Design of Hydraulic Gates

Wysyłka: Niedostępna
Sugerowana cena detaliczna 585,11 PLN
Nasza cena: 547,08 PLN
Oszczędzasz 6%
Dodaj do Schowka
Zaloguj się
Przypomnij hasło
×
×
Paypo
Oferujemy szeroki asortyment - ponad 120 tys. produktów
Dysponujemy solidną wiedzą - działamy już 11 lat
Dbamy o wybór najcenniejszych tytułów

Opis: Design of Hydraulic Gates - Paulo Erbisti

Revised and updated, this second edition of Design of Hydraulic Gates maintains the same goal as the original: to be used as a textbook and a manual of design of gates, presenting the main aspects of design, manufacture, installation and operation of hydraulic gates, while introducing new products, technologies and calculation procedures. This edition included new chapters on intake gates and trashrack design, highlighting the aspects of safety, operational and maintenance procedures. To improve the strength against structural failure of intake trashracks, the author proposes a series of rigid calculation assumptions, design parameters and manufacturing procedures, which will certainly result in safer trashracks. Some 340 drawings and photographs, 82 tables, 107 references and 23 worked examples help the reader to understand the basic concepts and calculation methods presented. Praise for the first edition: Nobody is better qualified than Professor Paulo Erbisti to have written this book "Design of Hydraulic Gates", because he has acquired a very broad personal experience during his career devoted to hydroelectric projects, not only with a scientific spirit, but also a practical approach. He knows very well all the phases of implementation of hydromechanical equipment, from feasibility studies through to erection and commissioning, as well as rehabilitation. This book is extremely welcome as an efficient synthesis of a broad subject, and engineers from the various disciplines, not only mechanical and electrical but also civil engineers, will recognize its value. The author has covered the subject of gates very comprehensively in his book, from history to new developments. He discusses not only the principle of gates and their associated equipment, the choice of type and calculation methods, but also he (as an excellent practical engineer, who knows that 'the devil hides in the details') describes their construction details. Each chapter is supported by a complete list of international references. The book will be very useful for experienced engineers (as well as students) for the conception, construction and operation of gates.The interest of this book is evident as a reference, and Professor Erbisti should be gratefully acknowledged for his important contribution to this technology. Raymond Lafitte, Professor at EPFL (Federal Institute of Technology, Lausanne), President of the International Hydropower Association As one leafs through the book, one is pleasantly surprised by the many clear illustrations and photos (ca. 300), tables (ca. 70) and calculations (ca. 20). [...] On the one hand, the book - as a textbook - offers students a very clear introduction to the field and on the other hand, represents a handbook with lots of useful advice for engineers in the field of steel hydraulic engineering. Some 90 bibliographic references lead the reader to further background information, also in the realm of more theoretically oriented steel hydraulic engineering. Erbisti's book "Design of Hydraulic Gates" is all in all a very useful and recommended book. Prof. Dr.-Ing. Gerhard Schmausser, Aalen, in Stahlbau 73 (2004), 644-646Preface Acknowledgements 1 Introduction 1.1 History and development 1.2 Gate components 1.3 Main applications 1.4 Types and classifications 1.4.1 Purpose 1.4.2 Movement 1.4.3 Water passage 1.4.4 Gate leaf composition 1.4.5 Location 1.4.6 Skin plate shape 2 Types of gates 2.1 Flap gate 2.2 Cylinder gate 2.3 Stoplogs 2.4 Slide gate 2.5 Caterpillar gate 2.6 Miter gate 2.7 Roller gate 2.8 Segment gate 2.9 Sector gate 2.10 Stoney gate 2.11 Drum gate 2.12 Bear-trap gate 2.13 Fixed-wheel gate 2.14 Visor gate 3 Basis for selection of gate type 3.1 Introduction 3.2 Most common types 3.3 Operational requirements 3.4 Present limits of gate sizes and heads 4 Hydrostatics 4.1 Introduction 4.2 Vertical lift gates 4.2.1 Weir gates 4.2.2 