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{{Navigation|before=|high=Description of the system elements|after=Introduction}}
{{Navigation|vorher=|hoch=Beschreibung der Systemelemente|nachher=Einleitung}}
[[Datei:Systemelement001.png|50px|none|Symbol System Element Catchment Area]] The simulation of natural catchment areas requires the determination of load generation, flow branching and runoff concentration. The methods of calculation used are described below.
[[Datei:Systemelement001.png|50px|none]] The simulation of natural catchment areas requires calculating the processes of runoff generation, distribution and concentration. The methods of calculation used are described below.




==Load Generation==
==Load Generation==


The load formation describes the determination of precipitation for the considered catchment area. Only one precipitation is used per catchment area. If there are several precipitation stations in the catchment area, it is useful to divide the area into several system elements 'catchment area', until only one precipitation can be assigned to each element.
Load generation is the process of determining the precipitation for the considered catchment area. In Talsim-NG, each sub-basin uses only one precipitation source. If there are several precipitation measurement stations in the catchment area, you can either divide the area into several sub-basins or aggregate precipitation sources, until only one precipitation source can be assigned to each element.




==Runoff generation of paved/unpaved surfaces==
==Runoff Generation for Permeable/Impermeable Areas==


The runoff generation determines the effective precipitation from the rainfall. From this, the components surface runoff, infiltration, evaporation and interflow are derived. A snow calculation is performed at temperatures below zero °C and is based on the Snow-Compaction-Method. Regarding the algorithms of the method, reference is made to the relevant literature.
Runoff generation determines the amount of effective precipitation from the rainfall. From this, the components surface runoff, infiltration, evaporation and interflow are derived. By defaut, snow calculation is carried out at temperatures below zero °C and is based on the Snow-Compaction-Method. Regarding the algorithms of the method, reference is made to the relevant literature.
The natural process from precipitation to runoff is divided into individual phases for the mathematical simulation. In the runoff generation phase, the precipitation (system load) is divided into the "effective precipitation" directly reaching the runoff, and the losses not affecting the runoff (moistening, trough, evaporation and infiltration losses). Therefore, this phase is also called load distribution. The resulting mathematical equation for the momentary load distribution is written as follows:
The natural process from precipitation to runoff is divided into individual phases for the mathematical simulation. In the runoff generation phase, the precipitation (system load) is divided into the "effective precipitation" which is transformed into runoff, and the losses not affecting runoff (wetting, depression, evaporation and infiltration losses). Therefore, this phase is also called load distribution. The resulting mathematical equation for the momentary load distribution is as follows:


<math>N_W(t) =N(t) -VP(t) -I(t) - \frac{dO}{dt} - \frac{dS}{dt}</math>
<math>N_W(t) =N(t) -VP(t) -I(t) - \frac{dO}{dt} - \frac{dS}{dt}</math>
Zeile 25: Zeile 25:
|<math>VP</math>: || Potential evaporation
|<math>VP</math>: || Potential evaporation
|-
|-
|<math>I</math>: || Infiltration into the floor area
|<math>I</math>: || Infiltration into the soil
|-
|-
|<math>O</math>: || Surface water supply
|<math>O</math>: || Surface water supply
Zeile 38: Zeile 38:
===Precipitation N(t)===
===Precipitation N(t)===


The precipitation data must be added to the simulation model in the form of rainfall series. In principle, it is irrelevant whether the precipitation series is a block rain, a model rain, a measured natural rain, a rain spectrum or a long-time rain series. Depending on the objective of the simulation calculation the appropriate load has to be selected. The rainfall series are either taken from the time series management of Talsim-NG or are generated, in case of applying a short term forecast, by entering a rainfall duration, a precipitation height and the choice of a rain model directly before a simulation.
Precipitation data must be provided to the simulation model in the form of time series. In principle, it is irrelevant whether the precipitation series is a block rain, a model rain, a time series of natural observed rainfall, a rain spectrum or a long-term rainfall time series. The appropriate load has to be selected depending on the objective of the simulation. The rainfall time series are either taken from the time series management of Talsim-NG or, when carrying out a short-term forecast, are generated by entering a duration, an amount and by selecting a model rain directly before a simulation.




=== Evaporation VP(t)===
=== Evaporation VP(t)===


Evaporation has a double effect on the formation of runoff. On the one hand, the initial conditions in the catchment area (wetting and trough filling on the surface as well as limiting soil moisture on permeable surfaces) are a result of the evaporation taking place before the considered precipitation event. On the other hand, the precipitation to be calculated, which affects runoff, is reduced by the amount of the current evaporation rate. The potential (energetically possible) evaporation VP is very different in time and place and is hardly accessible for an exact calculation. From evaluated measurements of 20 stations, mean values of these stations are presented as histogram. The following compensation function was determined /BRANDT, 1979/.
Evaporation has a double effect on runoff generation. On the one hand, the initial conditions in the catchment area (interception and depression storage on the surface as well as to a limited degree the soil moisture of permeable areas) are a result of the evaporation taking place before the considered precipitation event. On the other hand, the current runoff-effective precipitation is affected by the amount of the current evaporation rate.
 
The potential (energetically possible) evaporation VP varies in time and place and is very difficult to calculate exactly.
 
Talsim-NG offers multiple options for entering/calculating potential evaporation:
* Specification of an external time series with values for the potential evaporation
* Internal calculation of potential evaporation: the potential evaporation can be calculated internally based on temperature and, depending on the method, additional parameters. The following methods are available:
** Penman: requires the specification of average patterns or of time series for sunshine duration, wind speed and relative humidity
** Haude: requires the specification of average patterns or of a time series for relative humidity
** Turc: requires the specification of average patterns or of time series for sunshine duration and relative humidity
** Blaney-Criddle: simplistic method requiring only the specification of a latitude which is used internally to derive the sunshine duration.
* Specification of a fixed evaporation rate per year: when using this option, the entered annual value is distributed inner-annually using the compensation function according to Brandt (see below).
 
