Ground model (Water Overlay): Difference between revisions

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===Drainage===
===Drainage===
[[Drainage (Water Overlay)|Drainages]] are hydraulic structures that provide connections between the ground and nearby waterways, draining groundwater to levels which are optimal for agriculture. Drainage can be:
[[Drainage (Water Overlay)|Drainages]] are hydraulic structures that provide connections between the ground and nearby waterways, draining groundwater to levels which are optimal for agriculture.
* [[Drainage (Water Overlay)#Passive Drainage|Passive Drainage]] lets water flow from the drainage pipes into the waterway.
 
* [[Drainage (Water Overlay)#Active Drainage Negative Q|Active Drainage with a negative Q]] can pump water from from the waterway (with a lower level) into the drainage pipes.
{{Drainage_variants_reference}}
* [[Drainage (Water Overlay)#Active Drainage Positive Q|Active Drainage with a positive Q]] can pump water from the drainage pipes up into a waterway (with a higher level).


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Latest revision as of 17:16, 11 December 2024

The Water Module also contains a simplified multi-layer ground model, for infiltration, evapotranspiration, bottom flow and horizontal flow in the ground layer. Additionally, the model also applies a simplified form of exfiltration of water from the soil back onto the surface layer.

Groundwater modes

For the Water Module there exist three modes for handling groundwater:

Multi Layered model

The assumption is made that ground is bound vertically by the surface of the terrain at the top and by an impenetrable layer at the bottom. The distance between the surface and the impenetrable layer, and thus the effective height of the ground, is equal to ground bottom distance. In other words, the impenetrable ground layer is assumed to be a set distance below the surface. The distance is uniform across the entire project area, and thus the impenetrable follows the profile of the surface.

The fraction of water the ground can store per volume is defined with the WATER_STORAGE_PERCENTAGE attribute of the ground layer terrain.

The ground layer is modeled using two layers: the unsaturated zone and the saturated zone. The saturated zone is the region of the ground where the soil is fully saturated with water. The unsaturated zone is the region of the ground located directly above the saturated zone. This region can also contain water, but the amount contained is always less than the maximum storage fraction. Water in the unsaturated zone is assumed to be uniformly distributed across the entire height of the zone.

The edge between the unsaturated and saturated zone is defined as the groundwater level, also known as the watertable.

The groundwater table is the height of the top of the saturated zone, relative to datum. The amount of water in the saturated zone is determined with the datum height of the groundwater table, the datum height of the surface, the ground bottom distance and the ground terrain's WATER_STORAGE_PERCENTAGE.

Initialization

The ground water level is initialized with the values of the ground water prequel connected to the water model. If no ground water data is connected, the ground water level relative to datum is equal to the surface water level relative to datum, as defined by the WATER_LEVEL attribute of the water area in that location. If no water area exists there either, the groundwater level is set to one meter below the surface.

Vertical flow

Vertical ground water flow is modeled as infiltration and evapotranspiration.

Horizontal flow and aquifers

Ground flow is different from surface flow, since it has to account for the slowdown and porousness of the medium. In general, horizontal ground flow is calculated using formulas described in Harbaugh 2005[1][2]. Depending on the configuration of the Water Overlay , the flow can also be calculated using a KD values instead of K. However, when an aquifer is present, the horizontal aquifer flow variant is applied.

Undergroundflow2.png

Bottom flow

Water can also flow into the ground layer from deeper confined layers due to pressure from higher regions outside the project area. The speed at which the ground bottom flow occurs is dependent on the local ground water levels, the head (pressure) of the higher regions and the resistance of the layer separating the saturated zone of the freatic ground layer and deeper ground layer.

Note that ground bottom flow can also be negative, allowing water to flow out of the project area to the deeper confined layers to regions elsewhere.

Drainage

Drainages are hydraulic structures that provide connections between the ground and nearby waterways, draining groundwater to levels which are optimal for agriculture.

A Drainage can be:

Notes

  • The sewer is explicitly not part of the ground model, and is not affected by the GROUND_WATER attribute nor by the ground model directly.

Related

The following topics are related to this models.

Formulas
Groundwater level formula (Water Overlay)
Ground flow formula (Water Overlay)
Ground evaporation formula (Water Overlay)
Surface infiltration formula (Water Overlay)
Ground bottom flow formula (Water Overlay)
Ground infiltration formula (Water Overlay)
Models
Surface model (Water Overlay)
Evaporation model (Water Overlay)
Infiltration model (Water Overlay)
Tracer flow model (Water Overlay)

References

  1. Harbaugh, A.W., 2005, MODFLOW-2005, the U.S. Geological Survey modular ground-water model-the Ground-Water Flow Process: U.S. Geological Survey Techniques and Methods 6-A16, variously paginated.
  2. Langevin, C.D., Hughes, J.D., Banta, E.R., Niswonger, R.G., Panday, Sorab, and Provost, A.M. (2017) ∙ Documentation for the MODFLOW 6 Groundwater Flow Model: U.S. Geological Survey Techniques and Methods, book 6, chap. A55 ∙ p 31 ∙ found at: https://doi.org/10.3133/tm6A55 (last visited 2019-02-04)