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Numerical investigation of the effect of signal trapping on soot measurements using LII in laminar coflow diffusion flames

 
 
Affiliation:
NRC Institute for Chemical Process and Environmental Technology (ICPET-ITPCE); National Research Council Canada
Language:
English
Type:
Conference publication
Conference:
Ninth Asia-Pacific International Symposium on Combustion and Energy Utilization, Beijing, CN, November 2-6, 2008
Proceedings
Title:
Applied Physics B
Date:
2009
Pages :
671-682
NRCC #:
51614
NPArC #:
9069436
Keywords:
Laser-induced incandescence (LII); soot measurements; Rayleigh–Debye–Gans polydisperse fractal aggregate theory; laminar coflow diffusion flames; axisymmetric flames
Abstract:
Laser-induced incandescence has been rapidly developed into a powerful diagnostic technique for measurements of soot in many applications. The incandescence intensity generated by laser-heated soot particles at the measurement location suffers the signal trapping effect caused by absorption and scattering by soot particles present between the measurement location and the detector. The signal trapping effect was numerically investigated in soot measurements using both a 2D LII setup and the corresponding point LII setup at detection wavelengths of 400 and 780 nm in a laminar coflow ethylene/air flame. The radiative properties of aggregated soot particles were calculated using the Rayleigh–Debye–Gans polydisperse fractal aggregate theory. The radiative transfer equation in emitting, absorbing, and scattering media was solved using the discrete-ordinates method. The radiation intensity along an arbitrary direction was obtained using the infinitely small weight technique. The contribution of scattering to signal trapping was found to be negligible in atmospheric laminar diffusion flames. When uncorrected LII intensities are used to determine soot particle temperature and the soot volume fraction, the errors are smaller in 2D LII setup where soot particles are excited by a laser sheet. The simple Beer–Lambert exponential attenuation relationship holds in LII applications to axisymmetric flames as long as the effective extinction coefficient is adequately defined.
 
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