Interactions Between The Reaction Zone And Soot Field In A Laminar Boundary Layer Type Diffusion Flame

Interactions Between the Reaction Zone and Soot Field in a Laminar Boundary Layer Type Diffusion Flame

Author : Andrés Fuentes

Publisher :

Page : pages

File Size : 37,39 MB

Release : 2006

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ISBN :

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Book Description

The concurrent spreading of a boundary layer type diffusion flame is studied. The impossibility of obtaining a low velocity laminar flow without any perturbation induced by buoyancy has lead to the development of an experimental apparatus for use in micro-gravity facilities. Based on previous experimental observations, an original numerical approach has been developed showing, first the dominating role of the radiative heat transfer on the structure of the flame and second the major role of the soot on the extinction phenomenon at the flame trailing edge. The influence of the forced flow velocity, the fuel injection velocity and oxygen concentration on the geometry of the flame has been examined by imaging of CH* and OH* radicals spontaneous emission. Laser-Induced Incandescence (LII) is used to determine the soot field concentration in the flame. The soot formation has been studied by Laser Induced Fluorescence (LIF) of Polycyclic Aromatic Hydrocarbons (PAHs). The interaction between the reaction zone and the field of soot formation/oxidation is taken into account to analyze the flame length. These results can be used as the experimental input data for a future complete validation of numerical model simulating the soot formation and oxidation in this kind of flame.



On the Internal Structure of Laminar Diffusion Flames

Author : AMABLE. LINAN

Publisher :

Page : 1 pages

File Size : 12,4 MB

Release : 1961

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A study was carried out on the influence of chemical kinetics on laminar diffusion flames. In most of the flames of practical interest, the reaction zone is of negligible thickness, making it possible to obtain a solution of the boundary layer type. At each side of the reaction zone the temperature and concentration distributions may be determined by using the Burke-Schumann assumption of infinitely fast reaction rate. In the reaction zone, or chemical boundary layer, the convection effects may be neglected as compared with chemical reaction, conduction and diffusion effects. The equations governing this layer take then a simple for ; and from their solution a criterium for the validity of BurkeSchumann assumption and for flame extinction may be obtained. (Author).







On the Structure of Laminar Diffusion Flames

Author : Amable Liñán

Publisher :

Page : 43 pages

File Size : 29,85 MB

Release : 1963

Category : Electronic dissertations

ISBN :

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The structure of laminar diffusion flames is analyzed in the limiting case of large, although finite, reaction rates. It is shown that the chemical reaction takes place only in a very thin region or chemical boundary layer where convection effects may be neglected. Then the temperature and mass fraction distributions within the reaction zone are obtained analytically. The flame position, rates of fuel consumption, and temperature and concentration distributions outside of the reaction zone may be obtained by using the assumption of infinite reaction rates. For large Reynolds numbers mixing and combustion take place in boundary layers and free mixing layers. And again analytical solutions are obtained for the temperature and mass fraction distributions outside of the reaction zone. (Author).











Laminar Soot Processes (Lsp)

Author : National Aeronautics and Space Administration (NASA)

Publisher : Createspace Independent Publishing Platform

Page : 58 pages

File Size : 43,14 MB

Release : 2018-06

Category :

ISBN : 9781720608042

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Book Description

This is the final report of a research program considering the structure and the soot surface reaction properties of laminar nonpremixed (diffusion) flames. The study was limited to ground-based measurements of buoyant laminar jet diffusion flames at pressures of 0.1-1.0 atm. The motivation for the research is that soot formation in flames is a major unresolved problem of combustion science that influences the pollutant emissions, durability and performance of power and propulsion systems, as well as the potential for developing computational combustion. The investigation was divided into two phases considering the structure of laminar soot-containing diffusion flames and the soot surface reaction properties (soot surface growth and oxidation) of these flames, in turn. The first phase of the research addressed flame and soot structure properties of buoyant laminar jet diffusion flames at various pressures. The measurements showed that H, OH and O radical concentrations were generally in superequilibrium concentrations at atmospheric pressure but tended toward subequilibrium concentrations as pressures decreased. The measurements indicated that the original fuel decomposed into more robust compounds at elevated temperatures, such as acetylene (unless the original fuel was acetylene) and H, which are the major reactants for soot surface growth, and that the main effect of the parent fuel on soot surface growth involved its yield of acetylene and H for present test conditions. The second phase of the research addressed soot surface reaction properties, e.g., soot surface growth and surface oxidation. It was found that soot surface growth rates in both laminar premixed and diffusion flames were in good agreement, that these rates were relatively independent of fuel type, and that these rates could be correlated by the Hydrogen-Abstraction/Carbon-Addition (HACA) mechanisms of Colket and Hall (1994), Frenklach et al. (1990,1994), and Kazakov et al. (1995). It was also fou