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Introductory technical guidance for civil engineers interested in hydraulic design of spillways at dams and other water resources facilities. Here is what is discussed: 1. INTRODUCTION 2. BASIC CONSIDERATIONS 3. GENERAL CONSIDERATIONS FOR SPILLWAY DISCHARGE 4. ABUTMENT AND PIERS 5. EFFECT OF APPROACH FLOW 6. GRADIENTS IN GENERAL 7. HYDRAULIC AND ENERGY GRADIENT LINES 8. MEAN SPILLWAY PRESSURE COMPUTATION 9. SPILLWAY ENERGY LOSS 10. ENERGY LOSS FOR FULLY DEVELOPED TURBULENT BOUNDARY LAYER FLOW 11. TURBULENT BOUNDARY LAYER DEVELOPMENT ENERGY LOSS 12. HYDRAULIC JUMP ENERGY DISSIPATORS 13. CAVITATION.
Hydraulics of pressurized flow - Hydraulics of open-channel flow - Subsurface flow and transport - Environmental hydraulics - Sedimentation and erosion hydraulics - Risk/reliability-based hydraulics engineering degin - Hydraulics design for energy generation - Hydraulics of water distribution systems - Pump system hydraulic design - Water distribution system design - Hydraulic transient design for pipeline systems - Hydraulic design of drainage for highways - Hydraulic design of urban drainage systems - Hydraulics design of culverts and highway structures - Hydraulic design of flood control channels - Hydraulic design of spillways - Hydraulic design of stilling basisns and energy dissipators - Floodplain hydraulics - Flow transitions and energy dissipators for culverts and channels - Hydraulic design of flow measuring structures - Water and wastewater treatment plant hydraulics - Hydraulic design for groundwater contamination - Artificial recharge of groundwater: systems, design and ma ...
Introductory technical guidance for civil engineers interested in spillways for small dams. Here is what is discussed: 1. GENERAL 2. SERVICE SPILLWAYS.
A labyrinth weir is a series of duckbill spillways for controlling the flow of water over a dam or channel. This slim volume compares the crest shapes used on weirs, identifies considerations for designing downstream chutes and dealing with sedimentation, explores general guidelines for parameter se
Stepped channel design has been in use for more than 3,500 years. Recent advances in technology have triggered a regained interest in stepped design, although much expertise has been lost in the last 80 years. The steps significantly increase the rate of energy dissipation taking place along the chute and reduce the size of the required downstream energy dissipation basin. Stepped cascades are also used in water treatment plants to enhance the air-water transfer of atmospheric gases (e.g. oxygen, nitrogen) and of volatile organic components (VOC). Results from more than forty-five laboratory studies and four prototype investigations were re-analysed and compared. The book provides a new understanding of stepped channel hydraulics, and is aimed both at researchers and professionals.
Most dam accidents with hydroelectric plants are due to under-dimensioning of the maximum floods of spillway design, causing extravasation and dam breaks (this occurs in 23% of the accidents). This work highlights the relationship between spillway design and potential dam failure and other important aspects of these structures and presents the methodology of design based on the international experience on the subject. The book covers river basin studies and floods (the geology, geomorphology, hydrology, hydraulics, and layouts of the works). Further, spillway function, capacity and design flood, layouts, or arrangements, of hydroelectric works and types of spillways are treated in the book. Finally, the book discusses examples of dams that broke due to insufficient spillway capacity. The book is intended for engineers and the companies that design dams and power plants around the world, as well as students in dam and hydraulic engineering. In short, people interested in producing electricity that is clean and potentially cheaper than other sources.
Although hundreds of stilling basins and energy­dissipating devices have been designed in conjunction with spillways, outlet works, and canal structures, it is often necessary to make model studies of individual structures to be certain that these will operate as anticipated. The reason for these repetitive tests is that a factor of uncertainty exists regarding the overall performance characteristics of energy dissipators. The many laboratory studies made on individual structures over a period of years have been made by different personnel, for different groups of designers, each structure having different allowable design limitations. Since no two structures were exactly alike, attempts to generalize the assembled data resulted in sketchy and, at times, inconsistent results having only vague connecting links. Extensive library research into the works of others revealed the fact that the necessary correlation factors are nonexistent. To fill the need for up-to-date hydraulic design information on stilling basins and energy dissipators, a research program on this general subject was begun with a study of the hydraulic jump, observing all phases as it occurs in open channel flow. With a broader understanding of this phenomenon it was then possible to proceed to the more practical aspects of stilling basin design. This monograph generalizes the design of stilling basins, energy dissipators of several kinds and associated appurtenances. General design rules are presented so that the necessary dimensions for a particular structure may be easily and quickly determined, and the selected values checked by others without the need for exceptional judgment or extensive previous experience. Proper use of the material in this monograph will eliminate the need for hydraulic model tests on many individual structures, particularly the smaller ones. Designs of structures obtained by following the recommendations presented here will be conservative in that they will provide a desirable factor of safety. However, model studies will still prove beneficial to reduce structure sizes further, to account for nonsymmetrical conditions of approach or getaway, or to evaluate other unusual conditions not described herein.
Recent advances in technology have permitted the construction of large dams, reservoirs and channels. This progress has necessitated the development of new design and construction techniques, particularly with the provision of adequate flood release facilities. Chutes and spillways are designed to spill large water discharges over a hydraulic struc