Global ETD Search

1	Sensitivities of channel geometry compared to modeling assumptions in dam failure analysis Windham, Joseph Michael 10 December 2010 (has links) This research includes a sensitivity analysis of channel geometry and model assumptions in 1 dimensional (1D) dam break analysis. The specific modeling assumptions that are analyzed include, breach development time, breach width, and breach side-slopes. The question always arises when doing 1D dam break modeling of how detailed does the geometry data need to be to answer the subject question within an acceptable tolerance. LIDAR data and bathymetric data used for channel characteristic add significant detail to the model geometry as opposed to using course gridded data such as the USGS 10 meter Digital Elevation Models (DEMs). However, as geometry detail increases so does model development time, model run time, and cost to retrieve data. This research analyzes the level of error introduced in model results from accuracy of channel geometry as compared to the level of error introduced from assumption made in breach characteristic. Hydraulic Modeling
2	Making the Case for Tailored Stormwater Management Hixon, Lee Franklin 14 December 2009 (has links) Protection of downstream channels and reduction in flooding can potentially be improved by evaluating alternative site stormwater management (SWM) strategies at a watershed scale and selecting the optimal strategy for a subject watershed. Tailoring a management strategy for a specific watershed may be worthwhile to minimize development costs and maximize downstream benefit. A hydrologic/hydraulic model for a watershed in Blacksburg, Virginia, is used to evaluate downstream results based on implementation of several alternative SWM strategies currently practiced within the United States. Results show none of the strategies meet the goal of maintaining the baseline goal at the watershed POI for the full range of design storms. Modification to the strategy that performs best at the watershed scale did meet the watershed goal for all design storms except the 1-year. For smaller storm events, it appears that increasing the volume of an initial capture and the drawdown time to release that volume does not increase performance downstream. This is potentially significant as extra dollars spent on site would not provide extra benefit downstream. When post-development peak runoff rates are detained to the predevelopment rate for larger storm events, whether based on a site or watershed focused strategy, the watershed goal can be met. A volume reduction strategy performs well, but implementation is hindered by soils with poor infiltration and the presence of karst. Other insight to watershed based management strategies, the role of regional facilities and predevelopment condition assumptions at the site scale to maintain a baseline condition downstream are discussed. / Master of Science Hydrologic/hydraulic modeling urban stormwater management
3	Analysis and Prediction of Rainfall and Storm Surge Interactions in the Clear Creek Watershed using Unsteady-State HEC-RAS Hydraulic Modeling Winter, Heather 06 September 2012 (has links) This study presents an unsteady-state hydraulic model analysis of hurricane storm surge and rainfall-runoff interactions in the Clear Creek Watershed, a basin draining into Galveston Bay and vulnerable to flooding from both intense local rainfalls and storm surge. Storm surge and rainfall-runoff have historically been modeled separately, and thus the linkage and interactions between the two during a hurricane are not completely understood. This study simulates the two processes simultaneously by using storm surge stage hydrographs as boundary conditions in the Hydrologic Engineering Center’s – River Analysis System (HEC-RAS) hydraulic model. Storm surge hydrographs for a severe hurricane were generated in the Advanced Circulation Model for Oceanic, Coastal, and Estuarine Waters (ADCIRC) model to predict the flooding that could be caused by a worst-case scenario. Using this scenario, zones have been identified to represent areas in the Clear Creek Watershed vulnerable to flooding from storm surge, rainfall, or both. Storm Surge Rainfall Runoff Hazard Zones Unsteady-State Hydraulic Modeling
4	PREDICTING THE LOCATION AND DURATION OF TRANSIENT INDUCED LOW OR NEGATIVE PRESSURES WITHIN A LARGE WATER DISTRIBUTION SYSTEM Svindland, Richard C. 01 January 2005 (has links) Surge modeling is a tool used by engineers and utility owners in determining the surge pressures or transients that may result from routine pump and valve operations. Recent surge modeling work has focused on low and/or negative pressures within water distribution systems and how those occurrences could lead to intrusions. Effective surge modeling is needed in order to determine if the intrusion potential exists and what mitigation is needed to prevent intrusions. This work focuses on the generally unexplored area of using surge models to predict the location and duration of transient induced low and/or negative pressures within large complex water distribution systems. The studied system serves 350,000 people in the southeast United States, has 65 MGD of pumping capacity at two treatment plants, over 1500 miles of main and 12 storage tanks. This work focuses on the correlation between field data and the surge model using the author's extensive operational knowledge of the system, access to real-time SCADA data, and different celerity or wave speed values. This work also traces the steps taken by the author to locate areas within the system that experienced transient induced low and / or negative pressure.