====Compensation functions====
The following compensation functions according to Brandt are used to distribute entered annual values for evaporation over the year and to convert daily values to hourly values.
 
Using evaluated measurements of 20 stations, the mean values of which are presented in the following histogram, the following compensation function was determined /BRANDT, 1979/.


<math>VP=(0.96+0.0033 \cdot i) \cdot \sin\frac{2\pi}{365}(i-148)+158</math>
<math>VP=(0.96+0.0033 \cdot i) \cdot \sin\frac{2\pi}{365}(i-148)+158</math>
Zeile 49: Zeile 65:
with:
with:
{|style="margin-left: 40px;"
{|style="margin-left: 40px;"
|<math>i</math>: || current day of the outflow year
|<math>i</math>: || current day of the hydrological year
|-
|-
|<math>i=1</math>: || November 1
|<math>i=1</math>: || November 1
Zeile 55: Zeile 71:
|}
|}


The total annual potential evaporation height is 642 mm. If no measured evaporation values are available, this normalized annual potential evaporation can optionally be used to calculate the current evaporation. If the selected calculation time interval is less than one day, the potential evaporation for each calculation time interval is finally determined by means of the displayed daily variation. If the calculation interval is less than 1 day, the daily course is not taken into account.
The total annual potential evaporation height in this sample is 642 mm. If no measured evaporation values are available, this normalized annual potential evaporation pattern can optionally be used to calculate the current evaporation. If the simulation time step is less than one day, the potential evaporation for each time step is additionally determined using the daily pattern displayed below. If the calculation interval is more than 1 day, the daily pattern is not taken into account.
<gallery mode="packed" heights=300px">
<gallery mode="packed" heights=300px">
Datei:Jahresgang_ETpot.png|Year of potential evaporation after /BRAND, 1979/
Datei:Jahresgang_ETpot_EN.png|Annual pattern of potential evaporation according to /BRANDT, 1979/
Datei:Tagesgang_ETpot.png|Daily rate of potential evaporation as a multiple of the mean daily evaporation
Datei:Tagesgang_ETpot_EN.png|Daily pattern of potential evaporation as a multiple of the mean daily evaporation
</gallery>
</gallery>


===Surface Water Storage (Impermeable Areas) O===


===Surface water supply (sealed area portion) ===
For impermeable areas, snow storage and infiltration can be neglected, so that the balance equation is simplified as follows:
 
In the case of sealed surface portions, snow supply and infiltration can be neglected, so that the balance equation is simplified as follows:


<math>N_W(t)=N(t)-VP(t)-\frac{dO}{dt}</math>
<math>N_W(t)=N(t)-VP(t)-\frac{dO}{dt}</math>


the surface water supply change <math>dO/dt</math> represents the wetting of the surface as well as the filling and emptying (by evaporation) of the troughs.[[Datei:Schema_Modellansatz_Benetzungs-_und_Muldenverlust.png|thumb|cheme of the Model Approaches Loss of Wetting and Troughs]]
The change in surface water storage <math>dO/dt</math> represents the wetting of the surface as well as the filling and emptying (by evaporation) of depressions.[[Datei:Schema_Modellansatz_Benetzungs-_und_Muldenverlust_EN.png|thumb|Schematic of wetting and depression losses]]
The following standard value <math>BV</math> is used as wetting loss for sealed surfaces.
The following default value <math>BV</math> is used as wetting loss for impermeable areas.


<math>BV = 0.5 \mbox{ mm}</math>
<math>BV = 0.5 \mbox{ mm}</math>


The trough loss (MV) is specified by the user. The standard and simultaneously maximum value in the model is 4 mm.
Depression losses (MV) are specified by the user. The default and simultaneously maximum value in the model is 4 mm.
The trough loss represents the average value for an sloping surface. However, since the troughs are not evenly distributed and, as experience shows, drainage begins before the complete filling of the troughs has been reached everywhere, it is assumed that
Depression losses represent an average value for an sloped surface. Since depressions are not evenly distributed and runoff already begins before all depressions are completely filled, it is assumed that
* 1/3 of the sealed surface has a reduced trough loss of 1/3-MV
* 1/3 of the impermeable area has a reduced depression loss of 1/3&sdot;MV
* 1/3 of the sealed area the average trough loss of 3/3-MV
* 1/3 of the impermeable area has the average depression loss of MV
* 1/3 of the sealed surface has an increased trough loss of 5/3-MV
* 1/3 of the impermeable area has an increased depression loss of 5/3&sdot;MV
has. Therefore, runoff already occurs when the precipitation reduced by the evaporation rate exceeds the wetting loss and 1/3 of the trough loss (in case of dry history). The assumptions above are schematically sketched in the following figure.
Therefore, runoff already occurs when the precipitation reduced by the evaporation rate exceeds the wetting loss and 1/3 of the depression losses (in case of dry starting conditions). The assumptions described above are shown as a schematic in the following figure.


The runoff coefficient of the sealed surfaces (after covering the initial losses) is set at <math>\Psi = 1</math>. When determining the sealed surface of a subcatchment area, it must be taken into account that not all paved or sealed surfaces actually drain into a sewer system.
The runoff coefficient of the impermeable areas (after covering the initial losses) is set at <math>\Psi = 1</math>. When determining the portion of impermeable areas for a sub-basin, you must take into account that not all paved or sealed surfaces actually drain into a sewer system.
The continuous provision of the wetting and trough losses is achieved by continuous balancing of these reservoirs and evaporation.
The continuous provision of wetting and depression losses is achieved by continuously balancing the corresponding storages and the evaporation.




