An Investigation of the Different Temperature Changes in Carbon Nanotube Having Boundary Conditions into Steady Heat Flow Rate
Subject Areas : Thermodynamics and Heat Transter
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Keywords: Matrix phase, Nanocomposite plate, Nanotube, Temperature.,
Abstract :
The carbon nanotubes are applied for boosting polymers, because the carbon nanotubes are so stronger than ordinary polymers, and have the greatest dimensions than the ordinary carbon fibers. Since carbon nanotubes have high irregular thermal conductivity, this issue is very important from the technological aspect of energy management. In these fluids or organic polymers combined with carbon nanotubes, matrix-nanotube connective is of specific importance. The results show that when one of the edges of the plate has a temperature boundary condition, the increment speed of the minimum temperature increases over time, and it requires 200 seconds for the heat to be conducted across the length of the plate. Also, in case two non-adjacent edges are of constant temperature boundary condition, the temperature of the region increases and grows on two sides of the plate symmetrically. The applied support in the plate can also be a compound of some types of simple and trapped supports.
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