Spectrally Resolved Measurement of Flame Radiation to Determine Soot Temperature and Concentration

A multiwavelength flame emission technique is developed for high spatial resolution determination of soot temperature and soot volume fraction in axisymmetric laminar diffusion flames. Horizontal scans of line-integrated spectra are collected over a spectral range of 500-945 nm. Inversion of these data through one-dimensional tomography using a three-point Abel inversion yields radial distributions of the soot radiation from which temperature profiles are extracted. From an absolute calibration of the flame emission and by use of these temperature data, absorption coefficients are calculated, which are directly proportional to the soot volume fractions. The important optical parameters are discussed. It is shown that a uniform sampling cross section through the flame must be maintained and that variations in sampling area produce inconsistencies between measurements and theory, which cannot be interpreted as spatial averaging of the property field. The variations in cross-sectional sampling area have the largest influence on the measurements at the edges of the flame, where the highest resolution is required. Emission attenuation by soot has been shown to have minor influence on the soot temperature and soot volume fraction for the soot loading of the axisymmetric flame tested. An emission correction scheme is outlined, which could be used for more heavily sooting flames. For a refractive index absorption function E(m) = Im[(m 2 - 1)/(m 2 + 2)] that is independent of wavelength, the soot temperatures and soot volume fractions measured with this technique are in excellent agreement with data obtained by coherent anti-Stokes Raman scattering nitrogen thermometry and two-dimensional soot extinction in the same ethylene coflow diffusion flame. The agreement of the results suggests a limit of the slope of the spectral response of E(m) to be between 0 and 20% over the spectral range examined.

[1]  W. Bachalo,et al.  A Calibration-Independent Technique of Measuring Soot by Laser-Induced Incandescence Using Absolute Light Intensity , 2001 .

[2]  G. Faeth,et al.  Optical Properties in the Visible of Overfire Soot in Large Buoyant Turbulent Diffusion Flames , 2000 .

[3]  Ö. Gülder,et al.  Two-dimensional imaging of soot volume fraction in laminar diffusion flames. , 1999, Applied optics.

[4]  M. Barbini,et al.  Determination of the Soot Volume Fraction in an Ethylene Diffusion Flame by Multiwavelength Analysis of Soot Radiation , 1998 .

[5]  N Ladommatos,et al.  Optical diagnostics for soot and temperature measurement in diesel engines , 1998 .

[6]  Gerard M. Faeth,et al.  Refractive Indices at Visible Wavelengths of Soot Emitted From Buoyant Turbulent Diffusion Flames , 1997 .

[7]  Ümit Özgür Köylü Quantitative analysis of in situ optical diagnostics for inferring particle/aggregate parameters in flames : Implications for soot surface growth and total emissivity , 1997 .

[8]  J. Seitzman,et al.  Soot volume fraction and particle size measurements with laser-induced incandescence. , 1997, Applied optics.

[9]  Christopher R. Shaddix,et al.  The elusive history of m∼= 1.57 – 0.56i for the refractive index of soot , 1996 .

[10]  G. M. Faeth,et al.  Spectral extinction coefficients of soot aggregates from turbulent diffusion flames , 1996 .

[11]  Ö. Gülder,et al.  Influence of hydrogen addition to fuel on temperature field and soot formation in diffusion flames , 1996 .

[12]  Ümit Özgür Köylü,et al.  Optical Properties of Soot in Buoyant Laminar Diffusion Flames , 1994 .

[13]  Takashi Kashiwagi,et al.  Simultaneous optical measurement of soot volume fraction and temperature in premixed flames , 1994 .

[14]  Ümit Özgür Köylü,et al.  Optical Properties of Overfire Soot in Buoyant Turbulent Diffusion Flames At Long Residence Times , 1994 .

[15]  T. T. Charalampopoulos,et al.  Refractive indices of pyrolytic graphite, amorphous carbon, and flame soot in the temperature range 25° to 600°C☆ , 1993 .

[16]  Jay P. Gore,et al.  Temperature and soot volume fraction statistics in toluene-fired pool fires , 1993 .

[17]  C. Dasch,et al.  One-dimensional tomography: a comparison of Abel, onion-peeling, and filtered backprojection methods. , 1992, Applied optics.

[18]  Takashi Kashiwagi,et al.  Radiative heat feedback in a toluene pool fire , 1992 .

[19]  C. Megaridis,et al.  Absorption and scattering of light by polydisperse aggregates. , 1991, Applied optics.

[20]  R. J. Hall,et al.  Fractal properties of soot agglomerates , 1991 .

[21]  H. Semerjian,et al.  Analysis of light scattering from soot using optical cross sections for aggregates , 1991 .

[22]  R. J. Hall,et al.  Sooting flame thermometry using emission/absorption tomography. , 1990, Applied optics.

[23]  Robert J. Santoro,et al.  The Transport and Growth of Soot Particles in Laminar Diffusion Flames , 1987 .

[24]  Constantine M. Megaridis,et al.  Morphology of flame-generated soot as determined by thermophoretic sampling , 1987 .

[25]  J. Hessler,et al.  Spectral emissivity of tungsten: analytic expressions for the 340-nm to 2.6-microm spectral region. , 1984, Applied optics.

[26]  Rudolf O. Müller,et al.  Absorption and Scattering of X-Rays , 1972 .

[27]  A. F. Sarofim,et al.  Optical Constants of Soot and Their Application to Heat-Flux Calculations , 1969 .

[28]  R. Porter Numerical Solution for Local Emission Coefficients in Axisymmetric Self-Absorbed Sources , 1964 .