===Surface water supply (unsealed area) ===
===Surface Water Storage (Permeable Areas) O===


The surface water supply is calculated by balancing a loss reservoir depending on the selected runoff generation approach. Details can be found in the following sections on the calculation of infiltration or runoff-effective precipitation.
The surface water storage of permeable areas is calculated by balancing a loss storage depending on the selected runoff generation approach. Details can be found in the following sections on the calculation of infiltration and runoff-effective precipitation.




=== Infiltration or runoff-effective precipitation I(t), N<sub>W</sub>(t)===
=== Infiltration and runoff-effective precipitation I(t), N<sub>W</sub>(t)===


In the case of permeable surfaces, infiltration into the soil cannot be neglected, since this has a decisive influence on the runoff. For the calculation three approaches were implemented in the model:
In the case of permeable areas, infiltration into the soil cannot be neglected, since this has a decisive influence on the runoff. For the calculation three approaches are implemented in the model:
# Constant discharge coefficient <math>\Psi</math>
# Constant discharge coefficient <math>\Psi</math>
# Event-specific discharge coefficient based on the Soil-Conservation-Service (SCS) method
# Event-specific discharge coefficient based on the Soil-Conservation-Service (SCS) method
Zeile 99: Zeile 114:
====Constant discharge coefficient &Psi;====
====Constant discharge coefficient &Psi;====


If a <math>\Psi</math> value is given, the remaining part of the precipitation in the ratio of the runoff coefficient <math>\Psi</math> is added to the runoff after covering the initial losses (wetting and trough loss), independent of the history and characteristics of the precipitation. If possible, this approach should be avoided, since the process of runoff formation is only roughly simplified.
If a <math>\Psi</math> value is given, the remaining part of the precipitation after covering the initial losses (wetting and depression losses) is converted to runoff by multplying with <math>\Psi</math>, independent of the antecedent conditions and the characteristics of the rainfall event (amount, intensity, duration). If possible, this approach should be avoided, since the process of runoff formation is greatly simplified.




====Event-specific discharge coefficient based on the Soil-Conservation-Service (SCS)====
====Event-specific discharge coefficient based on the Soil-Conservation-Service (SCS) method====


If a CN value is given that is dependent on the soil type and land use (see /DVWK, 1991/), a prehistoric initial loss as well as a prehistoric relationship of the runoff coefficient from the amount of precipitation accumulated up to the time under consideration can be formulated /Zaiss, 1987/; i.e. the runoff coefficient increases with increasing precipitation in the course of the event.
Using a CN value that is dependent on the soil type and land use (see /DVWK, 1991/), the initial losses and a relationship between the runoff coefficient and the accumulated rainfall amount up to the current point in time can be derived, both of which are dependent on antecedent conditions /Zaiss, 1987/. With this approach, the runoff coefficient increases with increasing precipitation amount during the course of the rainfall event.
The quantification of the prehistory is based on the 21-day-precipitation index <math>VN</math>
The quantification of the antecedent conditions is based on the 21-day-precipitation index <math>VN</math>.


<math>V_N=\sum_{j=1}^21 C(j)^j \cdot hN_j</math>
<math>V_N=\sum_{j=1}^21 C(j)^j \cdot hN_j</math>
Zeile 111: Zeile 126:
with:
with:
{|style="margin-left: 40px;"
{|style="margin-left: 40px;"
|<math>hN_j</math>: || Precipitation height of the j-th previous day
|<math>hN_j</math>: || Precipitation amount of the j-th previous day
|-
|-
|<math>C(j)</math>: || Factor describing the influence of the j-th previous day
|<math>C(j)</math>: || Factor describing the influence of the j-th previous day
Zeile 117: Zeile 132:
|}
|}


The season impact is represented by a yearly variation of the factor C.
The impact of different seasons is represented by an annual pattern of the factor C.


<math>C=0.05 \cdot \sin\frac{2\pi}{365}(i+0.75)+0.85</math>
<math>C=0.05 \cdot \sin\frac{2\pi}{365}(i+0.75)+0.85</math>
Zeile 123: Zeile 138:
with:
with:
{|style="margin-left: 40px;"
{|style="margin-left: 40px;"
|<math>i</math>: || current day of the outflow year
|<math>i</math>: || current day of the hydrological year
|-
|-
|}
|}


As a result, the value C ranges between 0.8 < C < 0.9. This ensures that different rainfall indices are calculated for the same amount of rainfall at different times of the year and therefore a changed willingness to flow is taken into account.
As a result, the value of C ranges between 0.8 < C < 0.9. This ensures that different rainfall indices are calculated for the same amount of rainfall at different times of the year, thus taking into account different degrees of runoff readiness.
Depending on the prehistory quantified in this way, a current discharge coefficient can be calculated using the CN values specific to the area and valid for average prehistory conditions. The following figure shows for different CN-values how the current discharge coefficient changes depending on the prehistory.
Depending on the antecedent conditions quantified in this way, a current discharge coefficient can be calculated using the CN values specific to the area and valid for average previous conditions. The following figure shows how the current discharge coefficient for different CN-values changes depending on antecedent conditions.
Since the runoff readiness of a catchment area changes in the course of a rainfall event due to soil moisture, the runoff coefficient is also adjusted during an event as a function of the cumulative precipitation height.
Since the runoff readiness of a catchment area changes during the course of a rainfall event due to soil moistening, the runoff coefficient is also adjusted during an event as a function of the cumulative precipitation amount.
<gallery mode="packed" heights=300px>
<gallery mode="packed" heights=300px>
Datei:Abhängigkeit_des_Abflussbeiwertes_von_der_Vorgeschichte.png|Dependence of the discharge coefficient on the previous history
Datei:Abhängigkeit_des_Abflussbeiwertes_von_der_Vorgeschichte_EN.png|Dependence of the runoff coefficient on antecedent conditions
Datei:Abhängigkeit_des_Abflussbeiwertes_von_der_kumulierten_Niederschlagssumme.png|Dependence of the runoff coefficient on the cumulative precipitation sum
Datei:Abhängigkeit_des_Abflussbeiwertes_von_der_kumulierten_Niederschlagssumme_EN.png|Dependence of the runoff coefficient on the cumulative precipitation sum
</gallery>
</gallery>