Submerged gates 4.2.3 Spacing of horizontal beams 4.3 Radial gates 5 Structural design 5.1 Load cases 5.2 Allowable stresses 5.3 Skin plate 5.3.1 Thickness 5.3.2 Plate stresses 5.3.3 Effective width 5.4 Horizontal beams 5.4.1 Number of beams 5.4.2 Girder dimensions 5.4.2.1 Web thickness 5.4.2.2 Web depth 5.4.2.3 Flanges 5.4.3 Elastic stability 5.4.3.1 Compression flanges 5.4.3.2 Web stability 5.4.3.3 Stiffeners 5.4.4 Simple bending of beams 5.5 Segment gate 5.5.1 Skin plate 5.5.2 Gate framing 5.5.2.1 Girder arrangement 5.5.2.2 Horizontal beams 5.5.2.3 Vertical beams 5.5.3 Radial arms 5.5.3.1 Axial loads on the arms 5.5.3.2 Bearing loads 5.5.3.3 Buckling check 5.6 Silt pressure on gates 5.7 Gate seismic loads 6 Embedded parts, guides and supports 6.1 Slots and niches 6.2 Wheel track 6.2.1 Beam on an elastic foundation 6.2.2 Dimensioning by the Andree-Fricke theory 6.3 Slide tracks 6.4 Concrete bearing pressure 6.5 Lateral guidance 6.6 Wheels and pins 6.6.1 Design features 6.6.2 Contact pressure between wheel and track 6.6.3 Permissible contact stresses 1 6.6.4 Surface hardness 6.7 Gate hinges and bearings 6.7.1 Types of bearings 6.7.2 Cylindrical bushings 6.7.3 Spherical plain bearing 6.7.4 Roller bearings 7 Estimating gate weights 7.1 Introduction 7.2 Segment gates 7.3 Fixed-wheel gates 7.4 Double-leaf fixed-wheel gates 7.5 Stoplogs 7.6 Flap gates 7.7 Caterpillar gates 7.8 Embedded parts 8 Hydrodynamic forces 8.1 Introduction 8.2 Model tests 8.3 Factors influencing downpull 8.4 Formulae for the prediction of downpull 8.5 Method of Knapp 9 Gate operating forces 9.1 Introduction 9.2 Gate weight 9.3 Friction on supports and hinges 9.4 Seal deflection 9.5 Seal friction 10 Aeration 10.1 Introduction 10.2 Air vents - functions and features 10.3 Air vents - empirical calculation 10.4 Air-demand ratio 10.5 Air vent dimensioning 11 Gate hoists 11.1 Introduction 11.2 Screw lifts 11.3 Wire ropes 11.4 Roller chains 11.5 Oil hydraulic drives 11.6 Gate hoist arrangement 11.7 Hand operation 11.8 Design criteria 11.8.1 Load capacity 11.8.2 Operating speed 11.8.3 Safety factors 11.9 Gate position measurement 12 Materials 12.1 Introduction 12.2 Heat treatment 12.3 Rolled steels 12.4 Steels for machine elements 12.5 Stainless steels 12.6 Cast steels 12.7 Forged steels 12.8 Gray cast irons 12.9 Bronzes 12.10 Bolts 13 Gate seals 13.1 Introduction 13.2 Wood seals 13.3 Metallic seals 13.4 Rubber seals 13.5 Material for rubber seals 13.6 Clad seals 13.7 Rubber seal hardness 13.8 Rubber specifications 13.9 Seal leakage 13.10 Manufacture and assembly of seals 13.11 High-head segment gates - design considerations 13.12 Double-sealing gates 14 Manufacture, transportation and erection 14.1 Manufacture 14.1.1 Manufacturing steps 14.1.2 Full-size layout drawings 14.1.3 Storing of raw material 14.1.4 Marking 14.1.5 Cutting 14.1.6 Curving 14.1.7 Structure welding 14.1.8 Finishing 14.1.9 Pre-assembly 14.1.10 Machining 14.1.11 Mechanical fit-up 14.1.12 Anticorrosive protection 14.1.13 Inspection 14.1.14 Manufacturing tolerances 14.2 Transportation 14.3 Field erection 14.3.1 Erection instructions 14.3.2 Erection of embedded parts 14.3.3 Erection tolerances of embedded parts 14.3.4 Gate assembly 14.4 Acceptance tests 15 Trends and innovation in gate design 15.1 Long-span gates 15.2 High-head gates 15.3 Refurbishment and modernization of gates and dams 15.3.1 Heightening of existing gates 15.3.2 Installation of new gates on the top of the dam 16 Intake gates 16.1 Intake gates and accessories 16.2 Types of emergency gates 16.3 Gate hoists 16.3.1 Types of hoists 16.3.2 Hydraulic hoists 16.3.3 Cable hoists 16.3.4 Gantry cranes 16.4 Filling the penstock 16.5 Aeration 16.6 Guard gates for Kaplan turbines 16.7 Guard gates for bulb turbines 16.8 Draft tube stoplogs for bulb and Kaplan turbines 17 Intake trashracks 17.1 Introduction 17.2 Rack bar spacing 17.3 Design considerations 17.4 Flow velocity 17.5 Head loss 17.6 Flow-induced vibrations 17.7 Rack-cleaning machines 17.8 Safe design criteria for trashracks Name index Subject index


Szczegóły: Design of Hydraulic Gates - Paulo Erbisti

Tytuł: Design of Hydraulic Gates
Autor: Paulo Erbisti
Producent: CRC Press Inc.
ISBN: 9780415659390
Rok produkcji: 2014
Ilość stron: 442
Oprawa: Twarda
Waga: 0.95 kg