5	Modélisation physique et numérique des écoulements générés par la formation de brèche dans les digues fluviales soumises aux surverses / Physical and numerical modeling of dike-breach induced flows due to overtopping Rifai, Ismail 24 May 2018 (has links) La surverse d’une digue fluviale (levée) peut conduire au développement d’une brèche par érosion externe, suivie d’une rupture brutale de la digue. Cela provoquerait une vague de submersion dans la plaine protégée, laquelle peut présenter des enjeux humains, économiques et financiers majeurs. La gestion et la prévention du risque d’inondation passe par une détermination précise de l’aléa. Pour ce faire, il est nécessaire d’avoir une estimation fiable du débit au travers de la brèche, donc du mécanisme de formation de la brèche et de sa dynamique d’expansion. Les approches existantes sont souvent adaptées pour les digues frontales (barrage et remblai en terre) soumises aux surverses. La transposition de ces approches pour les digues fluviales demeure peu fiable. Les processus qui régissent la formation des brèches dans les digues fluviales restent donc encore du domaine de la recherche. Un programme expérimental visant à améliorer notre compréhension des processus physiques qui régissent la rupture graduelle des digues fluviales par surverse a été mené conjointement par le Laboratoire National d’Hydraulique et Environnement (LNHE) de la division R&D d’EDF et le groupe de recherche Hydraulics in Environmental and Civil Engineering (HECE) de l’Université de Liège. Les travaux ont été conduits sur deux dispositifs expérimentaux distincts, chacun constitué d’un canal principal et d’une plaine d’inondation, séparés par une digue fluviale. Nous nous sommes focalisés sur les surverses localisées de digues homogènes non-cohésives. Une métrologie adaptée, incluant la mesure détaillée de l’évolution de la géométrie de la brèche en continu, par une technique non intrusive (profilométrie laser), a été développée et exploitée dans les travaux de cette thèse. Les tests, réalisés sous conditions contrôlées, ont permis d’investiguer l’évolution de la bèche et des débits sortants pour différentes conditions hydrauliques (débits d’entrée dansle canal principal, régulation du débit sortant en aval du canal principal, confinement de la plaine inondable). Les effets des dimensions du canal principal, de la taille des sédiments et de la cohésion apparente ou encore de la mobilité des fonds au pied de la digue ont fait également l’objet d’étude. En exploitant les mesures, l’évolution des écoulements au voisinage de la brèche a été simulée avec le code de calcul bidimensionnel TELEMAC-2D, permettant d’évaluer les performances de ce code pour des cas d’écoulements, en rupture de digue fluviale, hautement transitoires et complexes. Le couplage avec le code morpho dynamique 2-D SISYPHE a permis d’apprécier l’apport d’une modélisation hydro-morpho dynamique détaillée à l’étude des brèches dans les digues fluviales / Overtopping of fluvial dikes (dykes or embankment levees) can promote external erosion, leading to the initiation of breaching and potentially brutal dike failure and inundation of the protected area. This can generate major human, economic, and financial losses. Flood risk management and prevention require precise hazard quantification. Accurate estimate of the flow through the breach is paramount, for which a precise understanding of the breach formation and expansion is required. Existing methods are often the result of investigations conducted on overtopping of frontal dikes (embankment dams). The application of such approaches to fluvial dikes is not reliable and processes underpinning breach expansion are still under research. An innovative experimental program was conducted to fill this gap by investigating the physical processes involved in overtopping induced fluvial dike gradual breaching. Experiments were conducted in the framework of collaboration between the National Laboratory for Hydraulics and Environment (LNHE) of the R&D division of EDF and the research team Hydraulics in Environmental and Civil Engineering (HECE) of University of Liège. Experiments were conducted on two distinct experimental setups, each consisting of a main channel and floodplain area separated by an erodible fluvial dike. The focus was made on overtopping induced spatial erosion of homogenous, non-cohesive dikes. Measurements included continuous scanning of the dike geometry using a non-intrusive method (Laser Profilometry Technique), which was designed and developed specifically for the present works. Tests conducted under controlled flow and dike configurations allowed assessing the effects of channel inflow discharge, downstream channel regulation system, and floodplain confinement on the breach development and outflow. Effects of main channel size, dike material size, apparent cohesion, and bottom erodibility were studied as well. Using the experimental data, the flow features near the breach area was simulated using the two-dimensional depth-averaged hydrodynamic code TELEMAC-2D, which allowed assessing the performance of the code for highly transient and complex flows such as involved in dike breaching. Coupling TELEMAC-2D with the morphodynamic model SISYPHE enabled investigating the interest of a detailed hydro-morphodynamic modeling for fluvial dike breaching studies Rupture de digue Modélisation hydraulique Suverses Dike breach Hydraulic modeling Overtopping
