| Description |
1 online resource |
| Series |
Energy science, engineering and technology |
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Energy science, engineering and technology series.
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| Contents |
HEAT FLUX: PROCESSES, MEASUREMENT TECHNIQUES AND APPLICATIONS; HEAT FLUX: PROCESSES, MEASUREMENT TECHNIQUES AND APPLICATIONS; Library of Congress Cataloging-in-Publication Data; CONTENTS; PREFACE; Chapter 1: Measurement of Heat Flux and Heat Transfer Coefficient; NOMENCLATURE; 1. HEAT FLUX METERS; 1.1. Slug Calorimeters; 1.2. Axial Conduction Probes (Plug-Type Probes); 1.3. Radial Conduction Gauges (Gardon Type Gauges); 2. STEADY-STATE INVERSE METHODS FOR DETERMINING HEAT FLUX AND HEAT TRANSFER COEFFICIENT |
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2.1. Methods for Solving One-Dimensional Inverse Nonlinear Heat Conduction Problems Encountered in Experimental Determination of Boundary Conditions2.2. Inverse Determination of Local Heat Transfer Coefficients; 2.3. Measurement of Heat Flux to Water-Walls In Boiler Combustion Chambers; 3. TRANSIENT INVERSE METHODS; 3.1. Transient Techniques for Determining Steady Heat Flux or Heat Transfer Coefficient; 3.2. Transient Techniques for Determining Time Varying Heat Flux or Heat Transfer Coefficient; 3.3. Space Marching Method for Determining Surface Heat Flux; REFERENCES |
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Chapter 2: Heat Flux Biocalorimetry: A Real-Time Analytical Tool for Bioprocess MonitoringABSTRACT; NOMENCLATURE; ABBREVIATIONS; 1. INTRODUCTION; 2. BIOCALORIMETRIC SENSITIVITY IMPROVEMENT; Baseline Heat Flow Rate Estimation Method; 2.1. Non-Invasive UA Estimation; 3. QUANTITATIVE STUDIES ON KINETICS OF MICROBIAL GROWTH; 3.1. Elemental and Enthalpy Balance for Analyzing Microbial Growth Processes; 3.2. Real-time Estimation of Specific Growth Rate from Heat Rate Data; 3.3. Diauxic Behavior; 4. BIOTHERMODYNAMIC STUDIES; 5. MONITORING AND CONTROL OF BIOPROCESSES |
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5.1. Photoautotrophic Bioprocess Systems5.2. Biological Wastewater Treatment Systems; 6. LARGE-SCALE HEAT FLUX BIOCALORIMETRY; 7. FUTURE PROSPECTS OF BENCH SCALE CALORIMETRY; REFERENCES; Chapter 3: Ability of Soil to Transfer a Large Amount of Heat Under Reduced Air Pressure; ABSTRACT; 1. INTRODUCTION; 2. MATERIALS AND METHODS; 2.1. Soil Samples; 2.2. Measurements of Thermal Conductivity of Soil; 3. RESULTS AND DISCUSSIONS; 3.1. Thermal Conductivity of Three-Phase Soil under Reduced Air Pressure; 3.2. Steady-State Heat Flux of Soil under Reduced Air Pressure; CONCLUSION; REFERENCES |
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Chapter 4: Contributions to the Net Flux in the Mediterranean Sea: Seasonal and Interannual VariationsABSTRACT; 1. INTRODUCTION; 2. DATA; 3. RESULTS AND DISCUSSION; 3.1. Surface Heat Fluxes in the Mediterranean Sea; 3.2. Budgets and Exchange through the Strait of Gibraltar; 4. SUMMARY AND CONCLUDING REMARKS; ACKNOWLEDGMENTS; REFERENCES; Chapter 5: Simulation of Heat Flux Transport in the Edge Plasma of Small Size Divertor Tokamak; ABSTRACT; INTRODUCTION; BASIC TRANSPORT EQUATIONS; (1) Particle Balance Equation; (2)Parallel Momentum Balance for Ions; (3) Parallel Momentum Balance for Electrons |
| Bibliography |
Includes bibliographical references and index |
| Notes |
English |
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Description based on print version record |
| Subject |
Heat flux -- Research
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SCIENCE -- Mechanics -- Thermodynamics.
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| Form |
Electronic book
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| Author |
Cirimele, Gianluca
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D'Elia, Marcello
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| LC no. |
2019713487 |
| ISBN |
9781614709107 |
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1614709106 |
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