Forchheimer flow to a well-considering time-dependent critical radius
Previous studies on the non-Darcian flow into a pumping well assumed that critical radius (<i>R</i><sub>CD</sub>) was a constant or infinity, where <i>R</i><sub>CD</sub> represents the location of the interface between the non-Darcian flow region and D...
| Main Authors: | , , |
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| Format: | Article |
| Language: | English |
| Published: |
Copernicus Publications
2014-06-01
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| Series: | Hydrology and Earth System Sciences |
| Online Access: | http://www.hydrol-earth-syst-sci.net/18/2437/2014/hess-18-2437-2014.pdf |
| Summary: | Previous studies on the non-Darcian flow into a pumping well assumed that
critical radius (<i>R</i><sub>CD</sub>) was a constant or infinity, where <i>R</i><sub>CD</sub>
represents the location of the interface between the non-Darcian flow region
and Darcian flow region. In this study, a two-region model considering
time-dependent <i>R</i><sub>CD</sub> was established, where the non-Darcian flow was
described by the Forchheimer equation. A new iteration method was proposed
to estimate <i>R</i><sub>CD</sub> based on the finite-difference method. The results
showed that <i>R</i><sub>CD</sub> increased with time until reaching the quasi steady-state flow, and the asymptotic value of <i>R</i><sub>CD</sub> only depended on the
critical specific discharge beyond which flow became non-Darcian. A larger
inertial force would reduce the change rate of <i>R</i><sub>CD</sub> with time, and
resulted in a smaller <i>R</i><sub>CD</sub> at a specific time during the transient flow.
The difference between the new solution and previous solutions were obvious
in the early pumping stage. The new solution agreed very well with the
solution of the previous two-region model with a constant <i>R</i><sub>CD</sub> under
quasi steady flow. It agreed with the solution of the fully Darcian flow
model in the Darcian flow region. |
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| ISSN: | 1027-5606 1607-7938 |