Liñán's diffusion flame theory

Last updated April 20, 2019

Liñán diffusion flame theory is a theory developed by Amable Liñán in 1974 to explain the diffusion flame structure using activation energy asymptotics and Damköhler number asymptotics.^[1]^[2]^[3] Liñán used counterflowing jets of fuel and oxidizer to study the diffusion flame structure, analyzing for the entire range of Damköhler number. His theory predicted four different type of flame structure as follows,

Amable Liñán Martínez is a Spanish aeronautical engineer considered a world authority in the field of combustion.

In combustion, a diffusion flame is a flame in which the oxidizer combines with the fuel by diffusion. As a result, the flame speed is limited by the rate of diffusion. Diffusion flames tend to burn slower and to produce more soot than premixed flames because there may not be sufficient oxidizer for the reaction to go to completion, although there are some exceptions to the rule. The soot typically produced in a diffusion flame becomes incandescent from the heat of the flame and lends the flame its readily identifiable orange-yellow color. Diffusion flames tend to have a less-localized flame front than premixed flames.

Activation energy asymptotics (AEA), also known as large activation energy asymptotics, is an asymptotic analysis used in the combustion field utilizing the fact that the reaction rate is extremely sensitive to temperature changes due to the large activation energy of the chemical reaction.

Nearly-frozen ignition regime, where deviations from the frozen flow conditions are small (no reaction sheet exist in this regime),
Partial burning regime, where both fuel and oxidizer cross the reaction zone and enter into the frozen flow on other side,
Premixed flame regime, where only one of the reactants cross the reaction zone, in which case, reaction zone separates a frozen flow region from a near-equilibrium region,
Near-equilibrium diffusion-controlled regime, is a thin reaction zone, separating two near-equilibrium region.

Mathematical description

The theory is well explained in the simplest possible model. Thus, assuming a one-step irreversible Arrhenius law for the combustion chemistry with constant density and transport properties and with unity Lewis number reactants, the governing equation for the non-dimensional temperature field $T(y)$ in the stagnation point flow reduces to

The Lewis number (Le) is a dimensionless number defined as the ratio of thermal diffusivity to mass diffusivity. It is used to characterize fluid flows where there is simultaneous heat and mass transfer.

Stagnation point flow represents a fluid flow in the immediate neighborhood of solid surface at which fluid approaching the surface divides into different streams or a counterflowing fluid streams encountered in experiments. Although the fluid is stagnant everywhere on the solid surface due to no-slip condition, the name stagnation point refers to the stagnation points of inviscid Euler solutions.

{\frac {d^{2}T}{dy^{2}}}+y{\frac {dT}{dy}}=-\mathrm {Da} \ y_{F}y_{O}e^{-T_{a}/T},\quad Z={\frac {1}{2}}\mathrm {erfc} \left({\frac {y}{\sqrt {2}}}\right)

where $Z$ is the mixture fraction, $\mathrm {Da}$ is the Damköhler number, $T_{a}=E/R$ is the activation temperature and the fuel mass fraction and oxidizer mass fraction are scaled with their respective feed stream values, given by

The Damköhler numbers (Da) are dimensionless numbers used in chemical engineering to relate the chemical reaction timescale to the transport phenomena rate occurring in a system. It is named after German chemist Gerhard Damköhler. The Karlovitz number (Ka) is related to the Damköhler number by Da = 1/Ka.

{\begin{aligned}y_{F}&=Z+T_{o}-T\\y_{O}&=(1-Z)/S+T_{o}-T\end{aligned}}

with boundary conditions $T(-\infty )=T(\infty )=T_{o}$ . Here, $T_{o}$ is the unburnt temperature profile (frozen solution) and $S$ is the stoichiometric parameter (mass of oxidizer stream required to burn unit mass of fuel stream). The four regime are analyzed by trying to solve above equations using activation energy asymptotics and Damköhler number asymptotics. The solution to above problem is multi-valued. Treating mixture fraction $Z$ as independent variable reduces the equation to

{\frac {d^{2}T}{dZ^{2}}}=-2\pi e^{y^{2}}\mathrm {Da} \ y_{F}y_{O}e^{-T_{a}/T}

with boundary conditions $T(0)=T(1)=T_{o}$ and $y={\sqrt {2}}\mathrm {erfc} ^{-1}(2Z)$ .

Extinction Damköhler number

The reduced Damköhler number is defined as follows

\delta =8\pi Z_{s}^{2}e^{y_{s}^{2}}\left({\frac {T_{s}^{2}}{T_{a}}}\right)^{3}\mathrm {Da} \ e^{-T_{a}/T}

where $y_{s}={\sqrt {2}}\mathrm {erfc} ^{-1}(2Z_{s}),\ Z_{s}=1/(S+1)$ and $T_{s}=T_{o}+Z_{s}$ . The theory predicted an expression for the reduced Damköhler number at which the flame will extinguish, given by

\delta _{E}=e\left[(1-\gamma )-(1-\gamma )^{2}+0.26(1-\gamma )^{3}+0.055(1-\gamma )^{4}\right]

where $\gamma =1-2(1-\alpha )(1-Z_{s})$ .

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References

↑ Linan, A. (1974). The asymptotic structure of counterflow diffusion flames for large activation energies. Acta Astronautica, 1(7-8), 1007-1039.
↑ Williams, F. A. (1985). Combustion Theory, (1985). Cummings Publ. Co.
↑ Liñán, A., Martínez-Ruiz, D., Vera, M., & Sánchez, A. L. (2017). The large-activation-energy analysis of extinction of counterflow diffusion flames with non-unity Lewis numbers of the fuel. Combustion and Flame, 175, 91-106.

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[1] Linan, A. (1974). The asymptotic structure of counterflow diffusion flames for large activation energies. Acta Astronautica, 1(7-8), 1007-1039.

[2] Williams, F. A. (1985). Combustion Theory, (1985). Cummings Publ. Co.

[3] Liñán, A., Martínez-Ruiz, D., Vera, M., & Sánchez, A. L. (2017). The large-activation-energy analysis of extinction of counterflow diffusion flames with non-unity Lewis numbers of the fuel. Combustion and Flame, 175, 91-106.

Liñán's diffusion flame theory

Contents

Mathematical description

Extinction Damköhler number

See also

Related Research Articles

References