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Shah Y.T. Energy and Fuel Systems Integration (Green Chemistry and Chemical Engineering)

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Shah Y.T. Energy and Fuel Systems Integration (Green Chemistry and Chemical Engineering)
Taylor & Francis Group, LLC., 2016. – 478 p. – ISBN: 1482253062.
Energy and Fuel Systems Integration explains how growing energy and fuel demands, paired with the need for environmental preservation, require different sources of energy and fuel to cooperate and integrate with each other rather than simply compete. Providing numerous examples of energy and fuel systems integration success stories, this book:
Discusses the use of different mixtures of fuels for combustion, gasification, liquefaction, pyrolysis, and anaerobic digestion processes
Describes the use of hybrid nuclear and renewable energy systems for power and heat cogenerations with nonelectrical applications
Details the holistic integration of renewable, nuclear, and fossil energy systems by gas, heat, and smart electrical grids
Energy and Fuel Systems Integration emphasizes the many advantages of these integrated systems, including sustainability, flexibility for optimization and scale-up, and more efficient use of storage, transportation, and delivery infrastructures
Contents
Introduction
Why Energy and Fuel Systems Integration?
Details on Methods of Integration
Multifuel, Hybrid, and Grid-Integrated Vehicles: A Case Study
Scales of Energy and Fuel Systems
Principles of Energy and Fuel Systems Management
Heat and Power by Co-Combustion
Advantages and Disadvantages of Multifuel Combustion
Methods of Co-Combustion and Associated System Configurations
Feedstock Pretreatment
Effects of Combustor Design
Emissions and Product Treatments
Commercial Processes and Large-Scale Multifuel
Markets and Economics of Multifuel Combustion
Other Co-Firing Options
Synthetic Gas Production by Co-Gasification
Co-Gasification of Coal and Biomass
Hydrothermal Gasification
Synthetic Liquid Production by Co-Processing
Direct Liquefaction of Coal in the Presence of a Donor Solvent
HTL of Coal and Biomass
Co-Processing
Decomposition, Extraction, and Co-Processing in Supercritical Water
Co-Pyrolysis
Advantages and Disadvantages
Co-Pyrolysis of Coal/Biomass/Waste
Co-Pyrolysis of Multifuels Systems Not Involving Coal
Hydrothermal Carbonization (Wet Pyrolysis)
Methane Production by Anaerobic Co-Digestion of Biomass and Waste
What Is Co-Digestion?
Advantages and Disadvantages
Major Applications, Users, and Related Issues
Feed Pretreatment
Process and Economic Considerations
Process Monitoring, Control, SCALE-UP, Modeling, and Optimization
Examples of Feedstock Effects
Typical Large-Scale Co-Digestion Plants
Future Prospects for Co-Digestion
Hybrid Nuclear Energy Systems
Why Nuclear Energy?
Strategies for Growth
Advanced Hybrid Nuclear–Renewable Energy Systems with Cogeneration (Combined Heat and Power Systems)
Nuclear Heat for Oil Production and Refining
Nuclear Heat for Various Thermochemical Transformation Systems
Nuclear Heat for Various Hydrogen Production Systems
Nuclear Heat for Desalination of Water
Nuclear Heat for District Heating
Nuclear Heat for Industrial Process Heat Applications
Use of Nuclear Reactor Heat and Power for Ship, Submarine, and Space Transportations
Market Potential and Future Prospects for HNES
Hybrid Renewable Energy Systems
Hybrid Wind Energy Systems
Hybrid Geothermal Energy Systems
Hybrid Solar Energy Systems
Future of Hybrid Renewable Energy Systems
Energy and Fuel Systems Integration by Gas, Heat, and Electricity Grids
Natural Gas Grid
Smart Electrical Grid
Methods of Energy Storage
Integration of Grids (SG) and Energy Storage
Multifuel, Hybrid, and Grid-Integrated Vehicles: A Case Study
Multifuel Vehicles
Hybrid Vehicles
Grid-Integrated Vehicles
Future of Multifuel, Hybrid, and Grid-Integrated Vehicles
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