RANS Simulations of Premixed Turbulent Flames

Lipatnikov, Andrei

doi:10.1007/978-981-10-7410-3_6

Energy, Environment, and Sustainability

2017

DOI: 10.1007/978-981-10-7410-3_6

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RANS Simulations of Premixed Turbulent Flames

Andrei Lipatnikov

Abstract: The paper aims at assessing a hypothesis that resolution required to evaluate fuel consumption and heat release rates by directly (i.e., without a subgrid model of unresolved influence of small-scale turbulent eddies on the local flame) processing filtered fields of density, temperature, and species mass fractions should be significantly finer than resolution required to directly compute flame surface density by processing the same filtered fields. For this purpose, box filters of various widths Δ are applied … Show more

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Cited by 2 publications

References 138 publications

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A DNS Study of Sensitivity of Scaling Exponents for Premixed Turbulent Consumption Velocity to Transient Effects

Lipatnikov

2018

Flow Turbulence Combust

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3D Direct Numerical Simulations of propagation of a single-reaction wave in forced, statistically stationary, homogeneous, isotropic, and constant-density turbulence, which is not affected by the wave, are performed in order to investigate the influence of the wave development on scaling (power) exponents for the turbulent consumption velocity U T as a function of the rms turbulent velocity u , laminar wave speed S L , and a ratio L 11 /δ F of the longitudinal turbulence length scale L 11 to the laminar wave thickness δ F. Fifteen cases characterized by u /S L = 0.5, 1.0, 2.0, 5.0, or 10.0 and L 11 /δ F = 2.1, 3.7, or 6.7 are studied. Obtained results show that, while U T is well and unambiguously defined in the considered simplest case of a statistically 1D planar turbulent reaction wave, the wave development can significantly change the scaling exponents. Moreover, the scaling exponents depend on a method used to compare values of U T , i.e., the scaling exponents found by processing the DNS data obtained at the same normalized wave-development time may be substantially different from the scaling exponents found by processing the DNS data obtained at the same normalized wave size. These results imply that the scaling exponents obtained from premixed turbulent flames of different configurations may be different not only due to the well-known effects of the mean-flame-brush curvature and the mean flow non-uniformities, but also due to the flame development, even if the different flames are at the same stage of their development. The emphasized transient effects can, at least in part, explain significant scatter of the scaling exponents obtained by various research groups in different experiments, thus, implying that the scatter in itself is not sufficient to reject the notion of turbulent burning velocity. Keywords Premixed turbulent combustion • Burning velocity • Consumption velocity • Turbulent flame development • DNS Nomenclature a heat diffusivity of a mixture c combustion progress variable

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A DNS Study of Sensitivity of Scaling Exponents for Premixed Turbulent Consumption Velocity to Transient Effects

Lipatnikov

2018

Flow Turbulence Combust

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Applications and Analysis Methods of Turbulent Combustion: A Review

Rahmati

2024

Inter J Fluid Mech Res

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Currently, about 80% of the world's energy is generated through the combustion of various fuel types. As this trend is anticipated to persist for the next several decades, combustion technology is poised to retain its pivotal role in energy production. Industries such as power generation, automobile manufacturing, and aerospace engineering invariably rely on combustion engineering applications, all of which frequently involve turbulent flows. Therefore, a comprehensive understanding of the intricate interplay between turbulence and combustion, along with the underlying structure and dynamics of flames, becomes imperative for facilitating optimal design and advancement of these applications. This article undertakes a review of the noteworthy contributions made in recent decades, along with the diverse applications of turbulent combustion across various industries. It provides an overview of computational simulation approaches and experimental methodologies employed in this field. Furthermore, it delves into the current state of knowledge, assessing the capabilities and limitations of present techniques. The article also outlines several ongoing challenges in modeling, indicating pathways for future research endeavors.

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RANS Simulations of Premixed Turbulent Flames

Cited by 2 publications

References 138 publications

A DNS Study of Sensitivity of Scaling Exponents for Premixed Turbulent Consumption Velocity to Transient Effects

A DNS Study of Sensitivity of Scaling Exponents for Premixed Turbulent Consumption Velocity to Transient Effects

Applications and Analysis Methods of Turbulent Combustion: A Review

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