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Destined to clarify the research, development, and design requirements in modern and computational terms needed for sustainable technological advances. Written for the combustion scientist/engineer to understand radiative effects on the pollution of the environment. Interrelates the process of thermodynamics, chemical kinetics, fluid mechanics, heat and mass transfer and turbulence. Includes computational design tools. Lays the foundation for modeling and prediction of chemically reacting combustion systems; collects data for operation of combustion devices. Analyzes the construction, use, and numerical results of combustion systems simulation.
460 pages, ©2005
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Table of contents: |
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Chapter 12: Combustion and Heat Transfer in Furnaces |
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12.2 Heat Transfer in a Well-Stirred Furnace |
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| 12.2.1 Steady-state heat transfer model for a well-stirred furnace |
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| 12.2.2 Dynamic well-stirred furnace |
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| 12.2.3 Model applications |
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12.3 One-Dimensional (Plug-Flow) Furnace Model |
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| 12.3.1 Batch plug-flow furnace model |
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| 12.3.2 Furnaces with continuously moving load |
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12.4 Cylindrical Turbulent Combustion Furnace Models |
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| 12.4.2 Turbulence/combustion and turbulence/radiation modeling |
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| 12.4.3 Applications to furnaces |
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12.5 Multidimensional Furnace Models |
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| 12.5.2 Turbulence/combustion and turbulence/radiation modeling |
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| 12.5.3 Industrial applications |
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12.6 Intensification of Heat Transfer in Furnaces |
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| 12.6.1 Enhancement of flame radiation |
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| 12.6.2 Heat recirculation |
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| 12.6.3 Heat transfer from impinging flame jets |
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12.7 Concluding Summary Remarks |
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