# Governing equations for transport phenomena

(Difference between revisions)
Jump to: navigation, search
 Revision as of 02:56, 25 January 2010 (view source)← Older edit Current revision as of 14:01, 5 August 2010 (view source) (→References) (11 intermediate revisions not shown) Line 1: Line 1: 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]].
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]].
- *[[Basics of governing equations|Basics]] *[[Basics of governing equations|Basics]] - :[[Lagrangian approach]] and [[Eulerian approach]]. *[[Integral formulation of governing equations|Integral Formulation]] *[[Integral formulation of governing equations|Integral Formulation]] :[[Transformation formula]], [[Integral continuity equation|continuity]], [[Integral momentum equation|momentum]], [[Integral energy equation|energy]], [[Integral entropy equation|entropy]], and [[Integral conservation of mass species equation|conservation of mass species]] equations. :[[Transformation formula]], [[Integral continuity equation|continuity]], [[Integral momentum equation|momentum]], [[Integral energy equation|energy]], [[Integral entropy equation|entropy]], and [[Integral conservation of mass species equation|conservation of mass species]] equations. Line 9: Line 7: *[[Differential formulation of governing equations|Differential Formulation]] *[[Differential formulation of governing equations|Differential Formulation]] :[[Continuity equation|Continuity]], [[Momentum equation|momentum]], [[Energy equation|energy]], [[Entropy equation|entropy]], and [[Conservation of mass species equation|conservation of mass species]] equations. :[[Continuity equation|Continuity]], [[Momentum equation|momentum]], [[Energy equation|energy]], [[Entropy equation|entropy]], and [[Conservation of mass species equation|conservation of mass species]] equations. + *[[Classifications of PDE and boundary conditions]] *[[Classifications of PDE and boundary conditions]] - :[[Elliptic, parabolic and hyperbolic equations|Elliptic, parabolic and hyperbolic PDEs]] and [[classification of boundary conditions]]. + + :[[Classification of PDEs]] and [[classification of boundary conditions|boundary conditions]]. *[[Jump and boundary conditions at interfaces]] *[[Jump and boundary conditions at interfaces]] - :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]], [[Supplementary conditions at interfaces|supplementary conditions]] and [[An Extension: Combustion|Combustion]]. + :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]]. - *[[Averaging formulation of governing equations|Averaging Formulation ]] + *'''[[Rarefied vapor self-diffusion model]]''' - :[[Overview of averaging|Overview]], [[Volume averaging|volume averaging]], [[Area averaging|area averaging]], and [[Boltzmann statistical averaging|Boltzmann statistical averaging]]. + + *'''[[Transport phenomena in combustion|Combustion]]''' + + *[[Averaging formulation of governing equations|Averaging Formulation]] + :[[Averaging approaches]], [[multi-fluid model]], [[homogeneous model]], [[Governing Equations for Porous Media|porous media]], and [[Boltzmann statistical averaging]]. + + *[[Fundamentals of turbulence]] + :[[ Description of turbulence]], and [[time-averaged governing equations for turbulence]]. *[[Related topics in governing equations|Related Topics]] *[[Related topics in governing equations|Related Topics]] Line 24: Line 31: Back to [[Multiphase Systems]].
Back to [[Multiphase Systems]].
Back to [[Main Page|'''T'''hermal-'''F'''luids'''P'''edia Main Page]]. Back to [[Main Page|'''T'''hermal-'''F'''luids'''P'''edia Main Page]]. + + ==References== + + Faghri, A., Zhang, Y., and Howell, J. R., 2010, ''Advanced Heat and Mass Transfer'', Global Digital Press, Columbia, MO. + + Faghri, A., and Zhang, Y., 2006, Transport Phenomena in Multiphase Systems, Elsevier, Burlington, MA. + + ==Further Reading== + + ==External Links==

## Current revision as of 14:01, 5 August 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.
Classification of PDEs and boundary conditions.
Conservation of mass, momentum, energy, and mass species.
Averaging approaches, multi-fluid model, homogeneous model, porous media, and Boltzmann statistical averaging.
Description of turbulence, and time-averaged governing equations for turbulence.

Back to Heat and Mass Transfer.
Back to Multiphase Systems.
Back to Thermal-FluidsPedia Main Page.

## References

Faghri, A., Zhang, Y., and Howell, J. R., 2010, Advanced Heat and Mass Transfer, Global Digital Press, Columbia, MO.

Faghri, A., and Zhang, Y., 2006, Transport Phenomena in Multiphase Systems, Elsevier, Burlington, MA.