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Turbulent contribution to heat loss in cavity receivers

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Logie, William; Abbasi, Ehsan; Hughes, Graham; Pye, John

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For the prediction of convective heat loss from solar concentrating receiver cavities a number of empirical correlations exist. Geometry and the inclination angle determine the degree to which natural convection can infiltrate the cavity and remove stably stratified hot air out through the aperture. This makes the task of defining characteristic lengths for such Nusselt correlations difficult, neither does their use offer insight as to how one might reduce heat loss through the use of baffles,...[Show more]

dc.contributor.authorLogie, William
dc.contributor.authorAbbasi, Ehsan
dc.contributor.authorHughes, Graham
dc.contributor.authorPye, John
dc.coverage.spatialAbu Dhabi, United Arab Emirates
dc.date.accessioned2020-12-20T20:58:23Z
dc.date.available2020-12-20T20:58:23Z
dc.date.createdOctober 11-14 2016
dc.identifier.isbn9780735415225
dc.identifier.urihttp://hdl.handle.net/1885/218577
dc.description.abstractFor the prediction of convective heat loss from solar concentrating receiver cavities a number of empirical correlations exist. Geometry and the inclination angle determine the degree to which natural convection can infiltrate the cavity and remove stably stratified hot air out through the aperture. This makes the task of defining characteristic lengths for such Nusselt correlations difficult, neither does their use offer insight as to how one might reduce heat loss through the use of baffles, air curtains or small aperture-to-cavity-area ratios. Computational Fluid Dynamics (CFD) can assist in the design of better cavity receivers as long as the rules upon which it rests are respected. This paper is an exploration of the need for turbulence modelling in cavity receivers using some common linear eddy viscosity closure schemes. Good agreement was obtained with the CFD software OpenFOAMO® 3.0.1 for a deep cavity aperture but it under-predicted a shallow cavity. The experiments used for validation were in the Grashof region Gr ≈ 106, well below the region for transition to turbulence between 108 < Gr < 109.
dc.format.mimetypeapplication/pdf
dc.language.isoen_AU
dc.publisherAmerican Institute of Physics (AIP)
dc.relation.ispartofseries22nd International Conference on Concentrating Solar Power and Chemical Energy Systems, SolarPACES 2016
dc.sourceAIP Conference Proceedings
dc.titleTurbulent contribution to heat loss in cavity receivers
dc.typeConference paper
local.description.notesImported from ARIES
local.description.refereedYes
dc.date.issued2017
local.identifier.absfor040499 - Geophysics not elsewhere classified
local.identifier.ariespublicationa383154xPUB7714
local.type.statusPublished Version
local.contributor.affiliationLogie, William, College of Engineering and Computer Science, ANU
local.contributor.affiliationAbbasi, Ehsan, College of Engineering and Computer Science, ANU
local.contributor.affiliationHughes, Graham, Imperial College London
local.contributor.affiliationPye, John, College of Engineering and Computer Science, ANU
local.identifier.doi10.1063/1.4984407
dc.date.updated2020-11-23T11:24:12Z
local.identifier.scopusID2-s2.0-85023601390
CollectionsANU Research Publications

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