In Combustion, G equation is a scalar field equation which describes the instantaneous flame position, introduced by Forman A. Williams in 1985[1][2] in the study of premixed turbulent combustion. The equation is derived based on the Level-set method. The equation was first studied by George H. Markstein, in a restrictive form for the burning velocity and not as a level set of a field.[3][4][5]

Mathematical description

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The G equation reads as[6][7]

 

where

  •   is the flow velocity field
  •   is the local burning velocity with respect to the unburnt gas

The flame location is given by   which can be defined arbitrarily such that   is the region of burnt gas and   is the region of unburnt gas. The normal vector to the flame, pointing towards the burnt gas, is  .

Local burning velocity

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According to Matalon–Matkowsky–Clavin–Joulin theory, the burning velocity of the stretched flame, for small curvature and small strain, is given by

 

where

  •   is the burning velocity of unstretched flame with respect to the unburnt gas
  •   and   are the two Markstein numbers, associated with the curvature term   and the term   corresponding to flow strain imposed on the flame
  •   are the laminar burning speed and thickness of a planar flame
  •   is the planar flame residence time.

A simple example - Slot burner

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The G equation has an exact expression for a simple slot burner. Consider a two-dimensional planar slot burner of slot width  . The premixed reactant mixture is fed through the slot from the bottom with a constant velocity  , where the coordinate   is chosen such that   lies at the center of the slot and   lies at the location of the mouth of the slot. When the mixture is ignited, a premixed flame develops from the mouth of the slot to a certain height   in the form of a two-dimensional wedge shape with a wedge angle  . For simplicity, let us assume  , which is a good approximation except near the wedge corner where curvature effects will becomes important. In the steady case, the G equation reduces to

 

If a separation of the form   is introduced, then the equation becomes

 

which upon integration gives

 

Without loss of generality choose the flame location to be at  . Since the flame is attached to the mouth of the slot  , the boundary condition is  , which can be used to evaluate the constant  . Thus the scalar field is

 

At the flame tip, we have  , which enable us to determine the flame height

 

and the flame angle  ,

 

Using the trigonometric identity  , we have

 

In fact, the above formula is often used to determine the planar burning speed  , by measuring the wedge angle.

References

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  1. ^ Williams, F. A. (1985). Turbulent combustion. In The mathematics of combustion (pp. 97-131). Society for Industrial and Applied Mathematics.
  2. ^ Kerstein, Alan R., William T. Ashurst, and Forman A. Williams. "Field equation for interface propagation in an unsteady homogeneous flow field." Physical Review A 37.7 (1988): 2728.
  3. ^ GH Markstein. (1951). Interaction of flow pulsations and flame propagation. Journal of the Aeronautical Sciences, 18(6), 428-429.
  4. ^ Markstein, G. H. (Ed.). (2014). Nonsteady flame propagation: AGARDograph (Vol. 75). Elsevier.
  5. ^ Markstein, G. H., & Squire, W. (1955). On the stability of a plane flame front in oscillating flow. The Journal of the Acoustical Society of America, 27(3), 416-424.
  6. ^ Peters, Norbert. Turbulent combustion. Cambridge university press, 2000.
  7. ^ Williams, Forman A. "Combustion theory." (1985).