Recenzje: Design of Hydraulic Gates - Paulo Erbisti

Zaloguj się
Przypomnij hasło
×
×

Design of Hydraulic Gates

Revised and updated, this second edition of Design of Hydraulic Gates maintains the same goal as the original: to be used as a textbook and a manual of design of gates, presenting the main aspects of design, manufacture, installation and operation of hydraulic gates, while introducing new products, technologies and calculation procedures. This edition included new chapters on intake gates and trashrack design, highlighting the aspects of safety, operational and maintenance procedures. To improve the strength against structural failure of intake trashracks, the author proposes a series of rigid calculation assumptions, design parameters and manufacturing procedures, which will certainly result in safer trashracks. Some 340 drawings and photographs, 82 tables, 107 references and 23 worked examples help the reader to understand the basic concepts and calculation methods presented. Praise for the first edition: Nobody is better qualified than Professor Paulo Erbisti to have written this book "Design of Hydraulic Gates", because he has acquired a very broad personal experience during his career devoted to hydroelectric projects, not only with a scientific spirit, but also a practical approach. He knows very well all the phases of implementation of hydromechanical equipment, from feasibility studies through to erection and commissioning, as well as rehabilitation. This book is extremely welcome as an efficient synthesis of a broad subject, and engineers from the various disciplines, not only mechanical and electrical but also civil engineers, will recognize its value. The author has covered the subject of gates very comprehensively in his book, from history to new developments. He discusses not only the principle of gates and their associated equipment, the choice of type and calculation methods, but also he (as an excellent practical engineer, who knows that 'the devil hides in the details') describes their construction details. Each chapter is supported by a complete list of international references. The book will be very useful for experienced engineers (as well as students) for the conception, construction and operation of gates.The interest of this book is evident as a reference, and Professor Erbisti should be gratefully acknowledged for his important contribution to this technology. Raymond Lafitte, Professor at EPFL (Federal Institute of Technology, Lausanne), President of the International Hydropower Association As one leafs through the book, one is pleasantly surprised by the many clear illustrations and photos (ca. 300), tables (ca. 70) and calculations (ca. 20). [...] On the one hand, the book - as a textbook - offers students a very clear introduction to the field and on the other hand, represents a handbook with lots of useful advice for engineers in the field of steel hydraulic engineering. Some 90 bibliographic references lead the reader to further background information, also in the realm of more theoretically oriented steel hydraulic engineering. Erbisti's book "Design of Hydraulic Gates" is all in all a very useful and recommended book. Prof. Dr.-Ing. Gerhard Schmausser, Aalen, in Stahlbau 73 (2004), 644-646Preface Acknowledgements 1 Introduction 1.1 History and development 1.2 Gate components 1.3 Main applications 1.4 Types and classifications 1.4.1 Purpose 1.4.2 Movement 1.4.3 Water passage 1.4.4 Gate leaf composition 1.4.5 Location 1.4.6 Skin plate shape 2 Types of gates 2.1 Flap gate 2.2 Cylinder gate 2.3 Stoplogs 2.4 Slide gate 2.5 Caterpillar gate 2.6 Miter gate 2.7 Roller gate 2.8 Segment gate 2.9 Sector gate 2.10 Stoney gate 2.11 Drum gate 2.12 Bear-trap gate 2.13 Fixed-wheel gate 2.14 Visor gate 3 Basis for selection of gate type 3.1 Introduction 3.2 Most common types 3.3 Operational requirements 3.4 Present limits of gate sizes and heads 4 Hydrostatics 4.1 Introduction 4.2 Vertical lift gates 4.2.1 Weir gates 4.2.2 Submerged gates 4.2.3 Spacing of horizontal beams 4.3 Radial gates 5 Structural design 5.1 Load cases 5.2 Allowable stresses 5.3 Skin plate 5.3.1 Thickness 5.3.2 