Heat transfer: Difference between revisions
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A heat transfer is basically an energy transfer that can produce work or a change of temperature difference between the interacting parts. It can take three forms: conductive, convective and radiative. In the case of a heat transfer due to the atmosphere around an aircraft, the three mechanisms are effective. This page currently focuses on convective heat transfer, which implies conductive heat transfer. Radiative transfer is probably negligible before the two others in our particular case study. | A heat transfer is basically an energy transfer that can produce work or a change of temperature difference between the interacting parts. It can take three forms: conductive, convective and radiative. In the case of a heat transfer due to the atmosphere around an aircraft, the three mechanisms are effective. This page currently focuses on convective heat transfer, which implies conductive heat transfer. Radiative transfer is probably negligible before the two others in our particular case study. | ||
==Introduction to heat convection== | ==Introduction to heat convection and conduction== | ||
Heat convection occurs when there is a fluid flowing around a control volume at a temperature different than the control volume's. The flow can be either ''natural'', when the fluid is flowing due to density gradients (buoyancy force), or ''forced'', when the fluid is flowing because an external process force it to flow or make the control volume move through the fluid. | Heat '''convection''' occurs when there is a fluid flowing around a control volume at a temperature different than the control volume's. The flow can be either ''natural'', when the fluid is flowing due to density gradients (buoyancy force), or ''forced'', when the fluid is flowing because an external process force it to flow or make the control volume move through the fluid. | ||
When air is the considered fluid, convection is always associated to '''conduction''' heat transfer. The reason is that a film is formed on the surface of the object, called the [https://en.wikipedia.org/wiki/Boundary_layer boundary layer], and it is partly steady and at a temperature closer than the temperature of the object than the temperature of the fluid. In that case, conduction applies. | |||
An insulation layer's effect can be easily calculated as its thermal [https://en.wikipedia.org/wiki/U-value#U-value transmittance] (U-value) or [https://en.wikipedia.org/wiki/R-value_(insulation) resistance] (R-value), the amount of heat that it allows to be transferred through it. This is directly obtained from the material's [https://en.wikipedia.org/wiki/Thermal_conductivity thermal conductivity] ''k'' (unit: W/m.K) and the thickness of the insulation ''L''. ''R = L/k'' and ''U = k/L''. Unit of U is W/m^2.K. The transmitter heat is then Φ = A × U × (T1 - T2), in Watt (= Joule/s), where A is the external area of the insulation layer, T1 and T2 are the internal and external temperature. Examples for the transmittance of insulation layers can be found here [http://bmeweb.niu.edu.tw/pcwu/%E7%BF%92%E9%A1%8C%E8%A7%A3%E7%AD%94/Heat%20Chap01-087.doc], | |||
===Heat transfer coefficient ''h''=== | |||
The rate of heat loss of a body by convection is proportional to the difference in temperatures between the body and its surroundings, as stated by [https://en.wikipedia.org/wiki/Convective_heat_transfer#Newton.27s_law_of_cooling Newton's law of cooling]: {{SERVER}}/images/formulas_mirror/newtons_law_of_cooling_neg.png , where ''h'' is the [https://en.wikipedia.org/wiki/Heat_transfer_coefficient heat transfer coefficient]. This ''h'' depends on many parameters (flow rate, surface roughness, fluid properties, and others) and is very hard to calculate accurately. Approximations exist for some conditions and determining them is still an active research topic for some conditions. It will be our main problem in the case of air to aircraft heat transfer. | |||
===The Nusselt number ''Nu''=== | |||
===The Reynolds number ''Re''=== | |||
===The Prandtl number ''Pr''=== | |||
==Cases of application== | |||
===Natural convection for horizontal cryogenic tank=== | |||
===Forced convection on aircraft fuselage during flight=== | |||
==References== | ==References== | ||
'''Textbook Of Heat Transfer''' (4th Edition), S.P. Sukhatme, 2006. [http://books.google.com/books?id=-VgAZm6KWrwC Google books] |
Revision as of 22:40, 20 November 2012
Heat transfer is a very complicated process involving many parameters and conditions. This page plays the role of introduction to heat transfer and a documentation on the methods used to calculate the heat transfers applied to our vehicle.
Heat transfers
A heat transfer is basically an energy transfer that can produce work or a change of temperature difference between the interacting parts. It can take three forms: conductive, convective and radiative. In the case of a heat transfer due to the atmosphere around an aircraft, the three mechanisms are effective. This page currently focuses on convective heat transfer, which implies conductive heat transfer. Radiative transfer is probably negligible before the two others in our particular case study.
Introduction to heat convection and conduction
Heat convection occurs when there is a fluid flowing around a control volume at a temperature different than the control volume's. The flow can be either natural, when the fluid is flowing due to density gradients (buoyancy force), or forced, when the fluid is flowing because an external process force it to flow or make the control volume move through the fluid.
When air is the considered fluid, convection is always associated to conduction heat transfer. The reason is that a film is formed on the surface of the object, called the boundary layer, and it is partly steady and at a temperature closer than the temperature of the object than the temperature of the fluid. In that case, conduction applies.
An insulation layer's effect can be easily calculated as its thermal transmittance (U-value) or resistance (R-value), the amount of heat that it allows to be transferred through it. This is directly obtained from the material's thermal conductivity k (unit: W/m.K) and the thickness of the insulation L. R = L/k and U = k/L. Unit of U is W/m^2.K. The transmitter heat is then Φ = A × U × (T1 - T2), in Watt (= Joule/s), where A is the external area of the insulation layer, T1 and T2 are the internal and external temperature. Examples for the transmittance of insulation layers can be found here [1],
Heat transfer coefficient h
The rate of heat loss of a body by convection is proportional to the difference in temperatures between the body and its surroundings, as stated by Newton's law of cooling: , where h is the heat transfer coefficient. This h depends on many parameters (flow rate, surface roughness, fluid properties, and others) and is very hard to calculate accurately. Approximations exist for some conditions and determining them is still an active research topic for some conditions. It will be our main problem in the case of air to aircraft heat transfer.
The Nusselt number Nu
The Reynolds number Re
The Prandtl number Pr
Cases of application
Natural convection for horizontal cryogenic tank
Forced convection on aircraft fuselage during flight
References
Textbook Of Heat Transfer (4th Edition), S.P. Sukhatme, 2006. Google books