viscous dissipation rate
Reynolds number
Issue Date: 2009
Publisher: Taylor&Francis
Citation: Özalp, A. A. (2009). "1st and 2nd law characteristics in a micropipe: Integrated effects of surface roughness, heat flux and reynolds number". Heat Transfer Engineering, 30(12), 973-987.
Abstract: A computational study of the integrated effects of surface roughness, heat flux, and Reynolds number on the 1st and 2nd law characteristics of laminar-transitional flow in a micropipe is presented. Analyses are carried by solving the variable fluid property continuity, Navier-Stokes, and energy equations for the surface roughness, heat flux, and Reynolds number ranges of 1-50 m, 5-100 W/m2, and 1-2000, respectively. Computations put forward that surface roughness not only accelerates transition to lower Reynolds number but also augments heat transfer rates, such that the transitional Reynolds numbers and intermittency values are evaluated as 1650, 575, and 450 and 0.132, 0.117, and 0.136 for the surface roughness cases of 1, 20, and 50 m, respectively. Thermocritical Reynolds numbers are identified by determining the viscous dissipation rates, which characterize the heating/cooling behavior and the related Reynolds number range. Surface roughness comes out to have no role on entropy generation at low Reynolds numbers; moreover, entropy generation is found to be inversely proportional with mean temperature variation, where the trends become almost asymptotic at the lower limit of the investigated Reynolds number range. Being independent of surface roughness, heat flux, and Reynolds number, radial irreversibility distribution ratio is determined to be negligible at the pipe centerline, indicating that the frictional entropy is minor and the major portion of the total entropy generation is thermal based.
URI: https://doi.org/10.1080/01457630902837467
https://www.tandfonline.com/doi/full/10.1080/01457630902837467
http://hdl.handle.net/11452/24087
ISSN: 0145-7632
Appears in Collections:Scopus
Web of Science

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