Solution of the Graetz-Nusselt problem for liquid flow over isothermal parallel ridges
Solution of the Graetz-Nusselt problem for liquid flow over isothermal parallel ridges
We consider convective heat transfer for laminar flow of liquid between parallel plates that are textured with isothermal ridges oriented parallel to the flow. Three different flow configurations are analyzed: one plate textured and the other one smooth; both plates textured and the ridges aligned; and both plates textured, but the ridges staggered by half a pitch. The liquid is assumed to be in the Cassie state on the textured surface(s), to which a mixed boundary condition of no-slip on the ridges and no-shear along flat menisci applies. Heat is exchanged with the liquid either through the ridges of one plate with the other plate adiabatic, or through the ridges of both plates. The thermal energy equation is subjected to a mixed isothermal-ridge and adiabatic-meniscus boundary condition on the textured surface(s). Axial conduction is neglected and the inlet temperature profile is arbitrary. We solve for the three-dimensional developing temperature profile assuming a hydrodynamically developed flow, i.e., we consider the Graetz-Nusselt problem. Using the method of separation of variables, the thermal problem is essentially reduced to a two-dimensional eigenvalue problem in the transverse coordinates, which is solved numerically. Expressions for the local Nusselt number and those averaged over the period of the ridges in the developing and fully developed regions are provided. Nusselt numbers averaged over the period and length of the domain are also provided. Our approach enables the aforementioned quantities to be computed in a small fraction of the time required by a general computational fluid dynamics (CFD) solver.
Graetz-Nusselt problem, Nusselt number, Superhydrophobic surfaces, Textured surfaces
Karamanis, Georgios
31be80ad-86e2-4bcc-b706-f6dfcab338a5
Hodes, Marc
31732b12-8b18-4b0e-9bc8-6dc690229ae9
Kirk, Toby
7bad334e-c216-4f4a-b6b3-cca90324b37c
Papageorgiou, Demetrios T.
deb25b82-b6bf-4f0d-afd0-3dfba527b23a
Karamanis, Georgios
31be80ad-86e2-4bcc-b706-f6dfcab338a5
Hodes, Marc
31732b12-8b18-4b0e-9bc8-6dc690229ae9
Kirk, Toby
7bad334e-c216-4f4a-b6b3-cca90324b37c
Papageorgiou, Demetrios T.
deb25b82-b6bf-4f0d-afd0-3dfba527b23a
Karamanis, Georgios, Hodes, Marc, Kirk, Toby and Papageorgiou, Demetrios T.
(2017)
Solution of the Graetz-Nusselt problem for liquid flow over isothermal parallel ridges.
Journal of Heat Transfer, 139 (9), [091702].
(doi:10.1115/1.4036281).
Abstract
We consider convective heat transfer for laminar flow of liquid between parallel plates that are textured with isothermal ridges oriented parallel to the flow. Three different flow configurations are analyzed: one plate textured and the other one smooth; both plates textured and the ridges aligned; and both plates textured, but the ridges staggered by half a pitch. The liquid is assumed to be in the Cassie state on the textured surface(s), to which a mixed boundary condition of no-slip on the ridges and no-shear along flat menisci applies. Heat is exchanged with the liquid either through the ridges of one plate with the other plate adiabatic, or through the ridges of both plates. The thermal energy equation is subjected to a mixed isothermal-ridge and adiabatic-meniscus boundary condition on the textured surface(s). Axial conduction is neglected and the inlet temperature profile is arbitrary. We solve for the three-dimensional developing temperature profile assuming a hydrodynamically developed flow, i.e., we consider the Graetz-Nusselt problem. Using the method of separation of variables, the thermal problem is essentially reduced to a two-dimensional eigenvalue problem in the transverse coordinates, which is solved numerically. Expressions for the local Nusselt number and those averaged over the period of the ridges in the developing and fully developed regions are provided. Nusselt numbers averaged over the period and length of the domain are also provided. Our approach enables the aforementioned quantities to be computed in a small fraction of the time required by a general computational fluid dynamics (CFD) solver.
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e-pub ahead of print date: 2 May 2017
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Copyright © 2017 by ASME.
Keywords:
Graetz-Nusselt problem, Nusselt number, Superhydrophobic surfaces, Textured surfaces
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Local EPrints ID: 495676
URI: http://eprints.soton.ac.uk/id/eprint/495676
ISSN: 0022-1481
PURE UUID: c1ef587f-8397-48fa-b491-9abb0166183b
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Date deposited: 20 Nov 2024 17:43
Last modified: 28 Nov 2024 03:10
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Contributors
Author:
Georgios Karamanis
Author:
Marc Hodes
Author:
Toby Kirk
Author:
Demetrios T. Papageorgiou
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