Numerical and experimental investigation of methane-oxygen detonation in a 9 m long tube

• Autorzy: Malik K. , Żbikowski M. , Teodorczyk A. , Lesiak P.

Identyfikatory

DOI

10.5604/12314005.1217241

• Języki publikacji: EN

Abstrakty

EN

Numerical investigation of methane-oxygen detonation parameters was conducted with an OpenFoam code. Custom solver ddtFoam made especially for detonation problems was made use of. It uses the HLLC scheme to resolve the discontinuities and the subgridscale model to improve results on coarse meshes. Combustion model is based on progress variable equation, which contains two source terms. The first is the deflagrative source term and is modelled using the Weller correlation. The second is the detonative source term and it accounts for autoignition effects. Range of analysed gaseous mixture compositions was 20, 33 and 40% of methane in oxygen. The 2D calculation geometry was a 9 m long pipe with diameter 0.17 m. The mesh consisted of 382 500 hexahedral cells with the dimensions of 2x2 mm. Experimental results such as pressure profiles and detonation velocities are presented. Simulations were performed using LES turbulence model (k-equation-eddy-viscosity model) and compared with experimental data. Various dynamic parameters, like for example reaction lengths for methane-oxygen detonations, are estimated from the steady ZND analyses conducted in Cantera and SDToolbox libraries and based on GRI 3.0 kinetic mechanism of methane combustion. These lengths were then used in empirical formulas to obtain the characteristic cell sizes and assessed against experimental data.

Słowa kluczowe

EN

detonation; methane; combustion; simulation; experiment; characteristic cell size

• Wydawca: Łukasiewicz Research Network - Institute of Aviation ; European Science Society of Powertrain and Transport KONES Poland ; Wydawnictwo Instytutu Technicznego Wojsk Lotniczych
• Czasopismo: Journal of KONES
• Rocznik: 2016
• Tom: Vol. 23, No. 4
• Strony: 311--318
• Opis fizyczny: Bibliogr. 15 poz., rys.

Twórcy

autor

Malik K.

• Warsaw University of Technology Institute of Heat Engineering Nowowiejska Street 21/25, 00-665 Warsaw, Poland tel.: +48 691 522 238, +48 22 2345226

autor

Żbikowski M.

• Warsaw University of Technology Institute of Heat Engineering Nowowiejska Street 21/25, 00-665 Warsaw, Poland tel.: +48 691 522 238, +48 22 2345226

autor

Teodorczyk A.

• Warsaw University of Technology Institute of Heat Engineering Nowowiejska Street 21/25, 00-665 Warsaw, Poland tel.: +48 691 522 238, +48 22 2345226

autor

Lesiak P.

• Scientific and Research Centre for Fire Protection National Research Institute Nadwiślańska Avenue 213, 05-420 Józefów, Poland

Bibliografia

• [1] Clavin, P., Theory of Gaseous Detonations, Université d’Aix-Marseille, 2004.
• [2] Ettner, F., Vollmer, K. G., Sattelmayer, T., Numerical simulation of the Deflagration-to-detonation transition in inhomogeneous mixtures, Technische Universität München, Garching 2014.
• [3] Fickett, W., Davis W., Detonation: Theory and Experiment, University of California Press, Berkeley, California 1979.
• [4] Gavrikov, A.I., Efimenko, A.A., Dorofeev, S.B., A model for detonation cell size prediction from chemical kinetics, Russian Research Center, Kurchatov Institute, Russia 1999.
• [5] Morgan, G., The Euler equations with a single-step Arrhenius reaction, University of Cambridge, Cambridge 2013.
• [6] Shepherd, J.E., Chemical kinetics of hydrogen-air-diluent detonations, Progress in Astronautics and Aeronautics, American Institute of Aeronautics and Astronautics, 1986.
• [7] Shepherd, J.E., Detonation: A look behind the front, 19th International Colloquium on the Dynamics of Explosions and Reactive Systems, Japan 2003.
• [8] Stamps, W.D., Slezak, S.E., Tieszen, S.R., Observations of the cellular structure of fuel–air detonations, Elsevier, 2005.
• [9] Toro, E.F., Spruce, M., Speares, W., Restoration of the contact surface in the HLL-Riemann solver, Cranfield Institute of Technology, Cranfield 1993.
• [10] Weller, H.G., Tabor, G., Gosman, A.D. and Fureby, C., Application of a flame-wrinkling LES combustion model to a turbulent mixing layer, Symposium on Combustion, 1998.
• [11] Wilcox, D.C., Turbulence modelling for CFD, DCW Industries, La Cañada Flintridge, 2006.
• [12] OpenFoam. The Open Source CFD Toolbox. User Guide, Version 2.1.1, 2012.
• [13] http://combustion.berkeley.edu/gri-mech/version30/text30.html, web page, accessed 5.07. 2016.
• [14] http://www.cantera.org/docs/sphinx/html/index.html, web page, accessed 5.07.2016.
• [15] http://shepherd.caltech.edu/EDL/public/cantera/html/SD_Toolbox/, web page, accessed 5.07. 2016.

Uwagi

PL

Opracowanie ze środków MNiSW w ramach umowy 812/P-DUN/2016 na działalność upowszechniającą naukę.