Surface-averaged quantities in turbulent reacting flows and relevant evolution equations

Abstract: While quantities conditioned to an isosurface of reaction progress variable c, which characterizes fluid state in a turbulent reacting flow, have been attracting rapidly growing interest in the recent literature, a mathematical and physical framework required for research into such quantities has not yet been elaborated properly. This paper aims at filling two fundamental gaps in this area, i.e., (i) ambiguities associated with a definition of a surface-averaged quantity and (ii) the lack of rigorous equations… Show more

“…A brief description will first be given for the derivation of the displacement speed evolution equation, both in an "averaged" as well as a "local" sense. More details on the derivation can be found in Yu and Lipatnikov (2019a). The explanations that follow will be directed toward physical interpretation of equation terms.…”

“…(6) can now be expanded using the product rule to yield [see Ref. Yu and Lipatnikov (2019a) for a more formal derivation] Equation (9) can be rewritten to give a general evolution equation for surface-averaged value of the quantity , which holds on all isosurfaces ĉ ∈ (0, 1) and at time instants and for an arbitrary variable . If is the displacement speed, S d , an equation for surface-averaged S d can then be obtained as long as * * t S d is known.…”

“…In the appendixes B and C of Ref. Yu and Lipatnikov (2019a) it is shown that the two terms in T 1 and T 2 can be recast into a form containing only spatial derivatives which facilitates their extraction from numerical simulations:…”

“…Here we should point out that zero gradient points have been excluded from the definitions of surface average in Eq. (5), see Yu and Lipatnikov (2019a), and Yu and Lipatnikov (2019c), however certain quantities of interest, e.g. S d and K , may locally grow unboundedly large in the neighborhood of a zero-gradient point, which poses a challenge for numerical calculation of surface-averaged quantities.…”

“…In the two frozen-velocity cases A and B, simulations of multiple transient waves c t are performed largely similarly to case C (further details on the difference are discussed in Yu and Lipatnikov (2019a)) but the duration of transient sampling is changed from 2 0 t to 2 F . It is worth noting that the transient data not only is of interest in itself because the vast majority of premixed turbulent flames are developing flames, as discussed in detail elsewhere (Lipatnikov and Chomiak 2002;Lipatnikov 2012), but also offer an opportunity to control the following numerical issue.…”

Assessment of an Evolution Equation for the Displacement Speed of a Constant-Density Reactive Scalar Field

“…A brief description will first be given for the derivation of the displacement speed evolution equation, both in an "averaged" as well as a "local" sense. More details on the derivation can be found in Yu and Lipatnikov (2019a). The explanations that follow will be directed toward physical interpretation of equation terms.…”

“…(6) can now be expanded using the product rule to yield [see Ref. Yu and Lipatnikov (2019a) for a more formal derivation] Equation (9) can be rewritten to give a general evolution equation for surface-averaged value of the quantity , which holds on all isosurfaces ĉ ∈ (0, 1) and at time instants and for an arbitrary variable . If is the displacement speed, S d , an equation for surface-averaged S d can then be obtained as long as * * t S d is known.…”

“…In the appendixes B and C of Ref. Yu and Lipatnikov (2019a) it is shown that the two terms in T 1 and T 2 can be recast into a form containing only spatial derivatives which facilitates their extraction from numerical simulations:…”

“…Here we should point out that zero gradient points have been excluded from the definitions of surface average in Eq. (5), see Yu and Lipatnikov (2019a), and Yu and Lipatnikov (2019c), however certain quantities of interest, e.g. S d and K , may locally grow unboundedly large in the neighborhood of a zero-gradient point, which poses a challenge for numerical calculation of surface-averaged quantities.…”

“…In the two frozen-velocity cases A and B, simulations of multiple transient waves c t are performed largely similarly to case C (further details on the difference are discussed in Yu and Lipatnikov (2019a)) but the duration of transient sampling is changed from 2 0 t to 2 F . It is worth noting that the transient data not only is of interest in itself because the vast majority of premixed turbulent flames are developing flames, as discussed in detail elsewhere (Lipatnikov and Chomiak 2002;Lipatnikov 2012), but also offer an opportunity to control the following numerical issue.…”

Assessment of an Evolution Equation for the Displacement Speed of a Constant-Density Reactive Scalar Field

Evolution of averaged local premixed flame thickness in a turbulent flow

Three questions regarding scalar gradient equations in flamelet theory