Nanofluid effect in the vertical pipe with heat input concerning flat plate solar collector: an analytical analysis
By: Panda, Rama Chandra.
Contributor(s): Panigrahi, Lipika.
Publisher: Prayagraj Pushpa Publishing House 2022Edition: Vol.28, Aug.Description: 71-84p.Subject(s): Mechanical EngineeringOnline resources: Click here In: JP journal of heat and mass transferSummary: Heat transfer analysis in nanofluid-based flat plate solar collectors has been investigated and presented in this work. Cu-H2O nanofluid in absorber tubes of the collector has been considered in the present analytical study. Natural convection flow in the pipe is studied as free convective flow through a vertical cylinder filled with Cu-H2O nanofluid. The governing nondimensional ODEs along with their appropriate boundary conditions are solved analytically. The impacts of numerous physical parameters like heat, Grashof number and volume of fraction concerning nanofluid are analyzed. The range of heat parameters is considered 1 to 3, while the Grashof number has been varied from 10-20 and the nanofluid volume fraction is varied from 1% to 3% in the parametric study. From the present study, it is observed that heat transfer enhancement occurs with an increase in the parameters mentioned.Item type | Current location | Call number | Status | Date due | Barcode | Item holds |
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Articles Abstract Database | School of Engineering & Technology Archieval Section | Not for loan | 2023-0462 |
Heat transfer analysis in nanofluid-based flat plate solar collectors has been investigated and presented in this work. Cu-H2O nanofluid in absorber tubes of the collector has been considered in the present analytical study. Natural convection flow in the pipe is studied as free convective flow through a vertical cylinder filled with Cu-H2O nanofluid. The governing nondimensional ODEs along with their appropriate boundary conditions are solved analytically. The impacts of numerous physical parameters like heat, Grashof number and volume of fraction concerning nanofluid are analyzed. The range of heat parameters is considered 1 to 3, while the Grashof number has been varied from 10-20 and the nanofluid volume fraction is varied from 1% to 3% in the parametric study. From the present study, it is observed that heat transfer enhancement occurs with an increase in the parameters mentioned.
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