Flussgebietsmodell/en: Unterschied zwischen den Versionen
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In water resources planning, model technology has long been of great importance. Hydrological and hydraulic models are used because both the benefits and possible negative consequences of measures or changes are not easy to anticipate due to the often complex interactions. Models can determine both the short and long-term effects of meausres and changes on the water balance. The models must be able to reproduce and accurately simulate structural changes and operational aspects, and the results must be presented clearly. Of particular importance is the consideration of entire river basins, not only in order to comply with EU Water Framework Directive. | In water resources planning, model technology has long been of great importance. Hydrological and hydraulic models are used because both the benefits and possible negative consequences of measures or changes are not easy to anticipate due to the often complex interactions. Models can determine both the short and long-term effects of meausres and changes on the water balance. The models must be able to reproduce and accurately simulate structural changes and operational aspects, and the results must be presented clearly. Of particular importance is the consideration of entire river basins, not only in order to comply with EU Water Framework Directive. | ||
A | A pure rainfall-runoff model is often not sufficient to represent an entire river basin with all its complex interactions. A river basin model should provide the possibility to model water resources infrastructure such as dams, canals and diversions, as well as their operation, i.e. the control and regulation of the structures. The modeling of water quality parameters is also becoming increasingly important. | ||
Talsim-NG | Talsim-NG combines all of the following: | ||
*[[Special:MyLanguage/Niederschlag-Abfluss-Modell|Rainfall-runoff model]] | *[[Special:MyLanguage/Niederschlag-Abfluss-Modell|Rainfall-runoff model]] | ||
*[[Special:MyLanguage/Fließgewässerberechnung|Flow routing]] | *[[Special:MyLanguage/Fließgewässerberechnung|Flow routing]] | ||
*[[Special:MyLanguage/Wasserinfrastruktur|Water infrastructure]] | *[[Special:MyLanguage/Wasserinfrastruktur|Water infrastructure]] | ||
*[[Special:MyLanguage/Bewirtschaftungsmodell| | *[[Special:MyLanguage/Bewirtschaftungsmodell|Operation model]] | ||
*[[Special:MyLanguage/Wassergütemodell|Water quality model]] | *[[Special:MyLanguage/Wassergütemodell|Water quality model]] | ||
Aktuelle Version vom 25. November 2020, 17:18 Uhr
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In water resources planning, model technology has long been of great importance. Hydrological and hydraulic models are used because both the benefits and possible negative consequences of measures or changes are not easy to anticipate due to the often complex interactions. Models can determine both the short and long-term effects of meausres and changes on the water balance. The models must be able to reproduce and accurately simulate structural changes and operational aspects, and the results must be presented clearly. Of particular importance is the consideration of entire river basins, not only in order to comply with EU Water Framework Directive.
A pure rainfall-runoff model is often not sufficient to represent an entire river basin with all its complex interactions. A river basin model should provide the possibility to model water resources infrastructure such as dams, canals and diversions, as well as their operation, i.e. the control and regulation of the structures. The modeling of water quality parameters is also becoming increasingly important.
Talsim-NG combines all of the following: