Self-sustained acoustic-wave interactions with counterflow flames

A. C. ZAMBON; H. K. CHELLIAH

doi:10.1017/S0022112006000498

Abstract

The interaction of acoustic waves with a planar counterflow flame is investigated numerically employing a detailed kinetic model and one-step global kinetic models. The mathematical formulation of quasi-one-dimensional fully unsteady laminar counterflow flames is presented and the governing equations are integrated numerically based on a MacCormack predictor–corrector scheme with second-order accuracy in space. Navier–Stokes characteristic boundary conditions are implemented to accurately represent perfect and partial reflection of acoustic waves at the boundaries. For well-resolved simulations, the occurrence of self-excited flame–acoustics instabilities is analysed in both non-premixed and premixed flames for a range of flow strain rates and flame locations, and employing two finite-rate kinetic models. Unlike the detailed kinetic model, one-step global models with large activation energy and overall reaction order greater than unity promote the amplification of acoustic pressure fluctuations in counterflow non-premixed flames. In contrast, premixed counterflow flames exhibit flame–acoustics instabilities with both kinetic models. While previous unsteady counterflow studies required external perturbations, the resonant unsteady phenomena predicted in this study are self-sustained under favourable boundary conditions. Detailed analyses of the characteristic time scales associated with convection, diffusion, chemistry and acoustics are presented to provide a better understanding of the exact coupling mechanisms.

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Zambon, A.C. and Chelliah, H.K. 2007. Acoustic-wave interactions with counterflow single- and twin-premixed flames: Finite-rate kinetics, heat release and phase effects. Proceedings of the Combustion Institute, Vol. 31, Issue. 1, p. 1247.

Ghosh, Amardip Diao, Qina and Yu, Ken 2007. Experimental Investigation of Shear-Coaxial Injector Flame Stability on Flow Parameters.

Kozubková, M. Kozubek, E. Nevrlý, V. Bitala, P. Štěpánek, O. Dlabka, J. Vašinek, M. Bojko, M. Zelinger, Z. Kubát, P. and Grigorová, E. 2012. The Effect of Nitrogen and Argon Dilution on Methane Oxidation in Laminar Flames. Procedia Engineering, Vol. 42, Issue. , p. 1826.

Ribert, Guillaume and Darabiha, Nasser 2012. Unsteady pressure effects on laminar counterflow H2/air diffusion flames.

Kozubková, M. Krutil, J. and Nevrlý, V. 2014. Experiments and mathematical models of methane flames and explosions in a complex geometry. Combustion, Explosion, and Shock Waves, Vol. 50, Issue. 4, p. 374.

Shchinnikov, P. A. Frantseva, A. A. and Dvortsevoy, A. I. 2019. An Approximate Model of Heat Treatment and Ignition of Coal in Small Cyclones. Thermal Engineering, Vol. 66, Issue. 7, p. 505.

Weiss, Adam D. Sánchez, Antonio L. and Williams, Forman A. 2019. Acoustic Response of Near-Equilibrium Diffusion Flames with Large Activation Energies. AIAA Journal, Vol. 57, Issue. 7, p. 2933.

Weiss, Adam D. Sánchez, Antonio L. and Williams, Forman A. 2019. Accuracies of reduced mechanisms for predicting acoustic combustion instabilities. Combustion and Flame, Vol. 209, Issue. , p. 405.

Shhinnikov, P A Ovchinnikov, Ju V Franceva, A A and Bojko, E E 2019. Kinetic model of ignition and combustion of finely-disperse coal-water fuel. Journal of Physics: Conference Series, Vol. 1261, Issue. 1, p. 012033.

Milan, Petro Junior Hickey, Jean-Pierre Wang, Xingjian and Yang, Vigor 2021. Deep-learning accelerated calculation of real-fluid properties in numerical simulation of complex flowfields. Journal of Computational Physics, Vol. 444, Issue. , p. 110567.

Boyko, E E and Ovchinnikov, Yu V 2021. Engineering a cyclone pre-furnaces’ calculating method for combustion fine water-coal suspensions. IOP Conference Series: Materials Science and Engineering, Vol. 1019, Issue. 1, p. 012064.

Hamdamov, Muzaffar Khujaev, Ismatulla Bazarov, Orifjan and Isabaev, Kasimbek 2021. Axisymmetric turbulent methane jet propagation in a wake air flow under combustion at a finite velocity. IOP Conference Series: Materials Science and Engineering, Vol. 1030, Issue. 1, p. 012163.

Khujaev, I.K. and Hamdamov, M.M. 2021. Axisymmetric Turbulent Methane Jet Propagation in a Co-Current Air Flow Under Combustion at a Finite Velocity. Herald of the Bauman Moscow State Technical University. Series Natural Sciences, p. 89.

Khujaev, I. K. Mirzoyev, A. A. Hamdamov, M. M. and Shirinov, Z. Z. 2022. Numerical simulation of methane-air mixture combustion. Vol. 2637, Issue. , p. 040003.

Latipov, Nusratilla Abduraimova, Dilbar Ibragimova, Zaytuna Otakhonov, Makhsud Hamdamov, M. and Bazarov, D. 2023. Numerical simulation of combustion processes. E3S Web of Conferences, Vol. 401, Issue. , p. 03072.

Khujaev, Ismatulla Ko’shaevich Fayziev, Rabim Alikulovich and Hamdamov, Muzaffar Muhiddinovich 2023. Internet of Things, Smart Spaces, and Next Generation Networks and Systems. Vol. 13772, Issue. , p. 26.

Yao, Matthew X. Hickey, Jean-Pierre and Blanquart, Guillaume 2023. Thermoacoustic response of fully compressible counterflow diffusion flames to acoustic perturbations. Proceedings of the Combustion Institute, Vol. 39, Issue. 4, p. 4711.

Arumapperuma, Geveen Yao, Matthew X. Hickey, Jean-Pierre and Han, Wang 2024. Flame-acoustic interactions in high-pressure H 2 /air diffusion flames . Combustion Theory and Modelling, Vol. 28, Issue. 5, p. 491.

Khujaev, Ismatulla Jumayev, Jurabek and Hamdamov, Muzaffar 2024. Modeling of combustion processes in cylindrical chambers using modern package programs. Vol. 3045, Issue. , p. 060015.

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Self-sustained acoustic-wave interactions with counterflow flames

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Self-sustained acoustic-wave interactions with counterflow flames

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