Propagation of Nonstationary Curved and Stretched Premixed Flames with Multistep Reaction Mechanisms

• Published in: Combustion science and technology Vol. 174; no. 8; pp. 1 - 43
• Main Authors: Klimenko, A. Y., Class, A. G.
• Format: Journal Article
• Language: English
• Published: London Taylor & Francis Group 01.07.2002; Taylor & Francis
• Subjects: Applied sciences; Combustion. Flame; Energy; Energy. Thermal use of fuels; Exact sciences and technology; Theoretical studies; Theoretical studies. Data and constants. Metering; Reaction mechanism; Flame structure; Premixed flame; Flow velocity; Combustion; Asymptotic approximation; Flame propagation; Modeling; Stretching
• ISSN: 0010-2202; 1563-521X
• DOI: 10.1080/00102200290021317

The propagation speed of a thin premixed flame disturbed by an unsteady fluid flow of a larger scale is considered. The flame may also have a general shape but the reaction zone is assumed to be thin compared to the flame thickness. Unlike in preceding publications, the presented asymptotic analysis is performed for a general multistep reaction mechanism and, at the same time, the flame front is curved by the fluid flow. The resulting equations define the propagation speed of disturbed flames in terms of the properties of undisturbed planar flames and the flame stretch. Special attention is paid to the near-equidiffusion limit. In this case, the flame propagation speed is shown to depend on the effective Zeldovich number Z f , and the flame stretch. Unlike the conventional Zeldovich number, the effective Zeldovich number is not necessarily linked directly to the activation energies of the reactions. Several examples of determining the effective Zeldovich number for reduced combustion mechanisms are given while, for realistic reactions, the effective Zeldovich number is determined from experiments. Another feature of the present approach is represented by the relatively simple asymptotic technique based on the adaptive generalized curvilinear system of coordinates attached to the flame (i.e., intrinsic disturbed flame equations [IDFE]).