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Free convection and conduction heat transfer
Posted 01.11.2009, 17:03 GMT-5 2 Replies
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Hi,
I am trying to build a model to simulate the heat transfer in a vertical pipe filled with liquid helium. Heat transfer will be due to two mechanisms, namely thermal conduction and free convection.
I have built a model with COMSOL Multiphysics 3.5a (Fluid Thermal Interaction -> Fluid-Thermal Incompressible Flow -> Steady State Analysis). I have attached the mph file.
My model consists of two subdomains, both of which represent the liquid helium volume. The two subdomains share a common boundary. One of the two subdomains has a constant heat dissipation per unit volume. The other subdomain has a boundary with a constant temperature. I expect the heat generated in the first subdomain to be conducted to the fixed-temperature boundary. What I am interested in is the temperature distribution in the two subdomains.
All is well if free convection is neglected, and only conduction is taken into account. The results make sense.
Heat transfer should be much better if free convection is included, however. I did that by applying a force of g*rho_He (T) (where g is the gravitational acceleration, and rho_He(T) the density of liquid helium as a function of temperature) to each volume unit of the helium subdomains. In addition, I defined the heat capacity of liquid helium (cp_He(T)).
The velocity field calculated with the Navier-Stokes equations (u and v) should then be used in the convection & conduction calculations, but it seems to be not, and I don't know why, at least the temperature profile is completely unaffected by changing g from 9.81 to -9.81 and 0. I did enter u and v as the x and y component of the fluid velocity in the convection & conduction subdomain setting window.
What puzzles me is that when I do the postprocessing, fairly high velocities are yielded (which is expected), but those values do not seem to be used in the convection calculations. If I enter much lower values manually (constant values instead of u and v in the subdomain setting window), the calculation works, i.e. convection occurs (or at least there is a very distinct influence on the temperature distribution in the subdomain).
Does anybody know what's wrong? Maybe I am making a very obvious mistake?
Best Regards,
Patrick
I am trying to build a model to simulate the heat transfer in a vertical pipe filled with liquid helium. Heat transfer will be due to two mechanisms, namely thermal conduction and free convection.
I have built a model with COMSOL Multiphysics 3.5a (Fluid Thermal Interaction -> Fluid-Thermal Incompressible Flow -> Steady State Analysis). I have attached the mph file.
My model consists of two subdomains, both of which represent the liquid helium volume. The two subdomains share a common boundary. One of the two subdomains has a constant heat dissipation per unit volume. The other subdomain has a boundary with a constant temperature. I expect the heat generated in the first subdomain to be conducted to the fixed-temperature boundary. What I am interested in is the temperature distribution in the two subdomains.
All is well if free convection is neglected, and only conduction is taken into account. The results make sense.
Heat transfer should be much better if free convection is included, however. I did that by applying a force of g*rho_He (T) (where g is the gravitational acceleration, and rho_He(T) the density of liquid helium as a function of temperature) to each volume unit of the helium subdomains. In addition, I defined the heat capacity of liquid helium (cp_He(T)).
The velocity field calculated with the Navier-Stokes equations (u and v) should then be used in the convection & conduction calculations, but it seems to be not, and I don't know why, at least the temperature profile is completely unaffected by changing g from 9.81 to -9.81 and 0. I did enter u and v as the x and y component of the fluid velocity in the convection & conduction subdomain setting window.
What puzzles me is that when I do the postprocessing, fairly high velocities are yielded (which is expected), but those values do not seem to be used in the convection calculations. If I enter much lower values manually (constant values instead of u and v in the subdomain setting window), the calculation works, i.e. convection occurs (or at least there is a very distinct influence on the temperature distribution in the subdomain).
Does anybody know what's wrong? Maybe I am making a very obvious mistake?
Best Regards,
Patrick
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2 Replies Last Post 02.11.2009, 12:32 GMT-5