Breach flow formula (Water Overlay): Difference between revisions

From Tygron Support wiki
Jump to navigation Jump to search
No edit summary
No edit summary
Line 6: Line 6:
* The water level used is defined by either an [[Breach_input_area_(Water_Overlay)|input area]] or the [[External water level (Water Overlay)|external water level]].  
* The water level used is defined by either an [[Breach_input_area_(Water_Overlay)|input area]] or the [[External water level (Water Overlay)|external water level]].  
* In case of an external area, the surface height used is defined by [[External surface level (Water Overlay)|external surface level]]. This height limits how far the water level can be lowered.
* In case of an external area, the surface height used is defined by [[External surface level (Water Overlay)|external surface level]]. This height limits how far the water level can be lowered.
* Optionally a second value can be supplied for the external surface level. In that case, the second value represents the area of the bottom.
* In case of an [[Breach input area (Water Overlay)|input area]], the average water level is based on the [[Surface water level formula (Water Overlay)|water level]] on the individual grid cells of the input area.
* In case of an [[Breach input area (Water Overlay)|input area]], the average water level is based on the [[Surface water level formula (Water Overlay)|water level]] on the individual grid cells of the input area.


Each timestep, the external water level is changed based on the amount of water flowing in or out.
Each timestep, the external water level is changed based on the amount of water flowing in or out.


<math>w_{e,t+1} = w_{e,t} -  \frac{Q_w}{A_b}</math>
<math>\Delta V = min(h_e \cdot A_s , Q_w \cdot \Delta t)</math>
In case <math>A_s == A_b</math>:
<math>w_{e,t+1} = w_{e,t} -  \frac{\Delta V}{A_b}</math>
Otherwise, the external water area is represented as a trapezoid prism and the new water level has to be calculated differently:
:<math>l = \sqrt{A_s}</math>
:<math>w_s = l</math>
:<math>w_b = \frac{A_b}{l}</math>
:<math>a = \frac{w_s-w_b}{4 \cdot h_0}
:<math>A_{t,t} = 2 \cdot (a \cdot h_t^2 + 0.5 \cdot w_b)</math>
:<math>\Delta A = \frac{\Delta V}{l}</math>
:<math>c = \frac{-\Delta A * A_{t,t}}{2}</math>
:<math>D = (\frac{w_b}{2})^2 - 4 \cdot a \cdot c</math>
 
if <math> D < 0</math>:
<math>w_{e,t+1} = w_{e,t} + \frac{\Delta V}{A_b}}</math>
 
else:
 
\end{cases}
</math>


Where:
Where:
: <math>Q_w</math> =  The calculated water flow which takes place, based on the [[Weir formula (Water Overlay)|weir formula]].
: <math>Q_w</math> =  The calculated water flow which takes place, based on the [[Weir formula (Water Overlay)|weir formula]].
: <math>Q</math> =  The limited water flow which takes place, based on the remaining water.
: <math>w_{e,t}</math> = The [[Surface water level formula (Water Overlay)|water level]] of the entry area at time <math>t</math>; In case of an external area: [[External water level (Water Overlay)|EXTERNAL_WATER_LEVEL]] of the [[Breach (Water Overlay)|breach]].
: <math>w_{e,t}</math> = The [[Surface water level formula (Water Overlay)|water level]] of the entry area at time <math>t</math>; In case of an external area: [[External water level (Water Overlay)|EXTERNAL_WATER_LEVEL]] of the [[Breach (Water Overlay)|breach]].
: <math>A_{s}</math> = The size of in the entry area; In case of an external area: [[External area (Water Overlay)|EXTERNAL_AREA]] of the breach.
: <math>A_{s}</math> = The size of in the entry area; In case of an external area: [[External area (Water Overlay)|EXTERNAL_AREA]] of the breach.

Revision as of 09:35, 21 June 2023

Flow through breaches is calculated based on the weir formula, including the consideration between free flow and submerged flow situations. The weir formula is supplied with the breach width (as stand-in for the weir width), which is always calculated with the breach growth formula before calculating the weir flow. The downstream water level can optionally be measured with an additionally configured Breach Level Area, or an automatically placed

For the entry area, the area where the water originates from, the following also applies:

  • The water level used is defined by either an input area or the external water level.
  • In case of an external area, the surface height used is defined by external surface level. This height limits how far the water level can be lowered.
  • Optionally a second value can be supplied for the external surface level. In that case, the second value represents the area of the bottom.
  • In case of an input area, the average water level is based on the water level on the individual grid cells of the input area.

Each timestep, the external water level is changed based on the amount of water flowing in or out.

In case : Otherwise, the external water area is represented as a trapezoid prism and the new water level has to be calculated differently:

if : Failed to parse (syntax error): {\displaystyle w_{e,t+1} = w_{e,t} + \frac{\Delta V}{A_b}}}

else:

\end{cases} </math>

Where:

= The calculated water flow which takes place, based on the weir formula.
= The limited water flow which takes place, based on the remaining water.
= The water level of the entry area at time ; In case of an external area: EXTERNAL_WATER_LEVEL of the breach.
= The size of in the entry area; In case of an external area: EXTERNAL_AREA of the breach.
= The (optional) size of the bottom of the entry area; In case of an external area: the second value provided for the EXTERNAL_AREA of the breach. In case only one value is provided,

Notes

  • The water level we cannot become lower than the surface height se, defined by EXTERNAL_SURFACE_LEVEL in case of an external entry area. In case of an input area within the project, the surface height is determined per grid cell.

Related

The following topics are related to this formula.

Features
Breach
Formulas
Weir formula
Breach growth formula
Models
Surface model