Zeile 139: Zeile 154:




=====Land use=====
=====Land Use=====


When using soil moisture simulation, it is necessary to specify the land use. From the information about land use, the rooting depth is needed to determine the thickness of the rooting layer. Further parameters of land use, which are used to calculate interception and transpiration, are
When using soil moisture simulation, it is necessary to specify the land use. From the information about land use, the rooting depth is needed to determine the thickness of the root layer. Further parameters of land use, which are used to calculate interception and transpiration, are
* Root depth
* Root depth
* Coverage rate
* Coverage
* Annual cycle of the degree of coverage
* Annual pattern of coverage
* Leaf area index
* Leaf area index
* Year of the leaf area index
* Annual pattern of the leaf area index
Haude factors can be assigned to each land use for a better consideration of the evaporation by entering annual courses.
Haude factors entered as annual patterns can be assigned to each land use for a better consideration of the evaporation.




=====Soil type/ Soil texture=====
=====Soil Type / Soil Texture=====


[[Datei:Programminterne_Zusammenfassung_Bodenschichten.png|thumb|Example of the summary of the soil layers to an internal program layer based on the rooting layer]]
[[Datei:Programminterne_Zusammenfassung_Bodenschichten_EN.png|thumb|Aggregation of soil layers to simulation layers]]
[[Datei:Schema_Bodenfeuchtesimulation.png|thumb|Sizes calculated with the soil moisture simulation]]
[[Datei:Schema_Bodenfeuchtesimulation_EN.png|thumb|Variables calculated with the soil moisture simulation]]
The soil moisture simulation is based on a non-linear calculation of the individual soil horizons. The soil is divided into different horizons (layers). Each layer is calculated and compared with the layers below or above (if available). The following soil physical parameters are used as parameters for the soil moisture calculation:
The soil moisture simulation is based on a non-linear calculation of the individual soil layers. The soil is divided into different layers. Each layer is calculated individually and inflows and outflows reconciled with the layers below or above (if present). The following physical soil parameters are used as parameters for the soil moisture calculation:
* Wilting point (WP)
* Wilting point (WP)
* Field capacity (FK)
* Field capacity (FC)
* Total pore volume (GPV)
* Total pore volume (TPV)
* Saturated conductivity (kf value)
* Saturated conductivity (kf value)
* Maximum infiltration capacity (Max.Inf.)
* Maximum infiltration capacity (max. inf.)
* Maximum rate of capillary suction (Max.Cap.)
* Maximum rate of capillary suction (max. cap.)
* Assignment to a soil type: sand, silt, clay
* Soil categorization: sand, silt, clay


The possible number of soil layers ranges from a minimum of one to a maximum of six. Experience has shown that the best results are achieved with a division into three layers. For this reason, the entered layers are always divided into three horizons within the program.
The possible number of soil layers ranges from a minimum of one to a maximum of six. Experience has shown that the best results are achieved with a division into three layers. For this reason, the entered layers are always internally divided into three simulation layers:
* Infiltration layer (standard thickness [cm] = 20)
* Infiltration layer (standard thickness [cm] = 20)
* Rooted layer (minimum thickness [cm] = 5)
* Root layer (minimum thickness [cm] = 5)
* Transport layer (minimum thickness [cm] = 5)
* Transport layer (minimum thickness [cm] = 5)


The calculation of the new soil properties for the layers used within the program is done by weighting them according to the given original thicknesses of the layers. In case of saturated conductivity the calculation is based on the principle of maintaining the continuity of the flow. In the case of vertical flow, the velocity v at a given flow rate in a program internal layer should have the same value due to the continuity of the flow. Thus, the hydraulic gradient is no longer constant.
The calculation of soil properties for the simulation layers is done by weighting them according to the given original thicknesses of the layers. In case of saturated conductivity the calculation is based on the principle of maintaining the continuity of the flow. For vertical flow, the velocity v at a given flow rate in one simulation layer should have the same value due to the continuity of the flow. Thus, the hydraulic gradient is no longer constant.


<math>kf_V=\frac{\sum_{i=1}^n d_i}{\sum_{i=1}^n \frac{d_i}{k_i}}</math>
<math>kf_V=\frac{\sum_{i=1}^n d_i}{\sum_{i=1}^n \frac{d_i}{k_i}}</math>
Zeile 178: Zeile 193:
|<math>k_i</math>: || saturated conductivity of the respective original layer [mm/h]
|<math>k_i</math>: || saturated conductivity of the respective original layer [mm/h]
|-
|-
|<math>kf_V</math>: || saturated conductivity of the layer used within the program [mm/h]
|<math>kf_V</math>: || saturated conductivity of the simulation layer [mm/h]
|-
|-
|}
|}
[[Datei:Schema_aktuelle_Verdunstung.png|thumb|Scheme of determination of the current evaporation]]
[[Datei:Schema_aktuelle_Verdunstung_EN.png|thumb|Schematic of calculation of the actual evapotranspiration]]
The water balance equation for a soil layer is solved on the basis of the area-wise linear representation of the process functions infiltration, current evaporation (evaporation + transpiration), percolation, interflow and capillary suction, which influence soil moisture. The input variable for evaporation and transpiration is determined from the potential evaporation.
The water balance equation for a soil layer is solved on the basis of the piece-wise linear representation of the process functions which influence soil moisture: infiltration, current evaporation (evaporation + transpiration), percolation, interflow and capillary suction. The input variable for evaporation and transpiration is determined from the potential evaporation.
The equation to be solved is:
The equation to be solved is:


