Abstract:
With natural convective heat transfer from horizontal
elements of relatively complex shape that have a uniform
surface temperature it has been found that if a length scale
based on the ratio of the element surface area to its perimeter is
used in defining the Nusselt and Rayleigh numbers then, for a
given Prandtl number, the variation of Nusselt number with
Raleigh number is effectively the same for all element shapes.
However, in a number of practical situations the element
surface is not isothermal but there is effectively a uniform heat
flux over the surface. Few studies have been undertaken to
determine whether natural convective heat transfer rates from
horizontal heated elements having a uniform surface heat flux
and relatively complex shapes can be correlated using the same
procedure that applies when there is an isothermal surface. A
fuller investigation of whether the results for surfaces with a
uniform heat flux can be correlated in this way has been
undertaken. Attention has been given to an element having a
circular shape with an inner circular adiabatic section, to an Ishaped
element, and to a plus (+)-shaped element. Results for a
square and a circular element are also presented for comparison
purposes. The elements considered are imbedded in a larger
surrounding flat adiabatic surface, attention being restricted to
the case where the heated elements are facing upwards. The
heat transfer from the element has been assumed to be to air.
The results have been obtained numerically using the
commercial CFD code ANSYS FLUENT©. The possibility that
turbulent flow can occur in the system has been allowed for by
using the basic k-epsilon turbulence model. The results have
been used to investigate whether the heat transfer rates in the
laminar, transitional and turbulent flow regions for the element
shapes considered here can be correlated for each of the
separate flow regions by using the same length scale that has
been found to apply for elements with a uniform surface
temperature.
Description:
Papers presented to the 12th International Conference on Heat Transfer, Fluid Mechanics and Thermodynamics, Costa de Sol, Spain on 11-13 July 2016.