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Calibration and Verification of a 2D Hydrodynamic Model for Simulating Flow around Emergent Bendway Weir Structures |
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| Authors: | A N Papanicolaou Mohamed Elhakeem Brian Wardman |
| Affiliation: | 1Professor and Donald E. Bently Faculty Fellow of Engineering, IIHR-Hydroscience and Engineering, Dept. of Civil and Environmental Engineering, The Univ. of Iowa, 100 C. Maxwell Stanley Hydraulics Laboratory, Iowa City, IA 52242 (corresponding author). E-mail: apapanic@engineering.uiowa.edu 2Assistant Professor, Department of Civil Engineering, College of Engineering and Computer Science, Abu Dhabi Univ., Abu Dhabi, 59911, UAE. E-mail: Mohamed.Elhakeem@adu.ac.ae 3Engineer, Northwest Hydraulic Consultants, 3950 Industrial Blvd., Suite 100-C, West Sacramento, CA 95691. E-mail: bwardman@nhc-sac.com |
| Abstract: | The predictive capability of a two-dimensional (2D)-hydrodynamic model, the finite-element surface water modeling system (FESWMS), to describe adequately the flow characteristics around emergent bendway weir structures was evaluated. To examine FESWMS predictive capability, a sensitivity analysis was performed to identify the flow conditions and locations within the modeled reach, where FESWMS inputs for Manning’s n and eddy viscosity must be spatially distributed for to better represent the river bed flow roughness characteristics and regions where the flow is highly turbulent in nature. The sensitivity analysis showed that high flow conditions masked the impact of Manning’s n and eddy viscosity on the model outputs. Therefore, the model was calibrated under low flow conditions when the structures were emergent and had the largest impact on the flow pattern and model inputs. Detailed field measurements were performed under low flow conditions at the Raccoon River, Iowa for model calibration and verification. The model predictions were examined for both spatially averaged and distributed Manning’s n and eddy viscosity model input values within the study reach for an array of emergent structures. Spatially averaged model inputs for Manning’s n and eddy viscosity provided satisfactory flow depth predictions but poor velocity predictions. Estimated errors in the predicted values were less than 10% for flow depth and about 60% for flow velocity. Distributed Manning’s n and eddy viscosity model inputs, on the contrary, provided both satisfactory flow depth and velocity predictions. Further, distributed inputs were able to mimic closely the recirculation flow pattern in the wake region behind the bendway weir structures. Estimated errors in the predicted values were less than 10 and 25% for flow depth and velocity, respectively. Overall, in the case of distributed model inputs, FESWMS provided satisfactory results and allowed a closed depiction of the flow patterns around the emergent bendway weirs. These findings suggest that 2D models with spatially distributed values for Manning’s n and eddy viscosity can adequately replicate the velocity vector field around emergent structures and can be valuable tools to river managers, except in cases when detailed three-dimensional flow patterns are needed. The study was limited to the examined low flow conditions, and more field data, especially under high flow conditions, are necessary to generalize the findings of this study regarding the model prediction capabilities. |
| Keywords: | Hydrodynamics Hydrologic models Calibration Verification Errors Surface water Weirs |