Unsteady Free Convection from Elliptic Tubes at Large Grashof Numbers

Perera, Ranmal

January 2008

This study solves the problem of unsteady free convection from an inclined heated tube both numerically and analytically. The tube is taken to have an elliptic cross-section having a constant heat flux applied to its surface. The surrounding fluid is viscous and incompressible and infinite in extent. The Boussinesq approximation is used to describe the buoyancy force driving the flow. The underlying assumptions made in this work are that the flow remains laminar and two-dimensional for all time. This enables the Navier-Stokes and energy equations to be formulated in terms of the streamfunction, and vorticity. We assume that initially an impulsive heat flux is applied to the surface and that both the tube and surrounding fluid have the same initial temperature. The problem is solved subject to the no-slip and constant heat flux conditions on the surface together with quiescent far-field and initial conditions. An approximate analytical-numerical solution was derived for small times, t and large Grashof numbers, Gr. This was done by expanding the flow variables in a double series in terms of two small parameters and reduces to solving a set of differential equations. The first few terms were solved exactly while the higher-order terms were determined numerically. Flow characteristics presented include average surface temperature plots as well as surface vorticity and surface temperature distributions. The results demonstrate that the approximate analytical-numerical solution is in good agreement with the fully numerical solution for small t and large Gr.

Natural convection

Grashof number

Heat transfer

Thermal fluid

Navier-Stokes equations

Energy equations

Elliptic tube

Analytical

Double expansion

Computer algebra systems

Applied Mathematics

Unsteady Free Convection from Elliptic Tubes at Large Grashof Numbers

Perera, Ranmal

January 2008

This study solves the problem of unsteady free convection from an inclined heated tube both numerically and analytically. The tube is taken to have an elliptic cross-section having a constant heat flux applied to its surface. The surrounding fluid is viscous and incompressible and infinite in extent. The Boussinesq approximation is used to describe the buoyancy force driving the flow. The underlying assumptions made in this work are that the flow remains laminar and two-dimensional for all time. This enables the Navier-Stokes and energy equations to be formulated in terms of the streamfunction, and vorticity. We assume that initially an impulsive heat flux is applied to the surface and that both the tube and surrounding fluid have the same initial temperature. The problem is solved subject to the no-slip and constant heat flux conditions on the surface together with quiescent far-field and initial conditions. An approximate analytical-numerical solution was derived for small times, t and large Grashof numbers, Gr. This was done by expanding the flow variables in a double series in terms of two small parameters and reduces to solving a set of differential equations. The first few terms were solved exactly while the higher-order terms were determined numerically. Flow characteristics presented include average surface temperature plots as well as surface vorticity and surface temperature distributions. The results demonstrate that the approximate analytical-numerical solution is in good agreement with the fully numerical solution for small t and large Gr.

Natural convection

Grashof number

Heat transfer

Thermal fluid

Navier-Stokes equations

Energy equations

Elliptic tube

Analytical

Double expansion

Computer algebra systems

Applied Mathematics

CFD Investigation of Heat Exchangers with Circular and Elliptic Cross-Sectional Channels

Aliev, Ruslan

January 2015

No description available.

Automotive Engineering

Mechanical Engineering

Nuclear Engineering

Petroleum Engineering

Aerospace Engineering

CFD analysis

circular and elliptic tube flow

heat exchanger

internal fluid flow

heat transfer

internal forced convection

figure of merit