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Modeling Reallocation of Reservoir Storage Capacity Between Flood Control and Conservation PurposesKim, Tae Jin 2009 May 1900 (has links)
Interest in converting portions of the large volumes of flood control storage
capacity in federal multiple-purpose reservoirs in Texas and elsewhere to water supply
and other conservation purposes has been growing for some time. Evaluation of storage
reallocations involving tradeoffs between flood control and conservation purposes in
multiple-purpose, multiple-reservoir systems represents a new area for applying the
Water Rights Analysis Package (WRAP) and Texas Water Availability Modeling
(WAM) System. A system of 12 multiple-purpose reservoirs operated by the U.S. Army
Corps of Engineers (USACE) and Brazos River Authority (BRA) was adopted as a case
study in this research to develop and test expanded WRAP/WAM-based methods for
analyzing modifications in reservoir storage allocations and related system operations.
The research consisted of the following tasks:
? The Brazos River Basin WRAP input dataset from the Texas WAM System (Brazos
WAM) has a 1940-1997 hydrologic period-of-analysis. The research included
developing and applying methods to extend the period-of-analysis to 1900-2007
providing a better representation of river basin hydrology. The methodology
developed could potentially be used to update the other river basin datasets in the
statewide WAM System.
? The Brazos WAM has 3,830 control points, 670 reservoirs, and hundreds of water
rights. The research included developing and applying methods to create a much easier-to-apply condensed dataset focused on the USACE/BRA reservoir system and
associated water rights that have only 48 control points and 14 reservoirs.
? The WRAP/WAM System was developed based on a monthly computational time
step. The research included applying developmental methodologies for converting a
monthly model to a daily time step that includes disaggregation of monthly
naturalized flows to daily flows, calibration of flow routing coefficients, and
incorporation of forecasting in the simulation.
? The WRAP/WAM System is designed for assessing water supply reliabilities and
stream flow and storage frequencies from the perspective of conservative purposes.
The research added flood risk indices to the WRAP modeling system in order to
address tradeoffs between flood control and conservation purposes.
? The WRAP/WAM-based simulation study performed with the modified WAM
dataset developed in this research demonstrates the improvements in water supply
capabilities and tradeoffs with flood control associated with various reservoir storage
reallocation strategies and other modifications in reservoir system operations.
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Water impacts on thermoelectric power generationStillwell, Ashlynn Suzanne 06 November 2013 (has links)
The energy-water nexus represents a complex system of correlated resources, with particular relevance to thermoelectric power plants. Since thermoelectric power plants typically depend on water for cooling, these facilities are prone to water-related challenges. At the same time, large water withdrawals for power plants can adversely impact other water users in a watershed. This work aims to evaluate water impacts on Texas power plant operations and the associated effects these power plants have on water availability. An evaluation of the water impacts on power generation in Texas was completed through four analyses: 1) water availability effects of changing cooling technologies, 2) economic value of drought resiliency through use of alternative cooling technologies, 3) dynamic impacts of reservoir storage on power generation operations, and 4) potential for reclaimed water as a cooling source. Based on the results of these analyses, the following general conclusions were drawn [bulleted list]: [bullet] Use of alternative cooling technologies decreases water withdrawals at the expense of additional energy and water consumption. However, the reduced withdrawals for power plants leaves more water in the stream for other water users, including instream flows. [bullet] Alternative cooling technologies incur additional capital costs, but gain value from reduced water withdrawals. The lower withdrawal requirements make such facilities more resilient to drought, which can have economic value from additional generation during possible drought-related curtailment or suspension. [bullet] Changing surface water reservoir storage at power plants has dynamic impacts on power generation operations, as well as other users in a river basin. Generally, decreasing power plant reservoir storage benefits other users in the basin. Instances arise where both beneficial and detrimental impacts are also observed. [bullet] Reclaimed water can be a technologically and economically feasible cooling source for many existing power plants. The future suitability of using reclaimed water for power plant cooling depends on water pipeline construction costs, reclaimed water flow, and water stress [end of bulleted list]. These general conclusions, along with further details, provide insight into the relationship between water resources and thermoelectric power plants. As resources become increasingly strained, understanding and responding to tradeoffs within the energy-water nexus, through such analyses, might become imperative for sustainable resource management. / text
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Řízení zásobní funkce nádrže s využitím metod umělé inteligence / Management of water reservoir storage function using methods of artificial intelligenceUrbanec, Patrik January 2020 (has links)
The subject of this thesis is to control the storage function of the reservoir using artificial intelligence methods, including the construction of the appropriate control algorithm. The thesis is divided into the theoretical part and the part of the application of reservoir storage function control. The theoretical part describes the control algorithm and the prediction model. The following are basic optimization methods and artificial intelligence methods. The second part presents the historical data used for the prediction model. The following is a description of calibration and validation of the control module and evaluation of the application results. Finally, there is a comparison and summary of individual results, control algorithm and prediction model. According to the results, the control algorithm can be recommended for further investigation.