Zeile 191: Zeile 206:
|<math>BF(t)</math>: || current soil moisture
|<math>BF(t)</math>: || current soil moisture
|-
|-
|<math>Inf(t)</math>: || Infiltration into the soil
|<math>Inf(t)</math>: || infiltration into the soil
|-
|-
|<math>Perk(t)</math>: || Percolation (seepage)
|<math>Perk(t)</math>: || percolation (seepage)
|-
|-
|<math>Eva_{akt}(t)</math>: || current evaporation
|<math>Eva_{akt}(t)</math>: || current evaporation
Zeile 204: Zeile 219:
|-
|-
|}
|}
[[Datei:Bodenprozessfunktionen.png|thumb|Display of selected soil process functions]]
[[Datei:Bodenprozessfunktionen_EN.png|thumb|Display of selected soil process functions]]
Infiltration, percolation, evaporation, transpiration, interflow and capillary suction depend on the current soil moisture. In the simulation, this dependence is described by the following function courses.
Infiltration, percolation, evaporation, transpiration, interflow and capillary suction depend on the current soil moisture. In the simulation, this dependence is described by the following functions.


<math>Inf(BF(t))=a_v \cdot \left(GPV-BF(t) \right)^{1.4}+k_f </math> &nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;(Ansatz nach HOLTAN)
<math>Inf(BF(t))=a_v \cdot \left(GPV-BF(t) \right)^{1.4}+k_f </math> &nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;(Approach according to HOLTAN)


<math>
<math>
Zeile 216: Zeile 231:
\end{cases}
\end{cases}
</math>
</math>
:::::::::::::::::(mod. Ansatz nach /OSTROWSKI, 1992/)
:::::::::::::::::(mod. approach according to /OSTROWSKI, 1992/)
<math>
<math>
Eva(BF(t)) =  
Eva(BF(t)) =  
Zeile 233: Zeile 248:
</math>
</math>


mit:
with:
{|style="margin-left: 40px;"
{|style="margin-left: 40px;"
|<math>a_v</math>: || Infiltrationsfaktor nach HOLTAN (in Talsim-NG <math>a_v=1</math>
|<math>a_v</math>: || infiltration factor according to HOLTAN (in Talsim-NG <math>a_v=1</math>)
|-
|-
|<math>k_f</math>: || Durchlässigkeitsbeiwert des gesättigten Bodens
|<math>k_f</math>: || coefficient of conductivity of saturated soil
|-
|-
|<math>nFK</math>: || nutzbare Feldkapazität (<math>nFK=FK-WP</math>)
|<math>nFK</math>: || available water capacity (<math>nFK=FK-WP</math>)
|-
|-
|<math>WP</math>: || Welkepunkt
|<math>WP</math>: || wilting point
|-
|-
|<math>FK</math>: || Feldkapazität
|<math>FK</math>: || field capacity
|-
|-
|<math>GPV</math>: || gesamtes Porenvolumen
|<math>GPV</math>: || total pore volume
|-
|-
|<math>f_{PK}</math>: || bodenabhängiger Skalierungfaktor der Perkolationsfunktion
|<math>f_{PK}</math>: || soil-dependent scaling factor of the percolation function
|-
|-
|<math>exp,PK</math>: || bodenabhängiger Krümmungsparameter der Perkolationsfunktion
|<math>exp,PK</math>: || soil-dependent curvature parameter of the percolation function
|-
|-
|<math>f_{Eva}</math>: || bodenabhängiger Skalierungsfaktor der Evaporationsfunktion
|<math>f_{Eva}</math>: || soil-dependent scaling factor of the evaporation function
|-
|-
|<math>f_{Trans}</math>: || bodenabhängiger Skalierungsfaktor der Transpirationsfunktion
|<math>f_{Trans}</math>: || soil-dependent scaling factor of the transpiration function
|-
|-
|<math>exp,Trans</math>: || Krümmungsparameter der Transpirationsfunktion
|<math>exp,Trans</math>: || curvature parameter of the transpiration function
|-
|-
|}
|}


Die Programmparameter werden intern berechnet. Der Anwender muss lediglich die Bodenkennwerte kf, WP, FK und GPV angeben.
These parameters are calculated internally. The user only has to specify the soil parameters kf, WP, FC and TPV.
Die Berechnung der Bodenprozesse erfolgt mit einem neuentwickelten [[Special:MyLanguage/Berechnungsschema von Speichern|Baustein zur Simulation von Speichern]].
The soil processes is are solved using a [[Special:MyLanguage/Berechnungsschema von Speichern|component for the simulation of storage]].




=====Elementarflächen=====
=====Hydrologic Response Units=====


Wird mit der Bodenfeuchtesimulation die Abflussbildung berechnet, wird gleichzeitig das Elementarflächenkonzept angewandt. Ein Einzugsgebietselement wird dabei in beliebig viele hydrologisch homogene Flächen unterteilt, d.h. Flächen gleichen Bodentyps und gleicher Landnutzung.
When runoff generation is calculated using soil moisture simulation, the concept of hydrologic response units (HRUs) is applied. A catchment area is divided into a number of hydrologically homogeneous areas, i.e. areas of the same soil type and the same land use.
Für jede Elementarfläche gilt genau eine Zuordnung von Landnutzung und Bodentyp. Die aus einer Elementarfläche resultierende Wassermenge wird am Elementausgang angesetzt, d.h. alle Elementarflächen geben unabhängig ihrer Lage im Einzugsgebiet Wasser mit der gleichen zeitlichen Verzögerung ab.
For each hydrologic response unit there is exactly one assignment of land use and soil type. The discharge resulting from a hydrologic response unit is output from the sub-basin element to which the HRU belongs, i.e. all hydrologic response units release discharge with the same time delay, independent of their location within the sub-basin.
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<gallery mode="packed" heights=200px>
Datei:Aufteilung_EZG_in_Elementarflächen.png|Aufteilung eines Einzugsgebietselementes in Elementarflächen
Datei:Aufteilung_EZG_in_Elementarflächen.png|Division of a sub-basin element into hydrologic response units
Datei:Elementarflächen_Zuordnung_Bodentyp_Landnutzung.png|Zuordnung von Bodentyp und Landnutzung zu Elementarflächen
Datei:Elementarflächen_Zuordnung_Bodentyp_Landnutzung_EN.png|Assignment of soil type and land use to hydrologic response units
</gallery>
</gallery>




