Advances in renewable energies and power technologies. Volume 2, Biomass, fuel cells, geothermal energies, and smart grids /

Advances in Renewable Energies and Power Technologies Volume 2: Biomass, Fuel Cells, Geothermal Energies, and Smart Grids examines both the theoretical and practical elements of renewable energy sources, covering biomass, fuel cells, geothermal energy, RES, distributed energy, smart grids, and conve...

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Detalles Bibliográficos
Clasificación:Libro Electrónico
Otros Autores: Yahyaoui, Imene (Editor )
Formato: Electrónico eBook
Idioma:Inglés
Publicado: Amsterdam, Netherlands : Elsevier, 2018.
Temas:
Renewable energy sources.
Biomass energy.
Fuel cells.
Geothermal resources.
Smart power grids.
Renewable Energy
�Energies renouvelables.
Bio�energie.
�Energie g�eothermique.
R�eseaux �electriques intelligents.
geothermal power.
BUSINESS & ECONOMICS > Industries > Energy.
Biomass energy
Fuel cells
Geothermal resources
Renewable energy sources
Smart power grids
Acceso en línea:Texto completo
Tabla de Contenidos:
  • Front Cover; Advances in Renewable Energies and Power Technologies: Volume 2: Biomass, Fuel Cells, Geothermal Energies, and Smart Grids; Copyright; Contents; Contributors; Preface; Acknowledgement; Chapter 1: Biomass: Some Basics and Biogas; 1.1. Introduction; 1.1.1. World Outlook and Projection; 1.2. Biomass Classification; 1.3. Technological Routes for Energy Conversion of Biomass; 1.3.1. Processes of Biomass Energy Conversion; 1.4. Anaerobic Digestion Process; 1.4.1. Operational Conditions to Anaerobic Digestion Process; 1.5. Biogas Produced by Anaerobic Digestion Based Systems.
  • 1.5.1. Biogas: Characteristics1.6. Biogas From Digesters; 1.6.1. Current Anaerobic Digestion Technologies Based on Digesters; 1.6.2. Digesters; 1.6.2.1. Completely Mixed Digesters; 1.6.2.2. Plug Flow Digesters; 1.6.2.3. Covered Lagoon Digesters; 1.6.2.4. Chinese Fixed Dome; 1.6.2.5. Indian Floating Dome; 1.6.3. Calculation of Biogas Power From Anaerobic Digester System; 1.7. Landfill Gas Modeling; 1.7.1. Parameters to Landfill Models; 1.7.2. Main LFG Models; 1.7.2.1. GASFILL; 1.7.2.2. Intergovernmental Panel on Climate Change Model; 1.7.2.3. Solid Waste Association of North America.
  • 1.7.2.4. European Pollutant Emission Register1.7.2.5. Netherlands Organization for Applied Scientific Research (TNO); 1.7.2.6. Afvalzorg; 1.7.2.7. LandGEM; 1.7.2.8. Mexico; 1.7.2.9. LFGGEN; 1.7.2.10. Numerical Models; 1.7.2.11. Other Models; 1.7.3. Software Used to Predict LFG and Methane Potential; 1.7.3.1. CALMIM; 1.7.3.2. GasSim; 1.7.4. Comparison Between Models; 1.8. Power Generation Based on Biomass; 1.8.1. Electricity Generation From Biomass: Thermal Cycles; 1.8.1.1. Gas Turbines Technologies; 1.8.1.2. Microturbine Technologies; 1.8.1.3. Steam Turbine Technologies.
  • 1.8.1.4. Combined Cycle Technologies1.9. Final Considerations; References; Chapter 2: Simulation Models of Biomass Thermochemical Conversion Processes, Gasification and Pyrolysis, for the Predicti ... ; 2.1. Gasification Process; 2.2. Pyrolysis Process; 2.3. Gasification/Pyrolysis Reactors; 2.4. Simulation Models; 2.4.1. Thermodynamic Equilibrium Models; 2.4.2. Kinetic Models; 2.4.3. Models in Aspen Plus; 2.4.4. Models in ChemCAD; 2.5. Results of the Simulation of the Gasification/Pyrolysis; 2.5.1. CHEM_Gas Model; 2.5.2. MAT_Gas Model; 2.5.3. CHEM_Pyro Model.
  • 2.5.4. Results of CHEM_Gas Simulations2.5.4.1. Validation of the Model CHEM_Gas Through the Experimentations of Barrio and Fossum; 2.5.4.2. Validation of the Model CHEM_Gas Through the Experimentations of Jayah et al.; 2.5.4.3. Validation of the Model CHEM_Gas Through the Experimentations of Skoulou et al.; 2.5.5. Results of MAT_Gas Simulations; 2.5.5.1. Comparison Among MAT_Gas, CHEM_Gas and Experimental Data of Barrio and Fossum; 2.5.5.2. Comparison among MAT_Gas, CHEM_Gas and experimental data of Jayah et al.

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