Exergy for A Better Environment and Improved Sustainability 1: Fundamentals: Green Energy and Technology
Editat de Fethi Aloui, Ibrahim Dinceren Limba Engleză Hardback – 17 aug 2018
Exergy for Better Environment and Sustainability, Volume 1 will appeal to researchers, students, and professionals within engineering and the renewable energy fields.
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Specificații
ISBN-13: 9783319625713
ISBN-10: 3319625713
Pagini: 800
Ilustrații: XVIII, 1469 p. 889 illus., 650 illus. in color. In 2 volumes, not available separately.
Dimensiuni: 155 x 235 mm
Ediția:1st ed. 2018
Editura: Springer International Publishing
Colecția Springer
Seria Green Energy and Technology
Locul publicării:Cham, Switzerland
ISBN-10: 3319625713
Pagini: 800
Ilustrații: XVIII, 1469 p. 889 illus., 650 illus. in color. In 2 volumes, not available separately.
Dimensiuni: 155 x 235 mm
Ediția:1st ed. 2018
Editura: Springer International Publishing
Colecția Springer
Seria Green Energy and Technology
Locul publicării:Cham, Switzerland
Cuprins
Part 1: Heat and mass transfer, and fluid mechanics.- Chapter1. Dynamic Study of a Metal Hydride Pump.- Chapter2. Unsteady Aerodynamic Analysis of Different Multi MW Horizontal Axis Wind Turbine Blade Profiles on SST-K-ω.- Chapter3. Productivity Analysis and Numerical Simulation for Fractured Wells in Unconventional Gas Reservoirs.- Chapter4. Study of Porous Flow Mechanism for Low Permeability Sandstone by Use of NMR.- Chapter5. Thermal and Dynamic characteristics of an Airflow in a Channel Provided with Circular and Triangular Cavities.- Chapter6. Turbulent Air Flow Investigation through the Vaned Diffuser Turbocharger using CFD.- Chapter7. Some Measurements in Multiple Jets.- Chapter8. Study of Growth Rate in Turbulent Mixing Layers.-Chapter9. Natural Convection Heat Transfer of Water-Based CuO and Water-Based Al2O3 Nanofluids Through A Horizontal Plate.- Chapter10. Analysis of Coriolis Effect in a Curved Pipe Conveying Hydrogen Using Timoshenko Beam Element.- Chapter11. Inverse Design Method of Wind Turbine in Solar Chimney Power Plants Coupled with Geothermal Energy.- Chapter12. The Techniques Used for Performance Prediction of Vertical Axis Wind Turbines.- Chapter13. Modeling and Numerical Investigation of Latent Heat Storage Unit Using Paraffin Wax.- Chapter14. Investigation of Effective Parameters on the Human Body Exergy and Energy Model.- Chapter15. Motion of a Solid Particle in a Water Flow Inside a Pipe.- Chapter16. Numerical Modeling and Performance Optimization Study of a Cavity Receiver in Solar Tower.- Chapter17. Parametric Study on Thermal Performance of PCM-Heat Sink Used for Electronic Cooling.- Chapter18. Aerodynamic and Energy Analysis of an Industrial Wind Turbine.-Chapter19. A CFD Analysis of the Air Flow through the Stirling Engine’s Singularities.- Chapter20. Modelling Energetic Efficiency of Coil Annealing Using Hydrogen Gas.- Chapter21. Modelling of Flat Plate and V-Corrugated Solar Air Heaters for Single and Counter Flow OperatingModes.- Chapter22. Parametric Numerical Study of Blood Flow Analysis in idealized Abdominal Aortic Aneurysms Geometries.- Chapter23. Experimental Investigation of Surface Flow Structure over Non-Slender Diamond Wing.- Chapter24. Experimental Investigations on Condensation of Steam in Microchannels.- Chapter25. Development of a CFD Model for Prediction of a Natural Gas Fuelled HCCI Engine Combustion and Performance Characteristics Employing a New Reduced Chemical Kinetic Mech.-Chapter26. Modeling of Wind Loads on Heliostats Installed in South Algeria for Various Pylon Height.- Chapter27. Experimental Investigations of the Effect of the Enrichment with Oxygen on the Stability of the Diffusion Flame from Burners with Separate Injections.- Chapter28. Prediction of Heat and Mass Transfer within a Metal-Hydrogen Reactor Using the Lattice Boltzmann Method.-Chapter29. Experimental and Theoretical Investigation of Flows inside a Gamma Stirling Engine Regenerator.-Chapter30. Secondary Migration of Fang Crude Petroleum Related to Volumetric Flow Rate.- Chapter31. Characteristic of Savonius vertical axis rotor in water channel.-Chapter32. Hydrodynamics Design of a Tunnel Submarine with Dimension Analysis.- Chapter33. Aerodynamic performances of Pitching wind air-foil using unsteady panel method.