Radial well aquifer benchmark (Water Module): Difference between revisions

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: <math>R</math>: distance of the considered stable water table edge to the well
: <math>R</math>: distance of the considered stable water table edge to the well
: <math>Q_0</math>: amount of water pumped out in m³ / day
: <math>Q_0</math>: amount of water pumped out in m³ / day
===Setup===
We use the following setup in our tests. The grid size used is 51 by 51, with a configurable cell size of <math>dx</math> in meters. There is one underground outlet, which pumps water away continuously with a default amount per second.
The outlet is placed on the cells x = 25 and y = 25 as an [[inlet]] with a negative inlet .
[[Inlet q (Water Overlay)|Inlet Q]] is set to <math>\frac{-Q_0}{3600*24}</math>


===References===
===References===

Revision as of 15:37, 16 December 2020

This testcase demonstrates a situation where a well is pumping up ground water. A characteristic ground water level curve will form over time.

Drainage freatic benchmark.gif

Formulas

Stationary lowering of the ground water table in a closed water transmissive layer can be described by the following formula [1]

where:

: stable water level at the considered stable water table edge
: water level between the considered stable water table edge and the well
: water level in the well
: transmissivity of the aquifer in m² / day
: distance to the well
: distance of the considered stable water table edge to the well
: amount of water pumped out in m³ / day

Setup

We use the following setup in our tests. The grid size used is 51 by 51, with a configurable cell size of in meters. There is one underground outlet, which pumps water away continuously with a default amount per second.

The outlet is placed on the cells x = 25 and y = 25 as an inlet with a negative inlet . Inlet Q is set to


References

  1. Verruijt, A. (1970). Theory of Groundwater Flow. Macmillan, London.