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Buoyancy induced heat transfer and fluid flow inside a tilted wavy solar collector [An article from: Building and Environment]
Book Details
Author(s)Y. Varol, H.F. Oztop
PublisherElsevier
ISBN / ASINB000PDSAX6
ISBN-13978B000PDSAX2
AvailabilityAvailable for download now
MarketplaceUnited States 🇺🇸
Description
This digital document is a journal article from Building and Environment, published by Elsevier in 2007. The article is delivered in HTML format and is available in your Amazon.com Media Library immediately after purchase. You can view it with any web browser.
Description:
Natural convection heat transfer and fluid flow were investigated inside a wavy walled and inclined solar collector, numerically. Flat ceiling was considered as cover (cold temperature) of solar collector and wavy wall as absorber (hot temperature). CFDRC commercial code was used to solve laminar-governing equations of natural convection. Working fluid was considered as air with Pr=0.71 inside the collector. Parameters that affect the flow and temperature field are Rayleigh number, inclination angle, aspect ratio, and wavelength. Flow and temperature fields were presented by streamlines and isotherms. Local and mean Nusselt numbers were calculated. Results indicate that heat transfer is increased with increasing Rayleigh number and aspect ratio, and is decreased with increasing wavelength.
Description:
Natural convection heat transfer and fluid flow were investigated inside a wavy walled and inclined solar collector, numerically. Flat ceiling was considered as cover (cold temperature) of solar collector and wavy wall as absorber (hot temperature). CFDRC commercial code was used to solve laminar-governing equations of natural convection. Working fluid was considered as air with Pr=0.71 inside the collector. Parameters that affect the flow and temperature field are Rayleigh number, inclination angle, aspect ratio, and wavelength. Flow and temperature fields were presented by streamlines and isotherms. Local and mean Nusselt numbers were calculated. Results indicate that heat transfer is increased with increasing Rayleigh number and aspect ratio, and is decreased with increasing wavelength.
