To determine Conditions under which the analysis of temperature distribution in a flow field can be completely uncoupled and the conditions for laminar and turbulent flow. Explanation The following conditions are to be considered for which the temperature distribution can be uncoupled: When a fluid is within a folded layer with impermeable boundaries that permits for exact temperature distribution. When the layer has negligible or very small slopes. When there is a constant surface temperature. When the blow is accompanied by constant heat flux. For laminar flow: The temperature distribution is influenced by conduction, convection, and dissipation. In a flow driven by frictional forces, the influence of dissipation can be significant at low Reynold’s number. Since both, the convection term and shear distribution are determined by the velocity field and since transfer properties are constant, it is reasonable to first solve for temperature distribution. If the velocity distribution is known, the temperature distribution may be solved directly from energy equation: The properties of the fluid are no longer held constant. The kinematic viscosity, thermal conductivity, and density fluctuate within the disk system depending on the temperature of the fluid at that grid point. For turbulent flow: Since the velocity field depends on the rate of transfer of momentum to the surface, τ w , we may expect the temperature field to depend, analogously, on the rate of heat transfer from the surface of the flow, q w . We also expect the fluid properties k and c p to appear. Further, if the velocity field analysis is restricted to y δ < 0.2 , we expect that by analogy the temperature field analysis will be restricted to y δ t < 0.2 approximately, where δ t is the thickness of the temperature profile. If the surface is heated all the way from the origin of the boundary layer, all the turbulent fluid will be heated and − as long as the molecular Prandtl number is not orders of magnitude different from unity - δ t would be almost equal to δ if the analogous definitions of δ and δ t were used. We now have eight variables, y , τ w , ρ , μ , k , c p , q w a n d T w − T , with four dimensions, mass, length, time and temperature

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Publisher: McGraw-Hill Education

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Chapter 4, Problem 4.5WP

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Conditions under which the analysis of temperature distribution in a flow field can be completely uncoupled and the conditions for laminar and turbulent flow.

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