Waterway level change benchmark (Water Module): Difference between revisions

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: <math>S</math>: freatic water storage fraction.
: <math>S</math>: freatic water storage fraction.


[[File:graph_waterlevel_change_percentual_over_distance.png|frame|right| De grafiek laat de relatieve verandering zien van de grondwaterstand na 1, 4, 9, 16, 25, 36, 49, 64, 81, 100 en 121 dagen, berekend met bovenstaande formule.]]
[[File:graph_waterlevel_change_percentual_over_distance.png|frame|left| De grafiek laat de relatieve verandering zien van de grondwaterstand na 1, 4, 9, 16, 25, 36, 49, 64, 81, 100 en 121 dagen, berekend met bovenstaande formule.]]
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Revision as of 14:13, 11 December 2020

Initially, the ground water table is the same as the water level in the waterway. Suddenly the level in the waterway rises with h0 meters. This causes water to infiltrate into the ground, raising the ground water table.

Situation of the waterway level change benchmark for groundwater

Formulas

When the water level in the water way changes, the water table level will also change over time. The relation between water level in the waterway and the ground water table at distance x from the water way is described by the following formulas [1]: In case the water level is raised, the following formula should hold:

In case the water level is lowered, the following formula should hold:

The formula erf is the complementary error function.

where:

: change in freatic groundwater table (m)
: change in water level in the waterway(m)
: distance to the water way (m)
: time since the water level change
: transmissivity of the aquifer (m2 / day)
: freatic water storage fraction.
De grafiek laat de relatieve verandering zien van de grondwaterstand na 1, 4, 9, 16, 25, 36, 49, 64, 81, 100 en 121 dagen, berekend met bovenstaande formule.


Setup

The test setup uses the same parameters used in the research results published in [2] The grid chosen is 112 by 5. The ground water table comparisons will be conducted in the x-direction. The grid cell size is set to 25meters.


The terrain height is set up as followed:

0.0 for x <= 2
3.0 for x == 3
10.0 for x > 3

The initial water level is set to 2, for both surface and the groundwater table, by using a water level area set to 2 meters.

The water will be raised to 4 meters, thereby simulating an of 2.

One inlet is placed on the cells x = 1 and y = 1 to 3, with the following setup to create the sudden stable water level increment:

UPPER_THRESHOLD set to 4.
LOWER_THRESHOLD set to 4.
Inlet Q set to 0, such that is unlimited.

This ensures that the water level is instantly raised to level 4 and that it remains at 4 at all times.

The ground is setup with: Water storage fraction set to 0.25.

An aquifer is added for the region as well, initialized with the Aquifer KD set to 700 m2/day.

For the test different simulation times T are tested, each resulting in a different relation graph as shown in the described case above.

A ground water overlay is used for the simulation, with a simulation time T configured using the Weather's rain M parameter, set to [T, 0.0], resulting in a simulation of T seconds without rain. Note that T has to be converted to days to be used in the formula's described above.

Results

References

  1. Marsily, Ghislain de, 1986. Quantitative Hydrogeology. Groundwater Hydrology for Engineers. Academic Press (originally in french, p199 for the formula)
  2. Ernst, L.F. 1958. Verhoging van grondwaterstanden en vermindering van afvoer door opstuwing van beken. Overdruk uit Verslagen Technische Bijeenkomsten 11-12. Versl. Meded. Comm. Hydrol. Onderz. T.N.O. No. 3 (1958).