Book contents
- Frontmatter
- Contents
- Preface
- Symbols and Acronyms
- 1 Introduction
- 2 Thermodynamics of a Pure Substance
- 3 Thermodynamics of Gaseous Mixtures
- 4 Chemical Equilibrium
- 5 Chemical Kinetics
- 6 Derivation of Transport Equations
- 7 Thermochemical Reactors
- 8 Premixed Flames
- 9 Diffusion Flames
- 10 Combustion of Particles and Droplets
- 11 Combustion Applications
- APPENDIX A Thermochemistry Data
- APPENDIX B Curve-Fit Coefficients for Δhc, Tad, Kp, Cp, h, and s
- APPENDIX C Properties of Fuels
- APPENDIX D Thermophysical and Transport Properties of Gases
- APPENDIX E Atmospheric Data
- APPENDIX F Binary Diffusion Coefficients at 1 atm and T = 300K
- Bibliography
- Index
8 - Premixed Flames
- Frontmatter
- Contents
- Preface
- Symbols and Acronyms
- 1 Introduction
- 2 Thermodynamics of a Pure Substance
- 3 Thermodynamics of Gaseous Mixtures
- 4 Chemical Equilibrium
- 5 Chemical Kinetics
- 6 Derivation of Transport Equations
- 7 Thermochemical Reactors
- 8 Premixed Flames
- 9 Diffusion Flames
- 10 Combustion of Particles and Droplets
- 11 Combustion Applications
- APPENDIX A Thermochemistry Data
- APPENDIX B Curve-Fit Coefficients for Δhc, Tad, Kp, Cp, h, and s
- APPENDIX C Properties of Fuels
- APPENDIX D Thermophysical and Transport Properties of Gases
- APPENDIX E Atmospheric Data
- APPENDIX F Binary Diffusion Coefficients at 1 atm and T = 300K
- Bibliography
- Index
Summary
Introduction
Our interest in this chapter is to look inside the thermochemical reactors discussed in the previous chapter. Inside the reactors, the formation of a visible flame is one obvious phenomenon. Flames are of two types, (a) premixed flames and (b) nonpremixed, or diffusion flames. A Bunsen burner, shown in Figure 8.1, is a very good example in which both types of flames are produced. In this burner, air and fuel are mixed in the mixing tube; this premixed mixture burns, forming a conical flame of finite thickness (typically, blue in color). This is called the premixed flame. It is so called because the oxygen required for combustion is obtained mainly from air, which is mixed with the fuel. This premixed combustion releases a variety of species, stable and unstable. Principally, the carbon monoxide resulting from the fuel-rich combustion burns in the outer diffusion flame. The oxygen required for combustion in this part of the flame is obtained from the surrounding air by diffusion (or by entrainment). The overall flame shape is determined by the magnitude of the mixture velocity and its profile as it escapes the burner tube, coupled with the extent of heat losses from the tube wall.
Unlike in premixed flames, in pure diffusion flames, the sources of fuel and oxidizer are physically separated. The candle flame shown in Figure 8.2(a) is an example of such a flame. When wax is melted, it flows up the wick and is vaporized as fuel.
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- Information
- Analytic CombustionWith Thermodynamics, Chemical Kinetics and Mass Transfer, pp. 164 - 197Publisher: Cambridge University PressPrint publication year: 2011