Principles of single-phase flow through porous media
- Univ. of Alberta, Edmonton (Canada)
Porous media are both permeable and dispersive to a traversing fluid. Flow of a single-phasefluid in porous media is not only of practical interest but also of fundamental significance in characterizing the porous media. In this chapter, the characteristics of porous media are introduced from both fundamental and application points of view. A continuum approach is used. The volume-averaged equations are used to describe the flow, where the momentum dispersion has been neglected. The relations between Darcy`s law-Brinkinans equation and the volume-averaged Navier-Stokes equation are described. The Forchheimer hypothesis, Ergun equation, and Liu-Afacan-Alashyah equation are briefly described in terms of coupling of the viscous and inertial effects oil the single-phaseflow in porous media. Discussions are provided on the concept and modeling of areal porosity, tortuosity, permeability, and shear factor. A curved passage model is discussed in terms of the shear factor and pressure-drop modeling for flow through porous media. Bounding wall effects are discussed through a simple approach. Examples of flow simulations in porous media (i.e., slightly compressible flow in oil reservoirs and incompressible flow infixed beds) are provided. 110 refs., 22 figs., 4 tabs.
- Sponsoring Organization:
- USDOE
- OSTI ID:
- 472139
- Journal Information:
- Advances in Chemistry Series, Journal Name: Advances in Chemistry Series Journal Issue: 251; ISSN 0065-2393; ISSN ADCSAJ
- Country of Publication:
- United States
- Language:
- English
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