6	USE OF UNSTEADY MODELING TO PREDICT FLOODING BY CORRELATING STREAM GAGES: A CASE STUDY Burke, Michael John 01 August 2011 (has links) Scientific studies have suggested an increase in the frequency and intensity of flooding. The research presented herein is focused on a small watershed, which has experienced intense flooding of a downstream, urbanized area. For emergency response and preparedness, it is pertinent to have the ability to predict intensity and peak flows of a flood. The Town of Dyer, Indiana has been severely impacted by flooding in the last twenty years. A 37.6 square mile watershed begins in a rural section of Illinois with tributaries draining into Plum Creek. The creek crosses into Indiana and becomes Hart Ditch, a straight, narrow, deep channel through the urbanized Town of Dyer. A HEC-HMS hydrologic model was used and calibrated based on USGS gage data. Storm events ranging from short, high intensity to long, intermittent precipitation provided a vast representation of possible scenarios within the watershed. The hydrologic model was paired with an unsteady HEC-RAS hydraulic model to allow for different lateral inflows to the creek providing variations of flow. A comparison between upstream and downstream stream gage readings was utilized to create a working model that predicts downstream water surface elevations for previous real-time storm and hypothetical storms. These conditions were analyzed by two stream gages and a correlation between the two gages was developed. This correlation was used to predict downstream water surface elevations. The correlation was also used to determine the time to crest based on readings at the upstream gage for many different storm events. The ability to know downstream water surface elevations for real-time storm events allows a window of time to implement emergency response in areas where flooding is imminent. The downstream area of concern has known flood elevations that represent various damage levels. Correlation Flooding Hydraulic Modeling Hydrologic Modeling Stream Gage
7	Python Tools to Aid and Improve Rapid Hydrologic and Hydraulic Modeling with the Automated Geospatial Watershed Assessment Tool (AGWA) Barlow, Jane E., Barlow, Jane E. January 2017 (has links) Hydrologic and hydraulic modeling are used to assess watershed function at different spatial and temporal scales. Many tools have been developed to make these types of models more accessible to use and model results easier to interpret. One tool that makes hydrologic models more accessible in a geographic information system (GIS) is the Automated Geospatial Watershed Assessment tool (AGWA); the GIS enables the development of spatially variable model inputs and model results for a variety of applications. Two major applications of AGWA are for rangeland watershed assessments and post-wildfire rapid watershed assessments. Each of these applications have primarily utilized the Kinematic Runoff and Erosion model (KINEROS2) which is accessible in AGWA. Two new tools were developed which work within the existing AGWA/KINEROS2 framework in ArcGIS to enhance rangeland and post-wildfire watershed assessments. The Storage Characterization Tool, was developed to work with high-resolution topographic data to characterize existing stock ponds so these features can easily be incorporated into AGWA/KINEROS2 for rangeland hydrologic analysis. The second tool simulates reach scale flood inundation (the Inundation Tool) utilizing AGWA/KINEROS2 outputs and local channel properties for Hydrologic Engineering Center (HEC-2) hydraulic calculations to compute flood inundation in post-wildfire environments. Both tools have been validated using multiple datasets and desired applications were outlined so that the tools are properly used. Hydraulic Modeling Hydrologic Modeling Inundation Ponds Storage Fire
8	Flood Capacity Improvement of San Jose Creek Channel Using HEC-RAS Mowinckel, Erland Kragh 01 June 2011 (has links) The Santa Ynez Mountains of Santa Barbara County, California, have seen many major storm events during the past century. San Jose Creek, which runs out of these mountains, through the town of Goleta, and into the Pacific Ocean, has experienced several intense flood events as a result. The lower portion of the creek was diverted in 1960 to alleviate flooding through Old Town Goleta. However, flooding still occurred in the storms of 1995 and 1998. This study incorporates a hydraulic analysis component of a project aimed at re-designing this diverted portion of the channel. It presents an analysis of modifications to this reach in order to improve its capacity and reduce flooding during a 100-year event. As one of the most prominent software for hydraulic modeling for steady and unsteady state open channel flow, HEC-RAS is used to analyze multiple variations in channel geometry and combinations of lining materials. Of these modifications, the best configuration is suggested. HEC-RAS hydraulic modeling open channel flow 100-year flood
