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Heat Transfer in Industrial Combustion

Heat Transfer in Industrial Combustion

by: Charles E. Baukal Jr.

Heat Transfer in Industrial Combustion  library.nu #405527

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language: en [ english ]
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year: 2000
pages: 527
bookmarked: no
paginated: no
vector: yes
cover: yes
searchable: yes
scanned: no

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Industry relies heavily on the combustion process. The already high demand for energy, primarily from combustion, is expected to continue to rapidly increase. Yet, the information is scattered and incomplete, with very little attention paid to the overall combustion system. Designed for practicing engineers, Heat Transfer in Industrial Combustion eclipses the extant literature with an emphasis on the aspects of heat transfer that directly apply to industry.From a practical point of view, the editor organizes relevant papers into a single, coherent resource. The book encompasses heat transfer, thermodynamics, and fluid mechanics, including the little-covered subjects of the use of oxygen to enhance combustion and flame impingement. Maximizing applications and minimizing theory, it covers modes of heat transfer, computer modeling, heat transfer from flame impingement, from burners, low temperature, high temperature, and advanced applications, and more.The theoretical focus of most literature has created a clear need for a practical treatment of the heat transfer as it applies to industrial combustion systems. With detailed coverage and extensive references, Heat Transfer in Industrial Combustion fills this void.

Table of Contents

Introduction Importance of Heat Transfer in Industrial Combustion Literature Discussion Combustion System Components Some Fundamentals of Combustion Combustion Chemistry Combustion Properties Exhaust Product Transport Properties Heat Transfer Modes Introduction Convection Radiation Conduction Phase Change Heat Sources and Sinks Heat Sources Heat Sinks Computer Modeling Combustion Modeling Modeling Approaches Simplified Models Computational Fluid Dynamic Modeling Experimental Techniques Introduction Heat Flux Temperature Gas Flow Gas Species Other Measurements Physical Modeling Flame Impingement Introduction Experimental Conditions Semi-Analytical Heat Transfer Solutions Empirical Heat Transfer Correlations Heat Transfer from Burners Introduction Open-Flame Burners Radiant Burners Effects on Heat Transfer In-Flame Treatment Heat Transfer in Furnaces Introduction Furnaces Heat Recovery Lower Temperature Applications Introduction Ovens and Dryers Fired Heaters Heat Treating Higher Temperature Applications Introduction Metals Industry Minerals Industry Waste Incineration Advanced Combustion Systems Introduction Oxygen-Enhanced Combustion Submerged Combustion Miscellaneous Appendices Reference Sources for Further Information Common Conversions Methods of Expressing Mixture Ratios for CH4, C3H8, and H2
Properties for CH4, C3H8, and H2 Flames Fluid Dynamics Equations Material Properties Author Index Subject Index

Each chapter contains a References section.

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