Your search keyword '"canal pool"' showing total 4 results

1. Environmental Hydraulics Research.

Author

Ramos, Helena M., Adeyeye, Kemi, Carravetta, Armando, McNabola, Aonghus, and Ramos, Helena M.

Subjects

Technology: general issues, ADV, CAES, CFD, CFD models, Darcy's law, E. coli, FTW, Lattice Boltzmann method, Poyang Lake, SCS curve number, SVF, Three Gorges Dam, area contraction ratio, bed shear stress, caffa3d, canal pool, channel regulation, cohesive sediments, consolidation, degradation, delay time, dissolved phosphorus, downstream constant water level, eco-design, energy concept, energy dissipation, energy dissipation rate, energy storage, engineering structure, environmentally-friendly solutions, erosion, erosion and energy dissipaters, fecal indicator bacteria, feedforward control, fish aggregation effect, fish protection, fitting coefficients, flocculation, fractal model, free surface flows, frozen soil, groundwater, head loss, hybrid hydro-wind-solar solutions, hydraulic conductivity, hydraulic efficiency, hydraulic structure design and management, hydraulic structures, hydraulics of renewable energy systems, hydro-energy, hydrodynamic condition, hydrodynamic model, hydrodynamics, hydrologic and ecologic challenges, hydropower systems, hydrostatic pressure machine, intake, jet falling, lifespan, mathematical modelling, micro hydropower, new hydraulic concepts, new power generation, open source, over-current capability, permeable spur dike, physical modeling, pressure fluctuations, pressurised flows, pulsating pressure, pulsating velocity, pumped hydro storage (PHS), release characteristics, river-lake system, rotating circular flume, scale model test, sediment deposition, similarity law, sliding mesh, soil freezing curve, soil structure, stormwater reuse, submerge ratio, surface disturbances, suspended vegetation, sustainable developments, sustainable efficiency, technical feasibility, time-averaged pressure, time-averaged velocity, toothed internal energy dissipaters (TIED), transient flow, velocity profile, volume compensation, volume of fluid, water flow diversity, water jet, water level, water systems efficiency, water well, water well management, well ageing, well operation

Abstract

Summary: This book aims to provide research and engineering applications related to water and hydraulic problems. It is comprised of scientific papers in all topics of hydraulics, in particular, on sustainable water management, environmental hydraulics, ecohydraulics, water-energy nexus, and systems protection and efficiency. Safety and innovation issues, interdisciplinary problems, and linkage of theory to experimental and field applications can also be found within. Solutions of water problems in the form of prediction models, flow simulations, engineering systems, monitoring, management strategies covering scientific investigations and/or experimental or field studies of flow behaviour, hydrodynamics, and climate changes effects and adaptation, new design solutions, innovative approaches in the field of environment, hydraulics, techniques, methods, and analyses to address the new challenges in environmental hydraulics are alo presented and explored. This topic is studied both from a technical and environmental point of view, with the objective of protecting and enhancing the quality of the environment. In a cross-disciplinary field of study, this book comprises open channel/river flows and pressurised systems, combining, among others, new technological, social, and environmental hydraulic challenges, working in water-related fields with available information, new concepts and tools, new design solutions, eco-friendly technologies, and the advanced materials necessary to address the increasing challenges of ensuring a sustainable water environment by promoting the adaptation, flexibility, integration, and sustainability of recognised environmental solutions.

2. Exploring Explicit Delay Time for Volume Compensation in Feedforward Control of Canal Systems

Author

Wenjun Liao, Guanghua Guan, and Xin Tian

Subjects

canal pool, delay time, volume compensation, feedforward control, downstream constant water level, Hydraulic engineering, TC1-978, Water supply for domestic and industrial purposes, TD201-500

