Burke–Schumann flame explained

In combustion, a Burke–Schumann flame is a type of diffusion flame, established at the mouth of the two concentric ducts, by issuing fuel and oxidizer from the two region respectively. It is named after S.P. Burke and T.E.W. Schumann,^[1] ^[2] who were able to predict the flame height and flame shape using their simple analysis of infinitely fast chemistry (which is now called as Burke–Schumann limit) in 1928 at the First symposium on combustion.

Mathematical description

Consider a cylindrical duct with axis along

direction with radius

through which fuel is fed from the bottom and the tube mouth is located at

z=0

. Oxidizer is fed along the same axis, but in the concentric tube of radius

outside the fuel tube. Let the mass fraction in the fuel tube be

Y_Fo

and the mass fraction of the oxygen in the outside duct be

Y_Oo

. Fuel and oxygen mixing occurs in the region

z>0

. The following assumptions were made in the analysis:

The average velocity is parallel to axis (

direction) of the ducts,

v=ve_z

The mass flux in the axial direction is constant,

\rhov=constant

Axial diffusion is negligible compared to the transverse/radial diffusion
The flame occurs infinitely fast (Burke–Schumann limit), therefore flame appears as a reaction sheet across which properties of flow changes
Effects of gravity has been neglected

Consider a one-step irreversible Arrhenius law,

Fuel+sO_{2 →}(1+s)Products+q

, where

is the mass of oxygen required to burn unit mass of fuel and

is the amount of heat released per unit mass of fuel burned. If

\omega

is the mass of fuel burned per unit volume per unit time and introducing the non-dimensional fuel and mass fraction and the Stoichiometry parameter,

y_F=

	Y_F
	Y_Fo

, y_O=

	Y_O
	Y_Oo

, S=

	sY_Fo
	Y_Oo

the governing equations for fuel and oxidizer mass fraction reduce to

\begin{align}	\rhoD_T
	r

	\partial	\left(r
	\partialr

	\partialy_F
	\partialr

\right)-\rhov

	\partialy_F
	\partialz

	\omega	\\
	Y_Fo

	\rhoD_T
	r

	\partial	\left(r
	\partialr

	\partialy_O
	\partialr

\right)-\rhov

	\partialy_O
	\partialz

	\omega
	Y_Fo

\\ \end{align}

where Lewis number of both species is assumed to be unity and

\rhoD_T

is assumed to be constant, where

D_T

is the thermal diffusivity. The boundary conditions for the problem are

\begin{align} at&z=0,0<r<a,y_F=1,y_O=0,\\
at&z=0,a<r<b,y_F=0,y_O=1,\\
at&r=b,0<z<infty,

	\partialy_F
	\partialr

=0,

	\partialy_O
	\partialr

=0. \end{align}

The equation can be linearly combined to eliminate the non-linear reaction term

\omega/Y_Fo

and solve for the new variable

	Sy_F-y_O+1
	S+1

where

is known as the mixture fraction. The mixture fraction takes the value of unity in the fuel stream and zero in the oxidizer stream and it is a scalar field which is not affected by the reaction. The equation satisfied by

	1
	r

	\partial	\left(r
	\partialr

	\partialZ
	\partialr

\right)-

	\rhov
	\rhoD_T

	\partialZ
	\partialz

(If the Lewis numbers of fuel and oxidizer are not equal to unity, then the equation satisfied by

is nonlinear as follows from Shvab–Zeldovich–Liñán formulation). Introducing the following coordinate transformation

\xi=

	r
	b

, η=

	\rhoD_T
	\rhov

	z
	b²

, c=

	a
	b

reduces the equation to

	1
	\xi

	\partial	\left(\xi
	\partial\xi

	\partialZ
	\partial\xi

\right)-

	\partialZ
	\partialη

=0.

The corresponding boundary conditions become

\begin{align} at&η=0,0<\xi<c,Z=1,\\ at&η=0,c<\xi<1,Z=0,\\ at&\xi=1,0<η<infty,

	\partialZ
	\partial\xi

=0. \end{align}

The equation can be solved by separation of variables

Z(\xi,η)=c²+2c

	infty
\sum
	n=1

	1
	λ_n

J_1(cλ_n)

	2(λ
J
	n)

J_0(λ_n

	2η
-λ
	n

\xi)e

where

J₀

and

J₁

are the Bessel function of the first kind and

λ_n

is the nth root of

J_1(λ)=0.

Solution can also be obtained for the planar ducts instead of the axisymmetric ducts discussed here.

^[3] ^[4]

Flame shape and height

In the Burke-Schumann limit, the flame is considered as a thin reaction sheet outside which both fuel and oxygen cannot exist together, i.e.,

y_Fy_O=0

. The reaction sheet itself is located by the stoichiometric surface where

Sy_F=y_O

, in other words, where

Z=Z_s\equiv

	1
	S+1

where

Z_s

is the stoichiometric mixture fraction. The reaction sheet separates fuel and oxidizer region. The inner structure of the reaction sheet is described by Liñán's equation. On the fuel side of the reaction sheet (

Z>Z_s

)

y_F=

	Z-Z_s
	1-Z_s

,y_O=0

and on the oxidizer side (

Z<Z_s

)

y_F=0,y_O=1-

	Z
	Z_s

For given values of

Z_s

(or,

) and

, the flame shape is given by the condition

Z(\xi,η)=Z_s

, i.e.,

	2
Z
	s=c

+2c

	infty
\sum
	n=1

	1
	λ_n

J_1(cλ_n)

	2(λ
J
	n)

J_0(λ_n

	2η
-λ
	n

\xi)e

When

Z_{s →}0

(

S → infty

), the flame extends from the mouth of the inner tube and attaches itself to the outer tube at a certain height (under-ventilated case) and when

Z_{s →}1

(

S → 0

), the flame starts from the mouth of the inner tube and joins at the axis at some height away from the mouth (over-ventilated case). In general, the flame height is obtained by solving for

in the above equation after setting

\xi=1

for the under-ventilated case and

\xi=0

for the over-ventilated case.

Since flame heights are generally large for the exponential terms in the series to be negligible, as a first approximation flame height can be estimated by keeping only the first term of the series. This approximation predicts flame heights for both cases as follows

\begin{align} η&=

	2
λ
	1

ln\left[

2cJ_1(cλ₁₎

	2)λ
(Z		J_0(λ₁₎
	1

\right], under-ventilated\\ η&=

	2
λ
	1

ln\left[

2cJ_1(cλ₁₎

2)λ

	2(λ
J
	1)

\right], over-ventilated, \end{align}

where

λ_1=3.8317.

Notes and References

Burke, S. P., and T. E. W. Schumann. "Diffusion flames." Industrial & Engineering Chemistry 20.10 (1928): 998–1004.
Zeldovich, I. A., Barenblatt, G. I., Librovich, V. B., & Makhviladze, G. M. (1985). Mathematical theory of combustion and explosions.
Williams, F. A. (2018). Combustion theory. CRC Press.
Williams, F. A. (1965). Combustion Theory: the fundamental theory of chemical reacting flow systems. Addison-Wesley.