==Abflusskonzentration==
==Runoff Concentration==


Die Abflusskonzentration bestimmt die Verzögerung des Oberflächenabflusses aus dem Einzugsgebiet. Es wird eine Parallelspeicherkaskade mit drei Speichern für unbefestigte und eine Kaskade für befestigte Flächen benutzt. Der Abfluss der Komponenten Interflow und Grundwasser wird über einen linearen Einzelspeicher verzögert an den Elementausgang abgegeben.
Runoff concentration determines the delay of runoff from the catchment area. A parallel storage cascade with three reservoirs for permeable and one cascade for impermeable areas is used for surface runoff. The outflow of the components interflow and baseflow is output at the element outlet after passing through a single linear storage.
[[Datei:Abflusskonzentration.png|frame|none|Berechnung der Abflusskonzentration von Einzugsgebieten]]
[[Datei:Abflusskonzentration_EN.png|frame|none|Calculation of the runoff concentration of catchment areas]]

Aktuelle Version vom 17. Dezember 2020, 10:45 Uhr

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Systemelement001.png

The simulation of natural catchment areas requires calculating the processes of runoff generation, distribution and concentration. The methods of calculation used are described below.


Load Generation

Load generation is the process of determining the precipitation for the considered catchment area. In Talsim-NG, each sub-basin uses only one precipitation source. If there are several precipitation measurement stations in the catchment area, you can either divide the area into several sub-basins or aggregate precipitation sources, until only one precipitation source can be assigned to each element.


Runoff Generation for Permeable/Impermeable Areas

Runoff generation determines the amount of effective precipitation from the rainfall. From this, the components surface runoff, infiltration, evaporation and interflow are derived. By defaut, snow calculation is carried out at temperatures below zero °C and is based on the Snow-Compaction-Method. Regarding the algorithms of the method, reference is made to the relevant literature. The natural process from precipitation to runoff is divided into individual phases for the mathematical simulation. In the runoff generation phase, the precipitation (system load) is divided into the "effective precipitation" which is transformed into runoff, and the losses not affecting runoff (wetting, depression, evaporation and infiltration losses). Therefore, this phase is also called load distribution. The resulting mathematical equation for the momentary load distribution is as follows:

[math]\displaystyle{ N_W(t) =N(t) -VP(t) -I(t) - \frac{dO}{dt} - \frac{dS}{dt} }[/math]

with:

[math]\displaystyle{ N_W }[/math]: Runoff-effective precipitation
[math]\displaystyle{ N }[/math]: Precipitation
[math]\displaystyle{ VP }[/math]: Potential evaporation
[math]\displaystyle{ I }[/math]: Infiltration into the soil
[math]\displaystyle{ O }[/math]: Surface water supply
[math]\displaystyle{ S }[/math]: Snow storage

In the following, the terms used in the equation and their calculation are explained in detail.


Precipitation N(t)

Precipitation data must be provided to the simulation model in the form of time series. In principle, it is irrelevant whether the precipitation series is a block rain, a model rain, a time series of natural observed rainfall, a rain spectrum or a long-term rainfall time series. The appropriate load has to be selected depending on the objective of the simulation. The rainfall time series are either taken from the time series management of Talsim-NG or, when carrying out a short-term forecast, are generated by entering a duration, an amount and by selecting a model rain directly before a simulation.


Evaporation VP(t)

Evaporation has a double effect on runoff generation. On the one hand, the initial conditions in the catchment area (interception and depression storage on the surface as well as to a limited degree the soil moisture of permeable areas) are a result of the evaporation taking place before the considered precipitation event. On the other hand, the current runoff-effective precipitation is affected by the amount of the current evaporation rate.

The potential (energetically possible) evaporation VP varies in time and place and is very difficult to calculate exactly.

Talsim-NG offers multiple options for entering/calculating potential evaporation:

  • Specification of an external time series with values for the potential evaporation
  • Internal calculation of potential evaporation: the potential evaporation can be calculated internally based on temperature and, depending on the method, additional parameters. The following methods are available:
    • Penman: requires the specification of average patterns or of time series for sunshine duration, wind speed and relative humidity
    • Haude: requires the specification of average patterns or of a time series for relative humidity
    • Turc: requires the specification of average patterns or of time series for sunshine duration and relative humidity
    • Blaney-Criddle: simplistic method requiring only the specification of a latitude which is used internally to derive the sunshine duration.
  • Specification of a fixed evaporation rate per year: when using this option, the entered annual value is distributed inner-annually using the compensation function according to Brandt (see below).

Compensation functions

The following compensation functions according to Brandt are used to distribute entered annual values for evaporation over the year and to convert daily values to hourly values.

Using evaluated measurements of 20 stations, the mean values of which are presented in the following histogram, the following compensation function was determined /BRANDT, 1979/.

[math]\displaystyle{ VP=(0.96+0.0033 \cdot i) \cdot \sin\frac{2\pi}{365}(i-148)+158 }[/math]

with:

[math]\displaystyle{ i }[/math]: current day of the hydrological year
[math]\displaystyle{ i=1 }[/math]: November 1

The total annual potential evaporation height in this sample is 642 mm. If no measured evaporation values are available, this normalized annual potential evaporation pattern can optionally be used to calculate the current evaporation. If the simulation time step is less than one day, the potential evaporation for each time step is additionally determined using the daily pattern displayed below. If the calculation interval is more than 1 day, the daily pattern is not taken into account.

