Modeling Of The Flood Regimes In Coupled Stream-aquifer Systems

Korkmaz, Serdar

01 December 2007

In this study, hydrogeological modeling of the Somme river basin situated in the north of France was made with special emphasis on the stream-aquifer interaction. The coupled model developed at Ecole des Mines de Paris was used. Geographic Information Systems (GIS) tools were incorporated during all the stages of modeling process for both preparation of input data and visualization of the results of simulations. Initially, the process began with Digital Elevation Model (DEM) analysis. Afterwards, the surface and aquifer grids were generated by using nested grid generators and refinement was made on the stream network and subcatchment boundaries in order to increase the accuracy of numerical solution. In order to run the surface model, meteorological forcing, land use and soil type data were acquired. Surface model was used to partition the precipitation into evapotranspiration, infiltration and surface runoff components. A steady-state piezometric head distribution was computed by the groundwater model to serve as an initial condition to the coupled model. The flow in the unsaturated zone was simulated by using Nash cascade model. The unsteady groundwater and surface flow simulations were performed by taking into consideration the stream-aquifer interaction on a daily time step. The calibration and validation were realized by using the streamflow and piezometric head measurements distributed around the basin. The strong groundwater influence on the hydrology of the basin is well represented by the model. Comparisons of predicted flooded areas in year 2001 were made with other models and a satellite derived image. In the end, several sensitivity analyses were performed for several parameters concerning the groundwater flow.

TC Hydraulic Engineering 1-978

Determination Of Hydraulic Parameters Of Semi-infinite Aquifers Using Marquardt Algorithm

Taskan, Cuneyt

01 January 2004

In this study, transmissivity and storage coefficient of a semi-infinite, confined, homogeneous and isotropic aquifer, where the flow is one-dimensional and linear, are determined using Marquardt algorithm, considering two independent cases: constant drawdown in the adjacent stream / or constant discharge from the aquifer due to pumping at a constant rate. In the first case piezometric head and discharge measurements are utilized. Hydraulic diffusivity, which is the ratio of transmissivity to storage coefficient, is determined from piezometric head measurements / whereas their product is determined from discharge measurements. Then, the two parameters are calculated easily. In the second case piezometric head observations are utilized only and transmissivity and storage coefficient are determined simultaneously. Convergence to true values is very fast for both cases even for poor initial estimates. Three examples, two using synthetic data for both cases and one using actual field data for the second case, are presented. Conventional type-curve matching method is used for comparison of the results. It is observed that the results of Marquardt algorithm are in a reasonable agreement with those of type-curve matching method.

TC Hydraulic Engineering 1-978

Modelo empírico linear para previsão da disponibilidade hídrica integrada em função da média móvel da precipitação / Empirical linear model for water availability forecast as a function of the rainfall moving average

Gómez García, Derly Estefanny

30 June 2016

Variações climáticas podem resultar na entrada insuficiente de água no balanço hídrico de uma região, acarretando em inconsistências relacionadas à outorga de água superficial. O sistema de outorga de água superficial utiliza as vazões percentis (Q7,10, Q90, Q95) para definir a vazão máxima outorgável. No entanto, em períodos de estiagem tais vazões de referência podem não ser suficientes para atender a demanda outorgada, demandando a captação de águas subterrâneas para contrabalançar essa insuficiência hídrica do manancial superficial. Portanto, a outorga dos recursos hídricos deve ocorrer de forma integrada e sustentável, considerando a alteração da descarga do aquífero para o rio devido à captação subterrânea. O objetivo deste trabalho é estimar a disponibilidade hídrica integrada (superficial e subterrânea), por meio de um modelo empírico linear, proposto como função da média móvel da precipitação de períodos anteriores relacionados ao tempo de regulação do aquífero. Técnicas de correlação e espectrais foram empregadas na análise de séries temporais de precipitação (P) e vazão (Q) da bacia hidrográfica do Ribeirão da Onça, com o objetivo de determinar os tempos de resposta de Q em relação a P. A metodologia proposta foi verificada para precipitação e vazões observadas na bacia com área de 65 km2 no período de 2003 a 2014. Os resultados indicam que o aquífero armazena uma parcela de água precipitada e controla o fluxo para o rio, com tempos de regulação de aproximadamente 60 dias para o escoamento subsuperficial e de aproximadamente 2 anos para o escoamento de base. A metodologia também foi testada para duas sub-bacias hidrográficas do Rio Jacaré-Guaçu, com áreas de 1867 e 3519 km2. A adoção da metodologia proposta permite calcular uma vazão de referência sustentável, possibilitando prever a variação da vazão de base nos períodos de recessão, por estar definida em função de precipitações passadas. Portanto, tal vazão seria mais condizente com as observadas no meio ambiente, proporcionando um adequado funcionamento do ecossistema, garantindo assim a sua preservação. / Climatic variation may result in insufficient input of water in the water balance in a region, resulting in inconsistencies in the water rights permits. Brazilian water allocation system uses the flow duration curves (Q7,10, Q90, Q95) to establish the maximum allowable discharge. However, during droughts such reference discharges may not reach the water rights permits, requiring groundwater extraction to compensate this deficiency in surface water bodies. Hence, the water right permits must be integral, considering the base flow variation due to the groundwater extraction. The aim of this study is to determine the integrated water availability (surface and groundwater), using an empirical linear model, proposed as a function of the average rainfall of previous periods related to the aquifer regulation time. Correlation and spectral techniques were employed for time-series analysis of precipitation (P) and discharge (Q) in the Ribeirão da Onça watershed, to determine response times of Q as a function of P. The proposed methodology was developed for precipitation and discharge observed from 2003 to 2014 in a watershed with an area of 65 km2. The obtained results indicate that the aquifer stores the rainfall water with regulation times of approximately 60 days for the subsurface flow, ans approximately 2 years for the base flow. The methodology was also tested for two sub-basins of the Jacaré-Guaçú River watershed, with areas of 1867 and 3519 km2.The proposed methodology allows the estimation of a sustainable reference discharge making it possible to predict the base flow variation during recession periods, since it is defined as a function of past rainfall. Therefore, this discharge is more consistent with the values observed in the environment, allowing a proper functioning of the ecosystem, thereby ensuring their preservation.

