Intro; Preface; Contents; About the Editors; Part I: Heat and Mass Transfer, and Fluid Mechanics; Dynamic Study of a Metal Hydride Pump; 1 Introduction; 2 System Description and Operation Concept of MHP; 3 Mathematical Model; 3.1 Energy Equation; 3.2 Mass Balance; 3.3 Kinetic Reaction; 3.4 Equilibrium Pressure; 3.5 Pressure Evolution; 3.6 Specific Water Discharge; 3.7 The Total Heat Input; 3.8 Pump Efficiency; 4 Results and Discussions; 4.1 Effect of Heating Temperature; 4.2 Effect of Desorption Gear Ratio; 4.3 Effect of Pump Piston Area; 5 Conclusions; References.
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3 Mathematics3.1 Productivity Statistics Formula for Directional Well; 3.2 Productivity Simulation Formula for Directional Well; 3.3 Productivity Simulation Formula for Horizontal Well; 3.4 Formula for Gradient Stress Calculation; 3.5 Formula for Minimum Horizontal Pressure Calculation; 4 Selection of Layers and Wells; 5 Numerical Simulation; 5.1 Establishment; 5.2 Matching of the Fracture; 5.3 Matching of the Reservoir Permeability; 6 Results; 6.1 Productivity of Directional Well; 6.2 Productivity of Horizontal Well; 6.3 Gradient Stress; 6.4 Productivity of New Horizontal Well by Simulation.
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3.5 Experiment for the Effect of Immobile Water Saturation3.6 Experiment for Gas-Water Flow Under High Pressure; 4 Results; 4.1 Physical Property and Classification; 4.2 Water Saturation Testing by NMR; 4.3 Gas Flow Mechanism Under High Pressure; 4.4 Effect of Crustal Stress; 4.5 Effec of Immobile Water Saturation; 4.6 Effect of Threshold Pressure; 4.7 Gas-Water Flow Mechanism Under High Pressure; 5 Conclusions; References; Thermal and Dynamic Characteristics of an Airflow in a Channel Provided with Circular and Triangular Cavities; 1 Introduction; 2 Mathematical Formulation.
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7 Sensitivity Analysis8 Uncertainty Analysis; 8.1 Uncertainties on Reserve; 8.2 Uncertainties on Permeability; 8.3 Uncertainties on Production After Fracturing; 9 Conclusions; References; Study of Porous Flow Mechanism for Low-Permeability Sandstone by the Use of NMR; 1 Introduction; 2 Mathematics; 2.1 Nuclear Magnetic Resonance; 2.2 Effect of Crustal Stress; 3 Experiments; 3.1 Experiment for Water-Gas Distribution; 3.2 Experiment for Measurement of Water Saturation by NMR; 3.3 Experiment for Gas Flow Mechanism Under High Pressure; 3.4 Experiment for the Effect of Crustal Stress.
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SUMMARY OR ABSTRACT
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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.
ACQUISITION INFORMATION NOTE
Source for Acquisition/Subscription Address
Springer Nature
Stock Number
com.springer.onix.9783319625720
OTHER EDITION IN ANOTHER MEDIUM
Title
Exergy for a better environment and improved sustainability. 1, Fundamentals.
International Standard Book Number
3319625713
PARALLEL TITLE PROPER
Parallel Title
Fundamentals
TOPICAL NAME USED AS SUBJECT
Exergy.
Sustainable development.
Thermodynamics.
Energy Efficiency.
Energy.
Engineering Fluid Dynamics.
Mechanical Engineering.
Renewable and Green Energy.
Sustainable Development.
Transportation.
Alternative & renewable energy sources & technology.