Abstract
When fluid flows through a pipe that is packed with sand particles, the fluid will bear the resistance from the sand-pack, as well as the viscous shear from the pipe wall. If the viscous shear from the pipe wall can be neglected, the fluid flow will obey Darcy’s law, and one can think the equivalent permeability of the packed-pipe equals the permeability of the sand-pack. However, if the viscous shear from the pipe wall cannot be neglected, the fluid flow will obey the Brinkman equation, and the permeability of the packed-pipe will be less than that of the sand-pack due to the additional viscous drag. In this work, on the basis of the Brinkman equation, we derived a series of analytical solutions for characterizing the fluid flow in packed-pipes. These solutions can be used to depict the velocity profiles, estimate the flux rate, and calculate the equivalent permeability of a packed-pipe. On the basis of these analytical solutions, we found that Poiseuille’s law is a special form of the derived equivalent permeability solution. We further divided the fluid flow in a packed-pipe into three regimes, including N-S flow, Brinkman flow, and Darcy flow. During the regime of Brinkman flow, the dimensionless flow velocity at the pipe center is 1, and the dimensionless flow velocity is gradually decreased to 0 at the pipe wall. We also investigated the effects of sorting, sand particle size, and sand-pack porosity on the packed-pipe permeability. The calculated results show that a more uniform size of the sand particles or a smaller mean particle diameter can lead to lower packed-pipe permeability. Compared to the sorting and mean particle diameter, the sand-pack porosity exerts a more significant effect on the packed-pipe permeability.
Highlights
Introduction e NavierStokes (N-S) equation describes fluid flow on the microlevel and it accounts for the effect of viscous shear on the fluid flow [1, 2]
One can find that the permeability ratio is increased as the Darcy parameter Da is increased
The authors derived a series of analytical solutions for characterizing the fluid flow through pipes that are packed with sand. ese solutions can be used to depict the velocity profiles in a packed-pipe (equation (15)), estimate the flux rate through a packed-pipe (equation (16)), and calculate the equivalent permeability of a packed-pipe (equation (17))
Summary
Stokes (N-S) equation describes fluid flow on the microlevel and it accounts for the effect of viscous shear on the fluid flow [1, 2]. On the basis of the reduced N-S equation, Hagenbach [3] derived an analytical solution for characterizing the flux rate in empty pipes (in this work, an empty pipe indicates a pipe that is filled only with fluid), which can be expressed as q β1β2πR4 Δp, (2). If we use equivalent permeability to characterize the ability of the empty pipes for transmitting the fluid, on the basis of Darcy’s law [4] we can have q β1πR2ke
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