Surface Water Storage (Impermeable Areas) O

For impermeable areas, snow storage and infiltration can be neglected, so that the balance equation is simplified as follows:

[math]\displaystyle{ N_W(t)=N(t)-VP(t)-\frac{dO}{dt} }[/math]

The change in surface water storage [math]\displaystyle{ dO/dt }[/math] represents the wetting of the surface as well as the filling and emptying (by evaporation) of depressions.

Schematic of wetting and depression losses

The following default value [math]\displaystyle{ BV }[/math] is used as wetting loss for impermeable areas.

[math]\displaystyle{ BV = 0.5 \mbox{ mm} }[/math]

Depression losses (MV) are specified by the user. The default and simultaneously maximum value in the model is 4 mm. Depression losses represent an average value for an sloped surface. Since depressions are not evenly distributed and runoff already begins before all depressions are completely filled, it is assumed that

  • 1/3 of the impermeable area has a reduced depression loss of 1/3⋅MV
  • 1/3 of the impermeable area has the average depression loss of MV
  • 1/3 of the impermeable area has an increased depression loss of 5/3⋅MV

Therefore, runoff already occurs when the precipitation reduced by the evaporation rate exceeds the wetting loss and 1/3 of the depression losses (in case of dry starting conditions). The assumptions described above are shown as a schematic in the following figure.

The runoff coefficient of the impermeable areas (after covering the initial losses) is set at [math]\displaystyle{ \Psi = 1 }[/math]. When determining the portion of impermeable areas for a sub-basin, you must take into account that not all paved or sealed surfaces actually drain into a sewer system. The continuous provision of wetting and depression losses is achieved by continuously balancing the corresponding storages and the evaporation.


Surface Water Storage (Permeable Areas) O

The surface water storage of permeable areas is calculated by balancing a loss storage depending on the selected runoff generation approach. Details can be found in the following sections on the calculation of infiltration and runoff-effective precipitation.


Infiltration and runoff-effective precipitation I(t), NW(t)

In the case of permeable areas, infiltration into the soil cannot be neglected, since this has a decisive influence on the runoff. For the calculation three approaches are implemented in the model:

  1. Constant discharge coefficient [math]\displaystyle{ \Psi }[/math]
  2. Event-specific discharge coefficient based on the Soil-Conservation-Service (SCS) method
  3. Soil moisture simulation


Constant discharge coefficient Ψ

If a [math]\displaystyle{ \Psi }[/math] value is given, the remaining part of the precipitation after covering the initial losses (wetting and depression losses) is converted to runoff by multplying with [math]\displaystyle{ \Psi }[/math], independent of the antecedent conditions and the characteristics of the rainfall event (amount, intensity, duration). If possible, this approach should be avoided, since the process of runoff formation is greatly simplified.


Event-specific discharge coefficient based on the Soil-Conservation-Service (SCS) method

Using a CN value that is dependent on the soil type and land use (see /DVWK, 1991/), the initial losses and a relationship between the runoff coefficient and the accumulated rainfall amount up to the current point in time can be derived, both of which are dependent on antecedent conditions /Zaiss, 1987/. With this approach, the runoff coefficient increases with increasing precipitation amount during the course of the rainfall event. The quantification of the antecedent conditions is based on the 21-day-precipitation index [math]\displaystyle{ VN }[/math].

[math]\displaystyle{ V_N=\sum_{j=1}^21 C(j)^j \cdot hN_j }[/math]

with:

[math]\displaystyle{ hN_j }[/math]: Precipitation amount of the j-th previous day
[math]\displaystyle{ C(j) }[/math]: Factor describing the influence of the j-th previous day

The impact of different seasons is represented by an annual pattern of the factor C.

[math]\displaystyle{ C=0.05 \cdot \sin\frac{2\pi}{365}(i+0.75)+0.85 }[/math]

with:

[math]\displaystyle{ i }[/math]: current day of the hydrological year

As a result, the value of C ranges between 0.8 < C < 0.9. This ensures that different rainfall indices are calculated for the same amount of rainfall at different times of the year, thus taking into account different degrees of runoff readiness. Depending on the antecedent conditions quantified in this way, a current discharge coefficient can be calculated using the CN values specific to the area and valid for average previous conditions. The following figure shows how the current discharge coefficient for different CN-values changes depending on antecedent conditions. Since the runoff readiness of a catchment area changes during the course of a rainfall event due to soil moistening, the runoff coefficient is also adjusted during an event as a function of the cumulative precipitation amount.


Soil Moisture Simulation

Land Use

When using soil moisture simulation, it is necessary to specify the land use. From the information about land use, the rooting depth is needed to determine the thickness of the root layer. Further parameters of land use, which are used to calculate interception and transpiration, are

  • Root depth
  • Coverage
  • Annual pattern of coverage
  • Leaf area index
  • Annual pattern of the leaf area index

Haude factors entered as annual patterns can be assigned to each land use for a better consideration of the evaporation.


Soil Type / Soil Texture
Aggregation of soil layers to simulation layers
Datei:Schema Bodenfeuchtesimulation EN.png
Variables calculated with the soil moisture simulation

The soil moisture simulation is based on a non-linear calculation of the individual soil layers. The soil is divided into different layers. Each layer is calculated individually and inflows and outflows reconciled with the layers below or above (if present). The following physical soil parameters are used as parameters for the soil moisture calculation:

  • Wilting point (WP)
  • Field capacity (FC)
  • Total pore volume (TPV)
  • Saturated conductivity (kf value)
  • Maximum infiltration capacity (max. inf.)
  • Maximum rate of capillary suction (max. cap.)
  • Soil categorization: sand, silt, clay

The possible number of soil layers ranges from a minimum of one to a maximum of six. Experience has shown that the best results are achieved with a division into three layers. For this reason, the entered layers are always internally divided into three simulation layers:

  • Infiltration layer (standard thickness [cm] = 20)
  • Root layer (minimum thickness [cm] = 5)
  • Transport layer (minimum thickness [cm] = 5)

The calculation of soil properties for the simulation layers is done by weighting them according to the given original thicknesses of the layers. In case of saturated conductivity the calculation is based on the principle of maintaining the continuity of the flow. For vertical flow, the velocity v at a given flow rate in one simulation layer should have the same value due to the continuity of the flow. Thus, the hydraulic gradient is no longer constant.

