Laminar natural convection within long vertical uniformly heated parallel-plate channels and circular tubes

Vorayos, Nat

27 June 2000

The problem of simple mathematical models of laminar natural convective flow within a long vertical parallel-plate channels and circular tubes kept at uniformly heated walls is revisited to seek a clear physical understanding of heat transfer mechanisms. A series solution method to analyze the fully developed flow and an integral solution method to analyze the developing flow are used. Chapters 3, 4, and 5 of this dissertation constitute a series of three-paper manuscripts for submission to archival journals. The channels and circular tubes considered here are assumed to be sufficiently long to yield a fully developed flow thermally as well as hydrodynamically before the exit is encountered. In such fully developed flow situation, the fluid mass flow rate naturally induced into the channel due to buoyancy is found to be a function of the wall heating condition. The predicted average Nusselt number as a function of GrPrD/L not only agrees with the existing literature but also is found to be in a functional form comparable to that proposed by Elenbaas (1942 a and b). Our results show that, in spite of being driven by buoyancy (rather than by a pump or a blower), the flow and heat transfer characteristics in the fully developed regime are essentially the same as those of fully developed laminar forced convection in which the flow is externally driven. This observation is confirmed to be valid also in the study (Chapter 5) of laminar natural convection in the developing (entrance) region within a long vertical parallel-plate channel and circular tube. The mass flow rate, which has to remain invariant with axial location even in the entry region, is determined by the flow in the fully developed region. This is the same mechanism involved in forced convection in which the fluid outside the developing boundary layers (i.e. the core flow) is forced to accelerate in the entrance region. The entrance length of channel natural convection is also discovered to be about the same as that in forced convection. / Graduation date: 2001

Natural convection cooling of vertical plates in an enclosure : a numerical simulation

Destremau, Axel

07 November 1991

Graduation date: 1992

Natural and mixed convection in a horizontal cylindrical annulus with and without fins on inner cylinder

Begum, Latifa.

January 2007

Determination of the heat transfer coefficients for natural and mixed convection in horizontal annuli is important for designing double pipe heat exchangers and for energy storage systems. In part one and two of this study, the 2D numerical solution of the laminar natural convection of water in six internally finned horizontal annuli has been obtained. The fins are attached to the external surface of the inner cylinder. Only the symmetrical half of the horizontal annulus with three equally spaced longitudinal divergent solid and porous fins are considered. The parameters of the problem are Rayleigh number, fin height, permeability and porosity of the porous fin, etc. The above parameters are suitably varied to ascertain their effects on fluid flow and heat transfer. The results show that traditional solid fins provide much higher heat transfer rates compared to the porous fins. Part three of this work deals with mixed convective heat transfer (laminar natural and forced convections) of water in a vented annulus. The forced flow conditions are imposed by providing an inlet at the top and an outlet at the bottom. For various parameters of the problem, the average and local Nusselt numbers along the inner cylinder are calculated for water for both aiding and opposing flows. The fourth part of this study deals with numerical modeling of natural convection of nanofluids in a horizontal cylindrical annulus. Simulations are carried out for Cu-water nanofluids. The results, in general, show that nanoparticles systematically decrease the natural convective heat transfer coefficient on the inner cylinder. Practical and useful correlations are provided for calculating average heat transfer rates from the inner cylinder in the form of average equivalent thermal conductivity and average Nusselt number for all of the four cases discussed above. These correlations are new and will be helpful in designing heat exchangers.

Heat -- Convection.

Energy storage.

Modeling the impact of a liquid droplet on a solid surface

Healy, William M.

05 1900

No description available.

Heat Transmission

Liquid films

Fluid dynamics Mathematical models

Heat Convection

Onset of flow instability and critical heat flux in horizontal, thin, uniformly-heated annuli

Stoddard, Ryan Manse

05 1900

No description available.

Heat Convection

Heat Transmission

Unsteady flow (Fluid dynamics)

Steady thermocapillary flow between a non-wetting liquid droplet and a solid surface

Wood, Andrea Marie

12 1900

No description available.

Fluid dynamics

Heat Convection

Lubrication and lubricants

Reduced gravity environments

Theoretical modeling of onset of ledinegg flow instability in a heated channel

Rhodes, Matthew D.

05 1900

No description available.

Liquids Cooling

Heat Convection

Heat Transmission

Fluids Thermal properties

Thermocapillary migration of a three-dimensional liquid droplet on a solid surface

Benintendi, Steven William

05 1900

No description available.

Heat Transmission

Liquid films

Heat Convection

Fluid dynamics

Local convective heat transfer from heated flat plates using synthetic air jets

Gillespie, Mark B.

08 1900

No description available.

Heat Convection

Electronic packaging Coding

Jets Fluid dynamics

A spectral model of bubble convection.

Daley, Roger Willis

January 1971

No description available.

Bubbles

Spectral theory (Mathematics)

Fluid dynamics