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101 0 $aeng
135   $aur|n|---|||||
181   $ctxt
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183   $acr
200 10$aEnergy dissipation in hydraulic structures /$fHubert Chanson, School of Civil Engineering, University of Queensland, Brisbane, Australia
205   $a1st ed.
210  1$aBoca Raton :$cCRC Press,$d[2015].
210  4$dİ2015
215   $a1 online resource (178 p.)
225 0 $aBalkema Book
225 0 $aIAHR Monographs
300   $aDescription based upon print version of record.
311 08$a1-138-02755-3 
311 08$a1-315-68029-7 
320   $aIncludes bibliographical references at the end of each chapters.
327   $aFront Cover; About the IAHR Book Series; Table of contents; Preface; 1. Introduction: Energy dissipators in hydraulic structures; 2. Energy dissipation at block ramps; 3. Stepped spillways and cascades; 4. Hydraulic jumps and stilling basins; 5. Ski jumps, jets and plunge pools; 6. Impact dissipators; 7. Energy dissipation: Concluding remarks
330   $aRecent 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 structure (e.g. dam, weir) without major damage to the structure itself and to its environment. At the hydraulic structure, the flood waters rush as an open channel flow or free-falling jet, and it is essential to dissipate a very signifi cant part of the flow kinetic energy to avoid damage to the hydraulic structure and its surroundings. Energy dissipation may be realised by a wide range of design techniques. A number of modern developments have demonstrated that such energy dissipation may be achieved (a) along the chute, (b) in a downstream energy dissipator, or (c) a combination of both. The magnitude of turbulent energy that must be dissipated in hydraulic structures is enormous even in small rural and urban structures. For a small storm waterway discharging at a 4 m3/s mm high drop, the turbulent kinetic energy flux per unit time is 120 kW! At a large dam, the rate of energy dissipation can exceed tens to hundreds of gigawatts; that is, many times the energy production rate of nuclear power plants. Many engineers have never been exposed to the complexity of energy dissipator designs, to the physical processes taking place and to the structural challenges. Several energy dissipators, spillways and storm waterways failed because of poor engineering design. It is believed that a major issue affecting these failures was the lack of understanding of the basic turbulent dissipation processes and of the interactions between free-surface aeration and flow turbulence. In that context, an authoritative reference
330 8 $abook on energy dissipation in hydraulic structures is proposed here. The book contents encompass a range of design techniques including block ramps, stepped spillways, hydraulic jump stilling basins, ski jumps and impact dissipators.
410  0$aIAHR Monographs
606   $aHydrodynamics
606   $aHydraulic structures
606   $aEnergy dissipation
606   $aDiversion structures (Hydraulic engineering)
615  0$aHydrodynamics.
615  0$aHydraulic structures.
615  0$aEnergy dissipation.
615  0$aDiversion structures (Hydraulic engineering)
676   $a628.10826634
700   $aChanson$b Hubert$0285131
801  0$bFlBoTFG
801  1$bFlBoTFG
906   $aBOOK
912   $a9910970010403321
996   $aEnergy dissipation in hydraulic structures$92876157
997   $aUNINA