Plate stresses 5.3.3 Effective width 5.4 Horizontal beams 5.4.1 Number of beams 5.4.2 Girder dimensions 5.4.2.1 Web thickness 5.4.2.2 Web depth 5.4.2.3 Flanges 5.4.3 Elastic stability 5.4.3.1 Compression flanges 5.4.3.2 Web stability 5.4.3.3 Stiffeners 5.4.4 Simple bending of beams 5.5 Segment gate 5.5.1 Skin plate 5.5.2 Gate framing 5.5.2.1 Girder arrangement 5.5.2.2 Horizontal beams 5.5.2.3 Vertical beams 5.5.3 Radial arms 5.5.3.1 Axial loads on the arms 5.5.3.2 Bearing loads 5.5.3.3 Buckling check 5.6 Silt pressure on gates 5.7 Gate seismic loads 6 Embedded parts, guides and supports 6.1 Slots and niches 6.2 Wheel track 6.2.1 Beam on an elastic foundation 6.2.2 Dimensioning by the Andree-Fricke theory 6.3 Slide tracks 6.4 Concrete bearing pressure 6.5 Lateral guidance 6.6 Wheels and pins 6.6.1 Design features 6.6.2 Contact pressure between wheel and track 6.6.3 Permissible contact stresses 1 6.6.4 Surface hardness 6.7 Gate hinges and bearings 6.7.1 Types of bearings 6.7.2 Cylindrical bushings 6.7.3 Spherical plain bearing 6.7.4 Roller bearings 7 Estimating gate weights 7.1 Introduction 7.2 Segment gates 7.3 Fixed-wheel gates 7.4 Double-leaf fixed-wheel gates 7.5 Stoplogs 7.6 Flap gates 7.7 Caterpillar gates 7.8 Embedded parts 8 Hydrodynamic forces 8.1 Introduction 8.2 Model tests 8.3 Factors influencing downpull 8.4 Formulae for the prediction of downpull 8.5 Method of Knapp 9 Gate operating forces 9.1 Introduction 9.2 Gate weight 9.3 Friction on supports and hinges 9.4 Seal deflection 9.5 Seal friction 10 Aeration 10.1 Introduction 10.2 Air vents - functions and features 10.3 Air vents - empirical calculation 10.4 Air-demand ratio 10.5 Air vent dimensioning 11 Gate hoists 11.1 Introduction 11.2 Screw lifts 11.3 Wire ropes 11.4 Roller chains 11.5 Oil hydraulic drives 11.6 Gate hoist arrangement 11.7 Hand operation 11.8 Design criteria 11.8.1 Load capacity 11.8.2 Operating speed 11.8.3 Safety factors 11.9 Gate position measurement 12 Materials 12.1 Introduction 12.2 Heat treatment 12.3 Rolled steels 12.4 Steels for machine elements 12.5 Stainless steels 12.6 Cast steels 12.7 Forged steels 12.8 Gray cast irons 12.9 Bronzes 12.10 Bolts 13 Gate seals 13.1 Introduction 13.2 Wood seals 13.3 Metallic seals 13.4 Rubber seals 13.5 Material for rubber seals 13.6 Clad seals 13.7 Rubber seal hardness 13.8 Rubber specifications 13.9 Seal leakage 13.10 Manufacture and assembly of seals 13.11 High-head segment gates - design considerations 13.12 Double-sealing gates 14 Manufacture, transportation and erection 14.1 Manufacture 14.1.1 Manufacturing steps 14.1.2 Full-size layout drawings 14.1.3 Storing of raw material 14.1.4 Marking 14.1.5 Cutting 14.1.6 Curving 14.1.7 Structure welding 14.1.8 Finishing 14.1.9 Pre-assembly 14.1.10 Machining 14.1.11 Mechanical fit-up 14.1.12 Anticorrosive protection 14.1.13 Inspection 14.1.14 Manufacturing tolerances 14.2 Transportation 14.3 Field erection 14.3.1 Erection instructions 14.3.2 Erection of embedded parts 14.3.3 Erection tolerances of embedded parts 14.3.4 Gate assembly 14.4 Acceptance tests 15 Trends and innovation in gate design 15.1 Long-span gates 15.2 High-head gates 15.3 Refurbishment and modernization of gates and dams 15.3.1 Heightening of existing gates 15.3.2 Installation of new gates on the top of the dam 16 Intake gates 16.1 Intake gates and accessories 16.2 Types of emergency gates 16.3 Gate hoists 16.3.1 Types of hoists 16.3.2 Hydraulic hoists 16.3.3 Cable hoists 16.3.4 Gantry cranes 16.4 Filling the penstock 16.5 Aeration 16.6 Guard gates for Kaplan turbines 16.7 Guard gates for bulb turbines 16.8 Draft tube stoplogs for bulb and Kaplan turbines 17 Intake trashracks 17.1 Introduction 17.2 Rack bar spacing 17.3 Design considerations 17.4 Flow velocity 17.5 Head loss 17.6 Flow-induced vibrations 17.7 Rack-cleaning machines 17.8 Safe design criteria for trashracks Name index Subject index

Powiadom o dostępności
Podaj swój e-mail a zostaniesz poinformowany jak tylko pozycja będzie dostępna.
×
Cena 585,11 PLN
Nasza cena 547,08 PLN
Oszczędzasz 6%
Wysyłka: Niedostępna
Dodaj do Schowka
Zaloguj się
Przypomnij hasło
×
×

Paypo
Zaloguj się
Przypomnij hasło
×
×
Dodane do koszyka
×