9	Drainage hydraulics of porous pavement : coupling surface and subsurface flow Eck, Bradley Joseph 06 October 2010 (has links) Permeable friction course (PFC) is a porous asphalt pavement placed on top of a regular impermeable roadway. Under small rainfall intensities, drainage is contained within the PFC layer; but, under higher rainfall intensities drainage occurs both within and on top of the porous pavement. This dissertation develops a computer model—the permeable friction course drainage code (PERFCODE)—to study this two-dimensional unsteady drainage process. Given a hyetograph, geometric information, and hydraulic properties, the model predicts the variation of water depth within and on top of the PFC layer through time. The porous layer is treated as an unconfined aquifer of variable saturated thickness using Darcy’s law and the Dupuit-Forchheimer assumptions. Surface flow is modeled using the diffusion wave approximation to the Saint-Venant equations. A mass balance approach is used to couple the surface and subsurface phases. Straight and curved roadway geometries are accommodated via a curvilinear grid. The model is validated using steady state solutions that were obtained independently. PERFCODE was applied to a field monitoring site near Austin, Texas and hydrographs predicted by the model were consistent with field measurements. For a sample storm studied in detail, PFC reduced the duration of sheet flow conditions by 80%. The model may be used to improve the drainage design of PFC roadways. / text Porous pavement Permeable friction course Dupuit-Forchheimer Sheet flow Diffusion wave Hydraulic modeling Highway drainage
10	Modeling rating curves from close-range remote sensing data : Application of laser and acoustic ranging instruments for capturing stream channel topography Lam, Norris January 2017 (has links) A rating curve provides a functional relationship between water height (i.e. stage) and discharge at a specified cross-section in a river. Used in combination with a time series of stage, rating curves become one of the central components for generating continuous records of streamflow. Since developing and maintaining rating curves can be time consuming, hydraulic models have shown potential to reduce the effort required for developing rating curves. A central challenge with modeling procedures, however, is the acquisition of accurate stream channel and floodplain topography. From this perspective, this thesis focuses on the real-world application of close-range remote sensing techniques such as laser-based ranging technologies (i.e. Light detection and ranging or LiDAR) or acoustic based ranging technologies (i.e. acoustic Doppler current profiler or ADCP) to capture topographic information for hydraulic modeling applications across various spatial scales. First, a review of the current LiDAR literature was carried out to identify potential ways to take full advantage of these novel data and technologies in the future. This was followed by four interconnected studies whereby: (i) a low-cost custom laser scanning system was designed to capture grain size distributions for a small stream; (ii) synthetically thinned airborne laser scanning (ALS) data was applied in a physically-based hydraulic modelling framework to develop rating curves; (iii) low-resolution national-scale ALS was coupled with ADCP bathymetry to be used in conjunction with a hydraulic model to develop rating curves; and (iv) the impact of measurement uncertainties on generating rating curves with a hydraulic model were investigated. This thesis highlights the potential of close-range remote sensing techniques for capturing accurate stream channel topography and derive from these data, the necessary parameters required for hydraulic modeling applications. / En avbördningskurva tillhandahåller ett funktionellt förhållande mellan vattendjup (dvs. vattenstånd) och flöde vid ett specifikt tvärsnitt i ett vattendrag. Avbördningskurvan blir en central komponent för generering av kontinuerliga tidsserier av vattenföring från tidsserier av vattenstånd. Eftersom det är tidskrävande att utveckla och underhålla avbördningskurvor erbjuder hydrauliska modeller attraktiva möjligheter att minska den insats som krävs för att utveckla avbördningskurvorna. En central utmaning för sådana modelleringsförfaranden är emellertid tillgången till noggrann topografidata av strömfåran och de omgivande stränderna. Den här avhandlingen fokuserar på tillämpningen av fjärranalystekniker för avståndsmätning på nära håll, såsom laserbaserade teknik (dvs. Light detection and ranging eller LiDAR) och akustisk baserat teknik (dvs. acoustic Doppler current profiler eller ADCP), för att fånga topografisk information för hydraulisk modellering av vattendrag i olika rumsliga skalor. Först presenteras en litteraturstudie av den nuvarande LiDAR-litteratur för att identifiera potentiella sätt att dra full nytta av dessa nya data och tekniker i framtiden. Detta följs av fyra sammanlänkade studier: (i) tillämpning av ett lågkostnads-laseravsökningssystem för att fånga kornstorleksfördelningar i ett litet vattendrag, (ii) syntetiskt förtunnad flygburen laserskanningsdata (ALS) applicerad i en fysiskt baserad hydraulisk modell för att utveckla avbördningskurvor, (iii) lågupplösta ALS från Svensk nationell höjdmodell kopplade med ADCP-batymetri för att ta fram en avbördningskurva med en hydraulisk modell, och (iv) undersökning av effekterna av osäkerheter på mätdata för att generera avbördningskurvor med en hydraulisk modell. Denna avhandling belyser potentialen för fjärranalystekniker för avståndsmätning på nära håll, för att fånga strömfårans exakta topografi och ifrån dessa data härleda de parametrar som krävs för hydrauliska modelleringstillämpningar. / <p>At the time of the doctoral defense, the following paper was unpublished and had a status as follows: Paper 5: Manuscript.</p> laser scanning acoustic Doppler current profiler hydraulic modeling rating curves Sweden Physical Geography Fysisk geografi

Search results