- Chapter34. Mathematical Modeling of heat and mass transfers in Humidifiers.- Chapter35. Heat and Mass Transfer during Hydriting.- Chapter36. Numerical and Dynamic Study of Flow Instabilities and Heat Transfer at a Backward Facing Step Using the Lattice Boltzmann Method.- Chapter37. Experimental investigations on oscillatory Couette-Taylor Flow wall shear stress behaviour using electrochemical technique: High modulation effect.- Chapter38. Boundary layer separation on an airfoil at a low Reynolds number.- Chapter39. Experimental Investigations of Taylor-Couette Flow Using PIV and Electrochemical Techniques.- Chapter40. Radial distribution of mass transfer and wall shear instantaneousrates in Couette-Taylor flow.- Chapter41. Testing and Analysis of R134a Clathrates with Additives for Cooling Applications.- Chapter42. A new analytical relation for performance of small regenerative turbine pumps.- Chapter43. Quantitative evaluation of influential coefficients of regenerative pumps.- Chapter44. Recovery of Waste Farm after Methanization by Evaporation on Inclined Plate.- Chapter45. Large Eddy Simulation based Lattice Boltzmann Method with different collision models.- Part2: Exergy and energy analyses and assessments.- Chapter46. Electrochemical, energy, exergy and exergoeconomic analyses of hybrid photocatalytic hydrogen production reactor for Cu-Cl Cycle.- Chapter47. LiBr Absorption Systems Integrated with High–Efficiency IGSG Plant.- Chapter48. The Effect of Ambient Temperature to Tabriz Power Plant Efficiency.- Chapter49. Energy and Exergy Analysis of Tabriz Power Plant for Different Loads.- Chapter50. Second Law Analysis of an Experimental Micro Turbojet Engine.-Chapter51. Effect of Thermal Conductivity of the Phase Change Material (PCM) on the Absorption Process of a Metal-Hydrogen Reactor.- Chapter52. Energy and exergy analysis of a solar-hydrogen hybrid renewable energy system in Ankara, Turkey.- Chapter53. Thermodynamic Analysis of Inlet Air cooling system for a centrifugal compressor.- Chapter54. A study on the Charge Discharge Cycle of a Compressed Hydrogen Tank for Automobiles.- Chapter55. Integration of Pulse Combustion in Air Bottoming Cycle Power Plants.- Chapter56. Multi-objective Optimization of a Cogeneration of Power and Heat in a Combined Gas Turbine and organic Rankine cycle.- Chapter57. Exergetic and Environmental Analysis of 100 MW Intercooled Gas Turbine Engine.- Chapter58. Experimental Analysis and Thermodynamic Modeling of an Absorption-Diffusion Refrigerator.- Chapter59. Exergoeconomic Approaches.- Chapter60. Exergy and Energy Analysis of an Aircraft Air Cycle Machine at Designated Altitude.- Chapter61. Integrated Modelof Horizontal Earth Pipe Cooling System for a Hot Humid Climate.- Chapter62. Waste Heat Recovery in a Sulfuric Acid Production Unit.- Chapter63. Comparative Energy, Exergy and Environmental Analyses of Parabolic Trough Solar Thermal Power Plant Using Nanofluids.- Chapter64. Exergetic Simulation and Performance Assessment of 1-1 Shell and Tube Heat Exchangers.- Chapter65. Parametric Exergetic Investigation of a Direct Formic Acid Fuel Cell System.- Chapter66. Experimental and Numerical Investigations of a Small Turbojet Engine with the Aid of Exergy.- Chapter67. Progress in High Performances, Low emissions and Exergy Recovery in Internal Combustion Engines.- Chapter68. Thermoeconomic Multi-Objective Optimization of an Ammonia-Water Power/Cooling Cycle coupled with a HCCI Engine.- Chapter69. Exergetic Optimisation of Atmospheric and Vacuum Distillation System Based on Bootstrap Aggregated Neural Network Models.- Chapter70. Modeling, simulation and optimization of solar assisted absorption cooling systems.- Chapter71. Exergetic Evaluation for Heat Exchanger Network in a Raw Petroleum Cracking Unit.- Chapter72. Design of an Inlet Air Cooling System for a Gas-Turbine Power Plant.- Chapter73. Exergetic Analysis of a Gas Turbine with Inlet Air Cooling System.- Chapter74. Exergy Analysis of a Hybrid System Including a Solar Panel, Fuel Cell and Absorption Chiller.- Chapter75. 3D Numerical Investigation of Ignition Timing Effects on the SI Engine exergy.- Chapter76. Exergy and Exergoeconomic Analysis and Optimization of the Cogeneration Cycle Under Solar Radiation Dynamic Model Using Genetic Algorithm.