In many practical applications, so-called premixed burners do not achieve perfect premixing of fuel and air. Instead, fuel injection pressure is limited, the permissible burner pressure drop is small and mixing lengths are curtailed to reduce the danger of flashback. Furthermore, internal or external piloting is frequently employed to improve combustion stability, while part-load operation often requires burner staging, where neighboring burners operate with unequal fuel/air equivalence ratios. In this report, an extension of the turbulent flame speed closure (TFC) model for highly turbulent premixed combustion is presented, which allows application of the model to the case of inhomogeneously premixed combustion. The extension is quite straightforward, i.e., the dependence of model parameters on mixture fraction is accounted for by providing appropriate lookup tables or functional relationships to the model. The model parameters determined in this way are adiabatic flame temperature, laminar flame speed and critical gradient. The model has been validated against a test case from the open literature and applied to an externally piloted industrial gas turbine burner with good success.

Issue Section:
Gas Turbines: Combustion and Fuel
Keywords:
gas turbines, power generation planning, flames, combustion, turbulence
Topics:
Combustion, Flames, Fuels, Temperature, Turbulence, Gas turbines
1.
Zimont
,
V. L.
, and
Lipatnikov
,
A. N.
,
1995
, “
A Model of Premixed Turbulent Combustion and Its Validation
,”
Chem. Phys. Reports
,
14
, No.
7
, pp.
993
1025
.
2.
Karpov
,
V. P.
,
Lipatnikov
,
A. N.
, and
Zimont
,
V. L.
,
1994
, “
A Model of Premixed Turbulent Combustion and Its Validation
,”
Archivum Combustionis
,
14
, No.
3–4
, pp.
125
141
.
3.
Zimont
,
V. L.
,
Polifke
,
W.
,
Bettelini
,
M.
, and
Weisenstein
,
W.
,
1998
, “
An Efficient Computational Model for Premixed Turbulent Combustion at High Reynolds Numbers Based on a Turbulent Flame Speed Closure
,”
ASME J. Eng. Gas Turbines Power
,
120
, pp.
526
532
.
4.
Polifke, W., Bettelini, W., Geng, W., Mu¨ller, U. C., Weisenstein, W., and Jansohn, P., 1998, “Comparison of Combustion Models for Industrial Applications,” ECCOMAS’98, John Wiley and Sons, London.
5.
Polifke
,
W.
,
Geng
,
W.
, and
Do¨bbeling
,
K.
,
1998
, “
Optimization of Rate Coefficients for Simplified Reaction Mechanisms With Genetic Algorithms
,”
Combust. Flame
,
113
, pp.
119
134
.
6.
Cokljat, D., Polifke, W., and Wild, P., 1998, “A Non-Adiabatic Method for Calculation of Premixed Flames Using a Turbulent Flame Speed Closure,” 7th Int. Conference on Numerical Combustion, March 30–April 1, York, UK, SIAM (United Kingdom and Republic of Ireland).
7.
Phillip, M., 1991, “Experimentelle und theoretische Untersuchungen zum Stabilita¨tsverhalten von Drallflammen mit zentraler Ru¨ckstro¨mzone.” Dissertation Universita¨t Karlsruhe, Germany.
8.
Peters, N., 1997, “Four Lectures on Turbulent Combustion,” ER-COFTAC Summer School, Sept. 15–19, Aachen.
9.
Kech, J. M., Reissing, J., Gindele, J., and Spicher, U., 1998, “Analysis of the Combustion Process in a Direct Injection Gasoline Engine,” COMODIA 98, 4th Int. Symp. on Diagnostics and Modeling of Combustion in Internal Combustion Engines, published by The Japan Society of Mechanical Engineers, Tokyo, Japan.
10.
Rogg, B., 1992, “RUN-1DL: The Cambridge Universal Laminar Flamelet Computer Code,” Reduced Mechanisms for Applications in Combustion Systems, N. Peters and B. Rogg, eds., Springer, Berlin.
11.
Go¨ttgens, J., Mauss, F., and Peters, N., 1992, Twenty Fourth Symposium (Int.) on Combustion, The Combustion Institute, Pittsburgh, PA, pp. 125–129.
12.
Mu¨ller
,
U. C.
,
Bollig
,
M.
, and
Peters
,
N.
,
1997
, “
Approximations for Burning Velocities and Markstein Numbers for Lean Hydrocarbon and Methanol Flames
,”
Combust. Flame
,
108
, pp.
349
356
.
13.
Dinkelacker, F., Soika, A., Most, D., Hofmann, D., Leipertz, A., Polifke, W., and Do¨bbeling, K., 1998, “Structure of Locally Quenched Highly Turbulent Lean Premixed Flames,” 27th. Int. Symposium on Combustion, Boulder, CO, pp. 857–865.
14.
Zimont, V. L., 1997, private communication.
15.
Lutz, A. E., Rupley, F. M., and Kee, R. J., 1996, “EQUIL: A CHEMKIN Implementation of STANJAN, for Computing Chemical Equilibria,” SAND96-xxxx, Sandia National Laboratories, Livermore, CA.
16.
Sayre, A., Lallemant, N., Dugue, J., and Weber, R., 1985, “Scaling Characteristics of Aerodynamics and Low-NOx Properties of Industrial Natural Gas Burners, The Scaling 400 Study, Part IV: The 300kW BERL test results,” IFRF Doc F40/y/11, International Flame Research Foundation.
17.
Fluent Inc., 1996, Fluent Validation Manual (TM-235), Fluent Inc., NH.
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