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Development of an acoustic diagnostic for determination of heatrelease rate perturbations in pulsated flames

Published online by Cambridge University Press:  20 July 2011

Jingxuan Li ,
Franck Richecoeur  and
Thierry Schuller
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Abstract

Heat release rate fluctuations are the source of combustion instabilities that causerecurrent problems in many combustors. These quantities are difficult to measure andoptical techniques are generally implemented. The initial validation of an alternativemethod is presented in the case of pulsated laminar premixed flames. The technique relieson determining the travel time of ultrasonic waves propagating through the flow. The linkbetween heat release rate fluctuations and perturbations in the travel time of ultrasonicwaves is established. Measurements made with this method are compared with opticalmeasurements and an analytical model. A good agreement is obtained for the gain and phaseof the transfer function between perturbations in the sound travel time and heat releaserate disturbances when the flame is submitted to harmonic modulations of the flow. Thiswork validates the principle of the proposed technique and lays the foundations for futuredevelopments.

Keywords

Heat release rateultrasonic wavespremixed flamessound travel time
Type
Research Article
Information
Mechanics & Industry , Volume 12 , Issue 3: CFM 2011 , 2011 , pp. 157 - 162
Copyright
© AFM, EDP Sciences 2011

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References

Références

Candel, S., Combustion dynamics and control: Progress and challenges, Proc. Comb. Inst. 29 (2002) 128 CrossRefGoogle Scholar
Fayoux, A., Zahringer, K., Gicquel, O., Rolon, J., Experimental and numerical determination of heat release in counterflow premixed laminar flames, Proc. Comb. Inst. 30 (2005) 251257 CrossRefGoogle Scholar
Ayoola, B., Balachandran, R., Frank, J., Mastorakos, E., Kaminski, C., Spatially resolved heat release rate measurements in turbulent premixed flames, Comb. Flame 144 (2006) 116 CrossRefGoogle Scholar
Hurle, I.R., Price, R.B., Sugden, T.M., Thomas, A., Sound emission from open turbulent premixed flames, Royal Soc. London Proc. Ser. A 303 (1968) 409427 CrossRefGoogle Scholar
Price, R., Hurle, I., Sugden, T., Optical studies of the generation of noise in turbulent flames, Symp. (Int.) on Combustion 12 (1969) 10931102 CrossRefGoogle Scholar
Higgins, B., McQuay, M.Q., Lacas, F., Candel, S., An experimental study on the effect of pressure and strain rate on CH chemiluminescence of premixed fuel-lean methane/air flames, Fuel 80 (2001) 15831591 CrossRefGoogle Scholar
Hardalupas, Y., Orain, M., Local measurements of the time dependent heat release rate and equivalence ratio using chemiluminescent emission from a flame, Comb. Flame 139 (2004) 188207 CrossRefGoogle Scholar
Lauer, M., Sattelmayer, T., On the adequacy of chemiluminescence as a measure for heat release in turbulent flames with mixture gradients, J. Eng. Gas Turbine. Power 132 (2010) 18 CrossRefGoogle Scholar
Lieuwen, T., Theory of high frequency acoustic wave scattering by turbulent flames, Comb. Flame 126 (2001) 14891505 CrossRefGoogle Scholar
Lieuwen, T., Rajaram, R., Neumeier, Y., Nair, S., Measurements of incoherent acoustic wave scattering from turbulent premixed flames, Proc. Comb. Inst. 29 (2002) 18091815 CrossRefGoogle Scholar
G. Searby, Instability phenomena during flame propagation. In Combustion Phenomena: Selected mechanisms of flame formation, propagation, and extinction, in: J. Jarosinski and B. Veyssiere (ed.), CRC Press, New York, 2008, pp. 67–79
Fleifil, M., Annaswamy, A.M., Ghoneim, Z.A., Ghoniem, A.F., Response of a laminar premixed flame to flow oscillations: A kinematic model and thermoacoustic instability results, Comb. Flame 106 (1996) 487510 CrossRefGoogle Scholar
Schuller, T., Durox, D., Candel, S., A unified model for the prediction of laminar flame transfer functions: comparisons between conical and V flame dynamics, Comb. Flame 134 (2003) 2134 CrossRefGoogle Scholar
Ducruix, S., Durox, D., Candel, S., Theoretical and experimental determinations of the transfer function of a laminar premixed flame, Proc. Comb. Inst. 28 (2000) 765773 CrossRefGoogle Scholar
Baillot, F., Durox, D., Prud’homme, R., Experimental and theoretical study of a premixed vibrating flame, Comb. Flame 88 (1992) 149168 CrossRefGoogle Scholar
S. Merrill, Radar Handbook, McGraw-Hill, New York, 2008