- Chapter77. Influence of Operating Parameters on the Thermal Efficiency of Complexes Combined Cycle.- Chapter78. Assessment of CO2 Measurements Based on Exergetic Approach for Low Carbon Standards in Buildings.- Chapter79. Energetic and Exergetic Performance Assessment of a Marine Engine With Measurement of CO2 Emission.- Chapter80. High-Temperature Latent Heat Storage Technology to Utilize Exergy of Solar Heat and Industrial Exhaust Heat.- Chapter81. Exergy Analysis for Energy Systems.- Chapter82. Conventional and Advanced Exergy Analysis of Post-Combustion CO2 Capture from Supercritical Coal-Fired Power Plant.- Chapter83. Exergy of Laminar Flow in Porous Medium.- Chapter84. An Exergy Analysis of a Laboratory Scale Fast Pyrolysis Process Design.- Chapter85. Greenhouse Gas Emission & Thermodynamic Assessments of an Integrated Trigeneration System Based on a SOFC Driving a GAX Absorption Refrigeration System as a Subsystem.- Chapter86. Energy and Exergy Analysis of a Novel Combined Power/Cooling Production Cycle Based on Solid Oxide Fuel Cell.- Chapter87. Combustion Analysis of Bio Fuel Derived From Waste Fish Fat.- Chapter88. Thermodynamic Performance Assessment and Comparison of Active Magnetic Regenerative and Conventional Refrigeration Systems.- Chapter89. Experimental Analysis of Biofuel and Undistilled Biofuel from Waste Fish Fat in Diesel Engine.- Chapter90. A Novel Approach to Local Level Design of Bioenergy Supply Chains Integrated with District Heating Systems.- Chapter91. Optimal Operation of MEA-Based Post-Combustion Carbon Capture Process for Natural Gas Combined Cycle Power Plants.- Chapter92. Technical and economic analysis of ionic liquid-based post-combustion CO2 capture process.- Chapter93. Process Simulation and energy consumption analysis for CO2 Capture with Different Solvents.- Chapter94. Energetic and Exergetic Performance Assessment of a Marine Engine with Measurement of CO2 Emission.- Chapter95. Some considerations regarding entropy production minimization method and optimization of thermo-mechanical systems. Power optimization versus entropy production minimization in thermomechanical systems.
Notă biografică
Ibrahim Dincer is a Professor at the Department of Automotive, Mechanical and Manufacturing Engineering Faculty of Engineering and Applied Science, at the University of Ontario Institute of Technology. He's an Editor-in-Chief of three academic journals and a board member for many more. He is the author and editor of numerous Springer titles.
Aloui Fethi is a Professor at the University of Valenciennes with interests in fluid mechanics, energetics, inverse methods among others.
Textul de pe ultima copertă
This multi-disciplinary book presents the most recent advances in exergy, energy, and environmental issues. Volume 1 focuses on fundamentals in the field and covers current problems, future needs, and prospects in the area of energy and environment from researchers worldwide. Based on selected lectures from the Seventh International Exergy, Energy and Environmental Symposium (IEEES7-2015) and complemented by further invited contributions, this comprehensive set of contributions promote the exchange of new ideas and techniques in energy conversion and conservation in order to exchange best practices in "energetic efficiency". Included are fundamental and historical coverage of the green transportation and sustainable mobility sectors, especially regarding the development of sustainable technologies for thermal comforts and green transportation vehicles. Furthermore, contributions on renewable and sustainable energy sources, strategies for energy production, and the carbon-free society constitute an important part of this book.
Exergy for Better Environment and Sustainability, Volume 1 will appeal to researchers, students, and professionals within engineering and the renewable energy fields.
Exergy for Better Environment and Sustainability, Volume 1 will appeal to researchers, students, and professionals within engineering and the renewable energy fields.
Caracteristici
Serves as a unique source of contemporary knowledge within the interactive fields of exergy, energy, and environment Presents fundamental case studies and historical coverage in the field Includes an editorship of the pioneers of exergy along with key chapters from the leading authorities