Your search keyword '"H1 Boundary Condition"' showing total 2 results

1. Effect of Aspect Ratio on Convective Heat Transfer for Flat Cross Section Using Nanofluid.

Author

Faysal, Syed Rafat, Qudrat Ovi, Ifat Rabbil, and Sadrul Islam, A. K. M.

Subjects

*HEAT convection, *HEAT transfer, *BUOYANT convection, *COMPUTER simulation, *NUSSELT number

Abstract

For a typical cooling application, enhancement of convective heat transfer greatly depends on tube cross sections. This phenomena was studied by performing numerical simulations on different cross sections for laminar flow with Nanofluids, containing different volume fractions (1%, 2%&3%) of Aluminum oxide water. Constant axial heat flux with constant peripheral wall temperature i.e. H1 boundary condition was applied and results were validated with existing cross sections. After accomplishing CFD analysis on several cross sections, convective heat transfer coefficient was found highest in case of flat cross section and then the effect of aspect ratio on Nusselt number was investigated. Result shows that Nusselt number increases exponentially with aspect ratio and after reaching a certain aspect ratio, and beyond that Nusselt number becomes constant. [ABSTRACT FROM AUTHOR]

Published

2017

2. Heat transfer characterization of rhombic microchannel for H1 and H2 boundary conditions.

Author

Saha, Sandip K., Agrawal, Amit, and Soni, Yogesh

Subjects

*HEAT transfer, *MICROCHANNEL flow, *HEAT flux, *BOUNDARY value problems, *COMPUTER simulation

Abstract

In this paper, the characterization of laminar convective heat transfer in rhombic shaped microchannel with H1 (axially constant heat flux and circumferentially constant temperature) and H2 (constant axial and circumferential wall heat flux) boundary conditions is presented. A three-dimensional numerical model is developed for hydrodynamically and thermally developing flow in different rhombic geometries with side-angles varying from 10° to 90°. The numerical model is first validated with the other model developed in the literature for rectangular geometry and subsequently the results are compared with rhombic channel with different side-angles. This model is then extended to determine the temperature and heat flux distributions in rhombic microchannel, which is used to find the local and hydrodynamically and thermally fully developed Nusselt numbers. It is found that the fully developed Nusselt number varies only with the side-angles of rhombic channel and generalized correlations are developed as a function of side-angles for H1 and H2 boundary conditions. Correlations for developing length, local and fully-developed Nusselt numbers for rhombic channels are currently not available. These results will be useful in design and optimization of rhombic microchannel for electronic cooling applications. [ABSTRACT FROM AUTHOR]

Published

2017