Combustion,
Edition 5
By Irvin Glassman, Richard A. Yetter and Nick G. Glumac

Publication Date: 26 Nov 2014
Description

Throughout its previous four editions, Combustion has made a very complex subject both enjoyable and understandable to its student readers and a pleasure for instructors to teach. With its clearly articulated physical and chemical processes of flame combustion and smooth, logical transitions to engineering applications, this new edition continues that tradition. Greatly expanded end-of-chapter problem sets and new areas of combustion engineering applications make it even easier for students to grasp the significance of combustion to a wide range of engineering practice, from transportation to energy generation to environmental impacts.

Combustion engineering is the study of rapid energy and mass transfer usually through the common physical phenomena of flame oxidation. It covers the physics and chemistry of this process and the engineering applications—including power generation in internal combustion automobile engines and gas turbine engines. Renewed concerns about energy efficiency and fuel costs, along with continued concerns over toxic and particulate emissions, make this a crucial area of engineering.

Key Features

  • New chapter on new combustion concepts and technologies, including discussion on nanotechnology as related to combustion, as well as microgravity combustion, microcombustion, and catalytic combustion—all interrelated and discussed by considering scaling issues (e.g., length and time scales)
  • New information on sensitivity analysis of reaction mechanisms and generation and application of reduced mechanisms
  • Expanded coverage of turbulent reactive flows to better illustrate real-world applications
  • Important new sections on stabilization of diffusion flames—for the first time, the concept of triple flames will be introduced and discussed in the context of diffusion flame stabilization
About the author
By Irvin Glassman, Princeton University, NJ, USA; Richard A. Yetter, Penn State University, University Park, USA and Nick G. Glumac, Professor, Department of Mechanical Science & Engineering, University of Illinois, Urbana-Champaign, USA
Table of Contents
  • Dedication 01
  • Dedication 02
  • Preface
  • Chapter 1. Chemical thermodynamics and flame temperatures
    • 1.1. Introduction
    • 1.2. Heats of Reaction and Formation
    • 1.3. Free Energy and the Equilibrium Constants
    • 1.4. Flame Temperature Calculations
    • 1.5. Sub and Supersonic Combustion Thermodynamics
    • Problems
  • Chapter 2. Chemical kinetics
    • 2.1. Introduction
    • 2.2. Rates of Reactions and Their Temperature Dependence
    • 2.3. Simultaneous Interdependent Reactions
    • 2.4. Chain Reactions
    • 2.5. Pseudo-First-Order Reactions and the “Falloff” Range
    • 2.6. The Partial Equilibrium Assumption
    • 2.7. Pressure Effect in Fractional Conversion
    • 2.8. Chemical Kinetics of Large Reaction Mechanisms
    • Problems
  • Chapter 3. Explosive and general oxidative characteristics of fuels
    • 3.1. Introduction
    • 3.2. Chain Branching Reactions and Criteria for Explosion
    • 3.3. Explosion Limits and Oxidation Characteristics of Hydrogen
    • 3.4. Explosion Limits and Oxidation Characteristics of Carbon Monoxide
    • 3.5. Explosion Limits and Oxidation Characteristics of Hydrocarbons
    • 3.6. The Oxidation of Aldehydes
    • 3.7. The Oxidation of Methane
    • 3.8. The Oxidation of Higher-Order Hydrocarbons
    • Problems
  • Chapter 4. Flame phenomena in premixed combustible gases
    • 4.1. Introduction
    • 4.2. Laminar Flame Structure
    • 4.3. Laminar Flame Speed
    • 4.4. Stability Limits of Laminar Flames
    • 4.5. Flame Progagation through Stratified Combustible Mixtures
    • 4.6. Turbulent Reacting Flows and Turbulent Flames
    • 4.7. Stirred Reactor Theory
    • 4.8. Flame Stabilization in High-Velocity Streams
    • 4.9. Combustion in Small Volumes
    • Problems
  • Chapter 5. Detonation
    • 5.1. Introduction
    • 5.2. Detonation Phenomena
    • 5.3. Hugoniot Relations and the Hydrodynamic Theory of Detonations
    • 5.4. Comparison of Detonation Velocity Calculations with Experimental Results
    • 5.5. The ZND Structure of Detonation Waves
    • 5.6. The Structure of the Cellular Detonation Front and Other Detonation Phenomena Parameters
    • 5.7. Detonations in Nongaseous Media
    • Problems
  • Chapter 6. Diffusion flames
    • 6.1. Introduction
    • 6.2. Gaseous Fuel Jets
    • 6.3. Burning of Condensed Phases
    • 6.4. Burning of Droplet Clouds
    • 6.5. Burning in Convective Atmospheres
    • Problems
  • Chapter 7. Ignition
    • 7.1. Concepts
    • 7.2. Chain Spontaneous Ignition
    • 7.3. Thermal Spontaneous Ignition
    • 7.4. Forced Ignition
    • 7.5. Other Ignition Concepts
    • Problems
  • Chapter 8. Environmental combustion considerations
    • 8.1. Introduction
    • 8.2. The Nature of Photochemical Smog
    • 8.3. Formation and Reduction of Nitrogen Oxides
    • 8.4. SOx Emissions
    • 8.5. Particulate Formation
    • 8.6. Stratospheric Ozone
    • Problems
  • Chapter 9. Combustion of nonvolatile fuels
    • 9.1. Carbon Char, Soot, and Metal Combustion
    • 9.2. Metal Combustion Thermodynamics
    • 9.3. Diffusional Kinetics
    • 9.4. Diffusion-Controlled Burning Rate
    • 9.5. Practical Carbonaceous Fuels (C. R. Shaddix)
    • 9.6. Soot Oxidation (C. R. Shaddix)
    • 9.7. Catalytic Combustion
    • Problems
  • Appendixes
  • Appendix A: Thermochemical data and conversion factors
  • Appendix B: Adiabatic flame temperatures of hydrocarbons
  • Appendix C: Specific reaction rate constants
  • Appendix D: Bond dissociation energies of hydrocarbons
  • Appendix E: Flammability limits in air
  • Appendix F: Laminar flame speeds
  • Appendix G: Spontaneous ignition temperature data
  • Appendix H: Minimum spark ignition energies and quenching distances
  • Appendix I: Programs for combustion kinetics
  • Index
Book details
ISBN: 9780124079137
Page Count: 774
Retail Price : £93.99
Audience
Professional engineers, researchers, senior undergraduate and graduate students taking courses in mechanical, chemical, aerospace and automotive engineering