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BL
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| Record Number
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863023
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| Main Entry
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Alami, Abdul Hai.
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| Title & Author
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Mechanical energy storage for renewable and sustainable energy resources /\ by Abdul Hai Alami.
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| Publication Statement
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Cham :: Springer,, 2020.
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| Series Statement
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Advances in science, technology & innovation,
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| Page. NO
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1 online resource
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| ISBN
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303033788X
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: 9783030337889
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3030337871
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9783030337872
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| Bibliographies/Indexes
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Includes bibliographical references.
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| Contents
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Intro -- Foreword -- Preface -- Contents -- About the Author -- List of Figures -- List of Tables -- List of Equations -- 1 Introduction to Mechanical Energy Storage -- 1.1 Introduction to Mechanical Energy Storage -- 1.2 Need for Storage Technology -- 1.3 Storage for Renewable Energy Resources -- 1.4 World Energy Resources and Consumption -- 1.5 Classification of Storage Systems -- 1.6 Available Storage Technologies -- 1.7 Mechanical Storage Systems -- 1.7.1 Units and Conversions -- References -- 2 General Concepts -- 2.1 Introduction -- 2.2 Basic Energy Conversion Concepts
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2.2.1 Thermodynamics -- 2.2.1.1 Internal Energy -- 2.2.1.2 Enthalpy -- 2.2.1.3 Entropy -- 2.2.1.4 Gibbs Rule and the Free Work Principle -- 2.2.2 Dynamics of Rigid Bodies -- 2.2.3 Heat Transfer -- 2.2.3.1 Sensible Heat -- 2.2.3.2 Latent Heat -- 2.2.4 Phase Diagrams -- 2.2.5 Compressible Flow -- 2.2.6 Electrical Generators -- 2.2.7 Ragone Plots -- References -- 3 Energy Storage in Elastic Components -- 3.1 Energy Storage in Elastic Components -- 3.2 Linear Springs -- 3.3 Torsional Springs -- 3.4 Hyperelastic Material -- 3.5 Energy Storage Applications -- References -- 4 Thermal Storage
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4.1 Thermal Storage -- 4.2 Latent Energy Storage -- 4.2.1 Available Materials for Latent Heat Storage: Inorganic Materials -- 4.2.2 Organic Phase-Change Materials -- 4.3 Experimental Latent Heat Trial -- 4.4 Thermal Storage for Solar Thermal Power Plants -- 4.5 Thermal Storage for Compressed-Air Energy Storage (CAES) Systems -- References -- 5 Flywheel Storage Systems -- 5.1 Flywheel Storage Systems -- 5.2 Flywheel Design -- 5.3 Components of Modern Flywheel Systems (Case Study of the AFS TRINITY) -- 5.3.1 Motor/Generator -- 5.3.2 Bearings -- 5.3.3 Composite Rotor -- 5.3.4 Control System
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5.3.5 Power Electronics -- 5.3.6 Ancillary Systems -- 5.3.7 Switchgear -- 5.3.8 Flywheel System Testing -- 5.3.9 System Performance -- 5.3.10 Operational Considerations -- 5.3.11 M3 Trinity System Technical Specifications -- 5.3.12 Potential Market for M3 Flywheels -- 5.4 Flywheels and Regenerative Braking Systems -- 5.4.1 Principal of Operation -- 5.5 Superconductors and Flywheels -- 5.6 Flywheels for Energy Storage and Attitude Control of the International Space Station -- References -- 6 Pumped Hydro Storage -- 6.1 Pumped Hydro Storage -- 6.2 Governing Equations
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6.3 Technical Consideration Pumped Hydro Storage Systems -- 6.4 Pumped Hydro Storage System Efficiency -- 6.4.1 Major Losses for Pumped Hydro Storage Systems -- 6.4.2 Response Time for Pumped Storage -- 6.5 Operational Aspects of Pumped Hydro Storage Systems -- 6.6 Technical Model for a Pumped Hydro Storage Facility [4] -- 6.6.1 Pumping Mode -- 6.6.2 Generation Mode -- 6.7 Case Study: Pumped Hydro Storage in the Hoover Dam (USA) [6] -- References -- 7 Compressed-Air Energy Storage Systems -- 7.1 Compressed-Air Energy Storage Systems -- 7.2 Large-Scale CAES Systems
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| Abstract
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The available literature on energy storage technologies in general, and mechanical energy storage in particular, is lacking in terms of both quantity and quality. This edited volume focuses on novel (yet uncomplicated) ideas that are currently part of the Energy Storage curriculum at the University of Sharjah, UAE. These techniques have been extensively researched and their prototypes are central to the undergraduate Energy Storage Lab that is associated with the course. Although ideally suited for wind energy storage, the techniques described are also suitable for renewable energy storage in general, and offer high two-way efficiency ratings.
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| Subject
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Direct energy conversion.
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| Subject
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Energy storage.
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| Subject
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Direct energy conversion.
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| Subject
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Energy storage.
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| Dewey Classification
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621.31/26
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| LC Classification
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TJ165
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