A superposition approach to study slip-flow forced convection in straight microchannels of uniform but arbitrary cross-section

This work presents a superposition approach to investigate forced convection in microducts of arbitrary cross-section, subject to H1 and H2 boundary conditions, in the slip-flow regime with further complication of a temperature jump condition assumption. It is shown that applying an average slip vel...

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Vydáno v:	International journal of heat and mass transfer Ročník 51; číslo 15-16; s. 3753 - 3762
Hlavní autor:	Hooman, K.
Médium:	Journal Article
Jazyk:	angličtina
Vydáno:	Oxford Elsevier Ltd 15.07.2008 Elsevier
Témata:	Applied fluid mechanics Computational methods in fluid dynamics Exact sciences and technology Fluid dynamics Fluidics Fundamental areas of phenomenology (including applications) MEMS Microscale Physics Superposition Temperature jump Velocity slip MEMS Temperature jump Superposition Velocity slip Microscale Slip flow Forced convection Pipe flow Computational fluid dynamics Digital simulation Boundary conditions Microchannel Modelling Microstructure Superposition method Microfluidics Heat transfer
ISSN:	0017-9310, 1879-2189
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Abstract	This work presents a superposition approach to investigate forced convection in microducts of arbitrary cross-section, subject to H1 and H2 boundary conditions, in the slip-flow regime with further complication of a temperature jump condition assumption. It is shown that applying an average slip velocity and temperature jump definition, one can still use the no-slip/no-jump results with some minor modifications. Present results for slip-flow in microchannels of parallel plate, circular, and rectangular cross-sections are found to be in complete agreement with those in the literature. Application of this methodology to microchannels of triangular cross-section is also verified by comparing the present results with those obtained numerically by undertaking the commercially available software CFD-ACE.
AbstractList	This work presents a superposition approach to investigate forced convection in microducts of arbitrary cross-section, subject to H1 and H2 boundary conditions, in the slip-flow regime with further complication of a temperature jump condition assumption. It is shown that applying an average slip velocity and temperature jump definition, one can still use the no-slip/no-jump results with some minor modifications. Present results for slip-flow in microchannels of parallel plate, circular, and rectangular cross-sections are found to be in complete agreement with those in the literature. Application of this methodology to microchannels of triangular cross-section is also verified by comparing the present results with those obtained numerically by undertaking the commercially available software CFD-ACE.
Author	Hooman, K.
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Keywords	MEMS Temperature jump Superposition Velocity slip Microscale Slip flow Forced convection Pipe flow Computational fluid dynamics Digital simulation Boundary conditions Microchannel Modelling Microstructure Superposition method Microfluidics Heat transfer
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Snippet	This work presents a superposition approach to investigate forced convection in microducts of arbitrary cross-section, subject to H1 and H2 boundary...
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SubjectTerms	Applied fluid mechanics Computational methods in fluid dynamics Exact sciences and technology Fluid dynamics Fluidics Fundamental areas of phenomenology (including applications) MEMS Microscale Physics Superposition Temperature jump Velocity slip
Title	A superposition approach to study slip-flow forced convection in straight microchannels of uniform but arbitrary cross-section
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