[math]\displaystyle{ kf_V=\frac{\sum_{i=1}^n d_i}{\sum_{i=1}^n \frac{d_i}{k_i}} }[/math]

with:

[math]\displaystyle{ d_i }[/math]: proportional layer thickness of the respective original layer [mm]
[math]\displaystyle{ k_i }[/math]: saturated conductivity of the respective original layer [mm/h]
[math]\displaystyle{ kf_V }[/math]: saturated conductivity of the simulation layer [mm/h]
Schematic of calculation of the actual evapotranspiration

The water balance equation for a soil layer is solved on the basis of the piece-wise linear representation of the process functions which influence soil moisture: infiltration, current evaporation (evaporation + transpiration), percolation, interflow and capillary suction. The input variable for evaporation and transpiration is determined from the potential evaporation. The equation to be solved is:

[math]\displaystyle{ \frac{dBF(t)}{dt}=Inf(t)-Perk(t)-Eva_{akt}(t)-Trans_{akt}(t)-Int(t)+Kap(t) }[/math]

with:

[math]\displaystyle{ BF(t) }[/math]: current soil moisture
[math]\displaystyle{ Inf(t) }[/math]: infiltration into the soil
[math]\displaystyle{ Perk(t) }[/math]: percolation (seepage)
[math]\displaystyle{ Eva_{akt}(t) }[/math]: current evaporation
[math]\displaystyle{ Trans_{akt}(t) }[/math]: current transpiration
[math]\displaystyle{ Int(t) }[/math]: interflow
[math]\displaystyle{ Kap(t) }[/math]: capillary suction
Display of selected soil process functions

Infiltration, percolation, evaporation, transpiration, interflow and capillary suction depend on the current soil moisture. In the simulation, this dependence is described by the following functions.

[math]\displaystyle{ Inf(BF(t))=a_v \cdot \left(GPV-BF(t) \right)^{1.4}+k_f }[/math]           (Approach according to HOLTAN)

[math]\displaystyle{ Perk(BF(t)) = \begin{cases} 0, & BF(t)\le f_{PK} \cdot nFK + WP \\ k_f \cdot \left(\frac{BF(t)-(f_{PK} \cdot nFK +WP)}{GPV-(f_{PK} \cdot nFK +WP)} \right)^{exp,PK}, & BF(t)\gt f_{PK} \cdot nFK + WP \end{cases} }[/math]

(mod. approach according to /OSTROWSKI, 1992/)

[math]\displaystyle{ Eva(BF(t)) = \begin{cases} 0, & BF(t)\le WP \\ f_{Eva} \cdot \left(\frac{BF(t)-WP}{GPV-WP} \right)^{exp,PK}, & BF(t)\gt WP \end{cases} }[/math]

[math]\displaystyle{ Trans(BF(t)) = \begin{cases} 0, & BF(t)\le f_{Trans} \cdot nFK + WP \\ f_{Trans} \cdot \left(\frac{BF(t)-(f_{Trans} \cdot nFK +WP)}{GPV-(f_{Trans} \cdot nFK +WP)} \right)^{exp,PK}, & BF(t)\gt f_{Trans} \cdot nFK + WP \end{cases} }[/math]

with:

[math]\displaystyle{ a_v }[/math]: infiltration factor according to HOLTAN (in Talsim-NG [math]\displaystyle{ a_v=1 }[/math])
[math]\displaystyle{ k_f }[/math]: coefficient of conductivity of saturated soil
[math]\displaystyle{ nFK }[/math]: available water capacity ([math]\displaystyle{ nFK=FK-WP }[/math])
[math]\displaystyle{ WP }[/math]: wilting point
[math]\displaystyle{ FK }[/math]: field capacity
[math]\displaystyle{ GPV }[/math]: total pore volume
[math]\displaystyle{ f_{PK} }[/math]: soil-dependent scaling factor of the percolation function
[math]\displaystyle{ exp,PK }[/math]: soil-dependent curvature parameter of the percolation function
[math]\displaystyle{ f_{Eva} }[/math]: soil-dependent scaling factor of the evaporation function
[math]\displaystyle{ f_{Trans} }[/math]: soil-dependent scaling factor of the transpiration function
[math]\displaystyle{ exp,Trans }[/math]: curvature parameter of the transpiration function

These parameters are calculated internally. The user only has to specify the soil parameters kf, WP, FC and TPV. The soil processes is are solved using a component for the simulation of storage.


Hydrologic Response Units

When runoff generation is calculated using soil moisture simulation, the concept of hydrologic response units (HRUs) is applied. A catchment area is divided into a number of hydrologically homogeneous areas, i.e. areas of the same soil type and the same land use. For each hydrologic response unit there is exactly one assignment of land use and soil type. The discharge resulting from a hydrologic response unit is output from the sub-basin element to which the HRU belongs, i.e. all hydrologic response units release discharge with the same time delay, independent of their location within the sub-basin.


Runoff Concentration

Runoff concentration determines the delay of runoff from the catchment area. A parallel storage cascade with three reservoirs for permeable and one cascade for impermeable areas is used for surface runoff. The outflow of the components interflow and baseflow is output at the element outlet after passing through a single linear storage.

Calculation of the runoff concentration of catchment areas