Archie's law: Difference between revisions

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Cementation exponent, m: Added some referenced values for cementation factors in carbonates
 
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{{Refimprove|date=April 2009}}
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An '''inviscid flow''' is the flow of an [[ideal fluid]] that is assumed to have no [[viscosity]]. In [[fluid dynamics]] there are problems that are easily solved by using the simplifying assumption of an inviscid flow.<ref>Clancy, L.J., ''Aerodynamics'', p.xviii</ref>
 
The flow of fluids with low values of [[viscosity]] agree closely with '''inviscid flow''' everywhere except close to the fluid boundary where the [[boundary layer]] plays a significant role.<ref>Kundu, P.K., Cohen, I.M., & Hu, H.H., ''Fluid Mechanics'', Chapter 10, sub-chapter 1</ref>
 
==Reynolds number==
The assumption of inviscid flow is generally valid where [[Viscosity|viscous]] forces are small in comparison to inertial forces. Such flow situations can be identified as flows with a [[Reynolds number]] much greater than one. The assumption that viscous forces are negligible can be used to simplify the [[Navier-Stokes equations|Navier-Stokes solution]] to the [[Euler equations (fluid dynamics)|Euler equations]].
 
The Euler equation governing inviscid flow is:
 
:<math>
\rho\left(
\frac{\partial}{\partial t}+{\bold u}\cdot\nabla
\right){\bold u}+\nabla p=0
</math>
 
which is admittedly [[Newton's second law]] applied on a flowing infinitesimal volume element. In the steady-state case, combined with the continuity equation of mass, this can be solved using [[potential flow]] theory.
 
==Problems with the inviscid-flow model==
While throughout much of a flow-field the effect of viscosity may be very small, a number of factors make the assumption of negligible viscosity invalid in many cases. Viscosity cannot be neglected near fluid boundaries because of the presence of a [[boundary layer]], which enhances the effect of even a small amount of [[viscosity]].  [[Turbulence]] is also observed in some high-Reynolds-number flows, and is a process through which energy is transferred to increasingly small scales of motion until it is dissipated by viscosity.{{cn|date=February 2013}}
 
==References==
* Clancy, L.J. (1975), ''Aerodynamics'', Pitman Publishing Limited, London.  ISBN 0-273-01120-0
* Kundu, P.K., Cohen, I.M., & Hu, H.H. (2004), ''Fluid Mechanics'', 3rd edition, Academic Press. ISBN 0-12-178253-0, ISBN 978-0-12-178253-5
 
===Notes===
{{reflist}}
 
==See also==
*[[Viscosity]]
*[[Fluid Dynamics]]
*[[Stokes Flow]], in which the viscous forces are much greater than inertial forces.
*[[Couette Flow]]
 
[[Category:Fluid dynamics]]
 
{{fluiddynamics-stub}}

Latest revision as of 11:21, 27 November 2014

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