Abstract

In the open channel control algorithm, good feed-forward controllers will reduce the transition time of the canal and improve performance. Feedforward control algorithms based on active storage compensation are greatly affected by delay time. However, there is no literature comparing the three most commonly used algorithms, namely volume step compensation, dynamic wave principle and water balance models, under the operation mode of constant water level downstream. In order to compare the existing three algorithms, and to avoid storage calculation by calculating the constant non-uniform water surface line or identification of relevant parameters, combined with the open channel constant gradient flow theory with the storage compensation algorithm, a delay time explicit algorithm is proposed in this study. Tested on the first canal pool of the American Society of Civil Engineers (ASCE) Test Canal 2, the performance of the delay time explicit algorithm is assessed and compared to that of the three conventional algorithms. In the current water intake plan, i.e., in the second hour, the intake begins to take 1.2 m3/s, and the upstream flow of the canal pool changes from 6 m3/s to 7.2 m3/s, among the three existing algorithms, the volume step compensation algorithm has better performance in terms of time to achieve stability, i.e., 1.25 h. The actual adjusted storage accounts for 99.6% of the target adjusted storage, which can basically meet the requirement of compensated storage of the canal pool. The delay time explicit algorithm only needs 1.47 h to stabilize the regulation system. The fluctuation of water level and discharge in the regulation process is small. The actual adjusted storage accounts for 99.6% of the target adjusted storage, which can basically meet the requirement of compensated storage for the canal pool. The delay time calculated by explicit algorithm can provide references for the determination of delay time in feedforward control.

Published

2019

3. Exploring explicit delay time for volume compensation in feedforward control of canal systems

Author

Liao, Wenjun (author), Guan, Guanghua (author), Tian, X. (author), Liao, Wenjun (author), Guan, Guanghua (author), and Tian, X. (author)

Abstract

In the open channel control algorithm, good feed-forward controllers will reduce the transition time of the canal and improve performance. Feedforward control algorithms based on active storage compensation are greatly affected by delay time. However, there is no literature comparing the three most commonly used algorithms, namely volume step compensation, dynamic wave principle and water balance models, under the operation mode of constant water level downstream. In order to compare the existing three algorithms, and to avoid storage calculation by calculating the constant non-uniform water surface line or identification of relevant parameters, combined with the open channel constant gradient flow theory with the storage compensation algorithm, a delay time explicit algorithm is proposed in this study. Tested on the first canal pool of the American Society of Civil Engineers (ASCE) Test Canal 2, the performance of the delay time explicit algorithm is assessed and compared to that of the three conventional algorithms. In the current water intake plan, i.e., in the second hour, the intake begins to take 1.2 m3/s, and the upstream flow of the canal pool changes from 6 m3/s to 7.2 m3/s, among the three existing algorithms, the volume step compensation algorithm has better performance in terms of time to achieve stability, i.e., 1.25 h. The actual adjusted storage accounts for 99.6% of the target adjusted storage, which can basically meet the requirement of compensated storage of the canal pool. The delay time explicit algorithm only needs 1.47 h to stabilize the regulation system. The fluctuation of water level and discharge in the regulation process is small. The actual adjusted storage accounts for 99.6% of the target adjusted storage, which can basically meet the requirement of compensated storage for the canal pool. The delay time calculated by explicit algorithm can provide references for the determination of delay time in feedf, Water Resources

Published

2019

4. Exploring Explicit Delay Time for Volume Compensation in Feedforward Control of Canal Systems.

Author

Liao, Wenjun, Guan, Guanghua, and Tian, Xin

Subjects

CANALS, FEEDFORWARD control systems, ALGORITHMS, WATER storage

Abstract

In the open channel control algorithm, good feed-forward controllers will reduce the transition time of the canal and improve performance. Feedforward control algorithms based on active storage compensation are greatly affected by delay time. However, there is no literature comparing the three most commonly used algorithms, namely volume step compensation, dynamic wave principle and water balance models, under the operation mode of constant water level downstream. In order to compare the existing three algorithms, and to avoid storage calculation by calculating the constant non-uniform water surface line or identification of relevant parameters, combined with the open channel constant gradient flow theory with the storage compensation algorithm, a delay time explicit algorithm is proposed in this study. Tested on the first canal pool of the American Society of Civil Engineers (ASCE) Test Canal 2, the performance of the delay time explicit algorithm is assessed and compared to that of the three conventional algorithms. In the current water intake plan, i.e., in the second hour, the intake begins to take 1.2 m3/s, and the upstream flow of the canal pool changes from 6 m3/s to 7.2 m3/s, among the three existing algorithms, the volume step compensation algorithm has better performance in terms of time to achieve stability, i.e., 1.25 h. The actual adjusted storage accounts for 99.6% of the target adjusted storage, which can basically meet the requirement of compensated storage of the canal pool. The delay time explicit algorithm only needs 1.47 h to stabilize the regulation system. The fluctuation of water level and discharge in the regulation process is small. The actual adjusted storage accounts for 99.6% of the target adjusted storage, which can basically meet the requirement of compensated storage for the canal pool. The delay time calculated by explicit algorithm can provide references for the determination of delay time in feedforward control. [ABSTRACT FROM AUTHOR]

Published

2019