A direct numerical simulation study of vorticity transformation in weakly turbulent premixed flames

Abstract: Database obtained earlier in 3D Direct Numerical Simulations (DNS) of statistically stationary, 1D, planar turbulent flames characterized by three different density ratios σ is processed in order to investigate vorticity transformation in premixed combustion under conditions of moderately weak turbulence (rms turbulent velocity and laminar flame speed are roughly equal to one another). In cases H and M characterized by σ = 7.53 and 5.0, respectively, anisotropic generation of vorticity within the flame brush i… Show more

“…In the present letter, we will restrict ourselves to results obtained in a single case H, characterized by the largest σ = 7.53 because significant amount of flamegenerated vorticity was documented in this case. 17 As shown elsewhere, 18 premixed turbulent flame H [the laminar flame speed S L = 0.6 m/s and thickness δ L = (T b − T u )/max{|∇T |} = 0.217 mm] is well associated with the flamelet combustion regime. 27 The rate A −1 F dA F /dt of an increase in an infinitesimal area A F of a flame surface is well known 28 to be equal to the local stretch rateṡ = ∇ · u − nn : u + S d ∇n.…”

“…Since the data were comprehensively discussed by various research groups, [10][11][12][13][14][15][16][17][18][19][20][21][22][23][24][25][26] we will restrict ourselves to a brief summary of those compressible simulations. They dealt with statistically 1D, planar, adiabatic flames modeled by unsteady 3D continuity, Navier-Stokes, and energy equations, as well as the ideal gas state equation.…”

“…Here, u is the velocity vector, n = −∇c/|∇c| is the unit vector normal to an iso-scalar surface of c(x, t) = const., S d = [∇ · (ρD∇c) + W ]/(ρ|∇c|) is the displacement speed, D is the molecular diffusivity of c, and W is the mass rate of product creation. Accordingly, probabilities of positive and negativeṡ, conditioned on the local enstrophy Ω = ω · ω or baroclinic torque term B = ω · (∇ρ × ∇p)/ρ 2 in the Ω-transport equation, 17 were extracted from the DNS data. Here, ω = ∇ × u is the vorticity vector and p is the pressure.…”

Letter: Does flame-generated vorticity increase turbulent burning velocity?

“…In the present letter, we will restrict ourselves to results obtained in a single case H, characterized by the largest σ = 7.53 because significant amount of flamegenerated vorticity was documented in this case. 17 As shown elsewhere, 18 premixed turbulent flame H [the laminar flame speed S L = 0.6 m/s and thickness δ L = (T b − T u )/max{|∇T |} = 0.217 mm] is well associated with the flamelet combustion regime. 27 The rate A −1 F dA F /dt of an increase in an infinitesimal area A F of a flame surface is well known 28 to be equal to the local stretch rateṡ = ∇ · u − nn : u + S d ∇n.…”

“…Since the data were comprehensively discussed by various research groups, [10][11][12][13][14][15][16][17][18][19][20][21][22][23][24][25][26] we will restrict ourselves to a brief summary of those compressible simulations. They dealt with statistically 1D, planar, adiabatic flames modeled by unsteady 3D continuity, Navier-Stokes, and energy equations, as well as the ideal gas state equation.…”

“…Here, u is the velocity vector, n = −∇c/|∇c| is the unit vector normal to an iso-scalar surface of c(x, t) = const., S d = [∇ · (ρD∇c) + W ]/(ρ|∇c|) is the displacement speed, D is the molecular diffusivity of c, and W is the mass rate of product creation. Accordingly, probabilities of positive and negativeṡ, conditioned on the local enstrophy Ω = ω · ω or baroclinic torque term B = ω · (∇ρ × ∇p)/ρ 2 in the Ω-transport equation, 17 were extracted from the DNS data. Here, ω = ∇ × u is the vorticity vector and p is the pressure.…”

Letter: Does flame-generated vorticity increase turbulent burning velocity?

“…Previous relevant studies on small scale isotropy within premixed flames include those of Hamlington et al, 15,16 Poludnenko, 22 and Lipatnikov et al 23 Lipatnikov et al 23 considered direct numerical simulations (DNSs) at low unburnt Karlovitz numbers (Ka * u = 0.2-0.3, where Ka * u = (l F /l) 1/2 (u o /S L ) 3/2 and l and u o are the integral length and velocity scales, respectively). They found anisotropy in vorticity and related this primarily to the effects of baroclinic torque.…”

“…These goals are accomplished by analyzing a series of DNS with varying Karlovitz numbers, Reynolds numbers, and flame density ratios previously performed by Bobbitt et al 6 The simulations are of statistically one-dimensional, slightly lean n-heptane/air flames using either finite-rate chemistry or tabulated chemistry. Simplified chemical and transport models are often used in numerical simulations of premixed turbulent combustion to reduce the computation cost, 15,16,18,22,23,25 but their impact on vorticity isotropy is not known. By analyzing DNS with different models, their impact on vorticity may be tested.…”

Vorticity isotropy in high Karlovitz number premixed flames

Effects of Lewis and Karlovitz numbers on transport equations for turbulent kinetic energy and enstrophy