Análise de séries temporais

Análise espectral

Correlação

Correlation

Gestão integrada de recursos hídricos

Integrated water resources planning

Interação Rio-Aquífero

Spectral analysis

Stream-Aquifer interaction

Time series analysis

Vazão sustentável

Water sustainability

Wavelet

Wavelet

Modelo empírico linear para previsão da disponibilidade hídrica integrada em função da média móvel da precipitação / Empirical linear model for water availability forecast as a function of the rainfall moving average

Derly Estefanny Gómez García

30 June 2016

Variações climáticas podem resultar na entrada insuficiente de água no balanço hídrico de uma região, acarretando em inconsistências relacionadas à outorga de água superficial. O sistema de outorga de água superficial utiliza as vazões percentis (Q7,10, Q90, Q95) para definir a vazão máxima outorgável. No entanto, em períodos de estiagem tais vazões de referência podem não ser suficientes para atender a demanda outorgada, demandando a captação de águas subterrâneas para contrabalançar essa insuficiência hídrica do manancial superficial. Portanto, a outorga dos recursos hídricos deve ocorrer de forma integrada e sustentável, considerando a alteração da descarga do aquífero para o rio devido à captação subterrânea. O objetivo deste trabalho é estimar a disponibilidade hídrica integrada (superficial e subterrânea), por meio de um modelo empírico linear, proposto como função da média móvel da precipitação de períodos anteriores relacionados ao tempo de regulação do aquífero. Técnicas de correlação e espectrais foram empregadas na análise de séries temporais de precipitação (P) e vazão (Q) da bacia hidrográfica do Ribeirão da Onça, com o objetivo de determinar os tempos de resposta de Q em relação a P. A metodologia proposta foi verificada para precipitação e vazões observadas na bacia com área de 65 km2 no período de 2003 a 2014. Os resultados indicam que o aquífero armazena uma parcela de água precipitada e controla o fluxo para o rio, com tempos de regulação de aproximadamente 60 dias para o escoamento subsuperficial e de aproximadamente 2 anos para o escoamento de base. A metodologia também foi testada para duas sub-bacias hidrográficas do Rio Jacaré-Guaçu, com áreas de 1867 e 3519 km2. A adoção da metodologia proposta permite calcular uma vazão de referência sustentável, possibilitando prever a variação da vazão de base nos períodos de recessão, por estar definida em função de precipitações passadas. Portanto, tal vazão seria mais condizente com as observadas no meio ambiente, proporcionando um adequado funcionamento do ecossistema, garantindo assim a sua preservação. / Climatic variation may result in insufficient input of water in the water balance in a region, resulting in inconsistencies in the water rights permits. Brazilian water allocation system uses the flow duration curves (Q7,10, Q90, Q95) to establish the maximum allowable discharge. However, during droughts such reference discharges may not reach the water rights permits, requiring groundwater extraction to compensate this deficiency in surface water bodies. Hence, the water right permits must be integral, considering the base flow variation due to the groundwater extraction. The aim of this study is to determine the integrated water availability (surface and groundwater), using an empirical linear model, proposed as a function of the average rainfall of previous periods related to the aquifer regulation time. Correlation and spectral techniques were employed for time-series analysis of precipitation (P) and discharge (Q) in the Ribeirão da Onça watershed, to determine response times of Q as a function of P. The proposed methodology was developed for precipitation and discharge observed from 2003 to 2014 in a watershed with an area of 65 km2. The obtained results indicate that the aquifer stores the rainfall water with regulation times of approximately 60 days for the subsurface flow, ans approximately 2 years for the base flow. The methodology was also tested for two sub-basins of the Jacaré-Guaçú River watershed, with areas of 1867 and 3519 km2.The proposed methodology allows the estimation of a sustainable reference discharge making it possible to predict the base flow variation during recession periods, since it is defined as a function of past rainfall. Therefore, this discharge is more consistent with the values observed in the environment, allowing a proper functioning of the ecosystem, thereby ensuring their preservation.

Análise de séries temporais

Análise espectral

Correlação

Gestão integrada de recursos hídricos

Interação Rio-Aquífero

Vazão sustentável

Wavelet

Correlation

Integrated water resources planning

Spectral analysis

Stream-Aquifer interaction

Time series analysis

Water sustainability

Wavelet