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Vodohospodářské řešení zásobního objemu nádrže Vranov / Water Management Analysis of Storage Capacity of the Vranov ReservoirVítková, Lucie January 2020 (has links)
The current persistent drought and changes in the climate system have raised water managers expert questions about how to manage water resources in the future. The manifestation of climate change in hydrological series and their influence on the magnitude of threats to the storage functions of reservoirs are more often investigated. Already today, long-term shortages of storage capacity in reservoirs lead to the introduction of special manipulations on water structures. The aim of the thesis is to perform the analysis of time series, respectively decomposition of hydrological series average annual and monthly discharges. Create extended hydrological bases using synthetic discharge series generators and develop a comprehensive analysis of storage volume without considering losses even with the introduction of losses from the water surface vapor in the UNCE RESERVOIR program. The created discharge series are compared and evaluated on the basis of statistical characteristics and reservoir storages results with the real discharge series. The practical app is conducted on the Vranov reservoir in the Dyje River Basin.
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Analýza nejistot hydrologických a provozních parametrů na vodohospodářské řešení zásobní funkce nádrže / Uncertainty Analysis of Hydrological and Operating Parameters on Water Management Analysis of Reservoir Storage CapacityPaseka, Stanislav January 2016 (has links)
The aim of the thesis is to introduce the concept of Monte Carlo method for incorporating the uncertainties into the all hydrological and operational data inputs, which are needed to design and operation of large open water reservoir. Incorporating uncertainties into data inputs during calculation of reservoir storage capacity, then the consequent active conservation storage capacity is loaded by uncertainties. In the same way the values of outflow water from reservoir and hydrological reliability are affected by these uncertainties as well. For these kind of calculations the reservoir simulation model has been used, which simulate behavior operation of reservoir and is able to evaluate the results of simulations and help to reduction risk of storage capacity failure, respectively reduction of water shortages during reservoirs operation during low water and dry periods.
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The Compartmented Reservoir: Efficient Water Storage in Flat Terrain Areas of ArizonaCluff, C. B. 15 April 1978 (has links)
From the Proceedings of the 1978 Meetings of the Arizona Section - American Water Resources Assn. and the Hydrology Section - Arizona Academy of Science - April 14-15, 1978, Flagstaff, Arizona / The compartmented reservoir is presented as an efficient method of storing water in areas of Arizona having a relatively flat terrain where there is a significant water loss through evaporation. The flat terrain makes it difficult to avoid large surface- area-to-water-volume ratios when using a conventional reservoir. Large water losses through evaporation can be reduced by compartmentalizing shallow impervious reservoirs and in flat terrain concentrating water by pumping it from one compartment to another. Concentrating the water reduces the surface-area-to-water-volume ratio to a minimum, thus decreasing evaporation losses by reducing both the temperature and exposure of the water to the atmosphere. Portable, high-capacity pumps make the method economical for small reservoirs as well as for relatively large reservoirs. Further, the amount of water available for beneficial consumption is usually more than the amount of water pumped for concentration. A Compartmented Reservoir Optimization Program (CROP-76) has been developed for selecting the optimal design configuration. The program has been utilized in designing several systems including several in Arizona. Through the use of the model, the interrelationship of the parameters have been determined. These parameters are volume, area, depth, and slope of the embankment around each compartment. These parameters interface with the parameters describing rainfall and hydrologic characteristics of the watershed. The water -yield model used in CROP-76 requires inputs of watershed area, daily precipitation and daily and maximum depletion. In addition, three sets of seasonal modifying coefficients are required either through calibration or estimated by an experienced hydrologist. The model can determine runoff from two types of watersheds, a natural and /or treated catchment. Additional inputs of CROP-76 are the surface water evaporation rate and the amount and type of consumptive use.
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Rainfall-Runoff Relationships for a Mountain Watershed in Southern ArizonaMyhrman, M., Cluff, C. B., Putnam, F. 15 April 1978 (has links)
From the Proceedings of the 1978 Meetings of the Arizona Section - American Water Resources Assn. and the Hydrology Section - Arizona Academy of Science - April 14-15, 1978, Flagstaff, Arizona / A network of rain gauges and two recorder -equipped flumes were installed near the head of Cottonwood Canyon on Mt. Hopkins in the Santa Rita Mountains pursuant to a water development study for the Smithsonian Institution's Mt. Hopkins Astrophysical Observatory. The watershed is generally characterized by steep slopes, a dense evergreen woodland cover predominated by several species of oaks, isolated bedrock exposures and talus chutes. The watershed for the lower flume site comprises about 145 acres (58.60 ha) with an elevation range from about 6775 to 8580 feet (2,065 to 2,615 m). Rainfall-runoff measurements were made during the summer and fall of 1977. A runoff efficiency of 0.56 percent was calculated for the lower-flume watershed. However, since physical evidence of surface flow was found only in side drainages receiving runoff from culverts located along the Mt. Hopkins access road, a second calculation was made, using only the total area of contributing road surface as the watershed area. This yielded a runoff efficiency of 27.0 percent. The latter value, adjusted for infiltration on the slopes below the culverts, agrees well with measured efficiencies for compacted-earth water harvesting catchments. Based on the above, recommendations were made for developing a water supply system using the access road, modified to increase its effectiveness, as a water harvesting system and having two surface reservoirs for storage. A computer model was used to test the capability of the system to meet the projected water needs of the observatory.
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Heterogeneity of Ohio’s Saline Reservoirs: Feldspar Abundance and its Effects on Carbon SequestrationDalton, Terra Ann 19 October 2011 (has links)
No description available.
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