Governing equations for transport phenomena
From Thermal-FluidsPedia
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*<b>[[Jump and boundary conditions at interfaces]]</b> | *<b>[[Jump and boundary conditions at interfaces]]</b> | ||
| - | :Conservation of [[Conservation of mass at interface|mass]], [[Conservation of momentum at interface|momentum]], [[Conservation of energy at interface|energy]], [[Conservation of mass species at interface|mass species]] | + | :Conservation of [[Conservation of mass at interface|mass]], [[Conservation of momentum at interface|momentum]], [[Conservation of energy at interface|energy]], and [[Conservation of mass species at interface|mass species]]. |
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| + | *'''[[Rarefied vapor self-diffusion model]]''' | ||
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| + | *'''[[An Extension: Combustion|Combustion]]''' | ||
*<b>[[Averaging formulation of governing equations|Averaging Formulation ]]</b> | *<b>[[Averaging formulation of governing equations|Averaging Formulation ]]</b> | ||
Revision as of 13:58, 28 June 2010
Transport phenomena, which represent transports of momentum, heat and mass, include fluid mechanics, heat and mass transfer. The discussions of governing equations in the links below can be applied to Fluid Mechanics, Heat and Mass Transfer, thermal-fluids aspects of Combustion, as well as Multiphase Systems.
- Transformation formula, continuity, momentum, energy, entropy, and conservation of mass species equations.
- Continuity, momentum, energy, entropy, and conservation of mass species equations.
- Conservation of mass, momentum, energy, and mass species.
Back to Heat and Mass Transfer.
Back to Multiphase Systems.
Back to Thermal-FluidsPedia Main Page.