Gas turbine combustors are often susceptible to self-excited oscillations, which lead to unacceptable levels of pressure, velocity, and heat release fluctuations. Although instabilities can occur in systems with locally constant equivalence ratio, it is very important to take into account the influence of equivalence ratio fluctuations, which are generated in the fuel air mixer in the unstable case. These fluctuations are convected into the flame and lead to an additional mechanism for the generation of heat release fluctuations. Moreover, entropy waves are produced in the flame, which travel through the combustor and generate additional pressure waves during the acceleration of the flow at the combustor exit. To date, available theories use the physically unrealistic assumption that the equivalence ratio waves as well as the entropy waves are convected downstream without any spatial dispersion due to the combustor aerodynamics. An analytical approach is presented, which allows us to take the spatial dispersion into consideration. For that purpose, the response of the burner and the combustor to an equivalence ratio impulse or an entropy impulse is calculated using the Laplace transformation and a more general transfer function for harmonic waves is derived. The obtained expression has three parameters, which represent the influence of the burner or the combustor aerodynamics, respectively. This equation can be used in numerical codes, which represent the combustion system through a network of acoustic multiports, if the equivalence ratio and the entropy are added to the vector of variables considered. The parameters required for the dynamic combustor model can be deduced from a detailed CFD analysis of the combustor flow in case of the application of the theory to a particular combustor design. As an example, a simple model combustor is used to demonstrate the application of the theory. It is highlighted how the spatial dispersion of the equivalence ratio and entropy fluctuations can be included in the stability analysis. The calculated examples reveal that the influence of both variables on the generation of instabilities is highly overpredicted if the spatial dispersion is not taken into account. Furthermore, it can be deduced from the study that burner and combustor designs with a wide range of convective time scales have advantages with respect to the stability of the combustor.

Issue Section:
Gas Turbines: Combustion and Fuels
Keywords:
combustion, engineering, gas turbines, aerodynamics, stability criteria, fluctuations, oscillations, heat
Topics:
Acoustics, Combustion chambers, Entropy, Flames, Fluctuations (Physics), Stability, Waves, Aerodynamics, Gas turbines, Flow (Dynamics)
1.
Keller
,
J. J.
,
1995
, “
Thermoacoustic Oscillations In Combustion Chambers of Gas Turbines
,”
AIAA J.
,
33
, No.
12
, pp.
2280
2287
.
2.
Hubbard, S., and Dowling, A. P., 1998, “Acoustic Instabilities in Premixed Burners,” AIAA 98-2272, 4th AIAA/CEAS Aeroacoustics Conference, Toulouse, France, June 1998.
3.
Polifke, W., Paschereit, C. O., and Do¨bbeling. K., 1999, “Suppression of Combustion Instabilities Through Destructive Interference of Acoustic and Entropy Waves,” 6th Int. Congress on Sound and Vibration, Copenhagen.
4.
Lieuwen, T., Torres, H., Johnson, C., and Zinn, B. 1999, “A Mechanism of Combustion Instability in Lean Premixed Gas Turbine Combustors,” ASME Paper 99-GT-3.
5.
Davies
,
P. O. A. L.
,
1988
, “
Practical Flow Duct Acoustics
,”
J. Sound Vib.
,
124
, p.
91
115
.
6.
Deucker, E., 1995, “Ein Beitrag zur Vorausberechnung des akustischen Stabilita¨tsverhaltens von Gasturbinen-Brennkammern mittels theoretischer und experimenteller Analyze von Brennkammerschwingungent,” VDI Fortschrittsberichte, Reihe 6, No. 317.
7.
Fleifil
,
M.
, et al.,
1996
, “
Response of a Laminar Premixed Flame to Flow Oscillations: A Kinematic Model and Thermoacoustic Instability Results
,”
Combust. Flame
,
106
, pp.
487
510
.
8.
Ohtsuka, M., et al., 1998, “Combustion Oscillation Analysis of Premixed Flames at Elevated Pressures,” ASME Paper 98-GT-581.
9.
Peracchio, A. A., and Proscia, W. M., 1998, “Non-Linear Heat-Release/Acoustic Model for Thermoacoustic Instability in Lean Premixed Combustors,” ASME paper 98-GT-269.
10.
Lenz, W., “Die dynamischen Eigenschaften von Flammen und ihr Einfluss auf die Entstehung selbsterregter Brennkammerschwingungen,” dissertation, Universita¨t Karlsruhe, 1980.
11.
Dowling
,
A. P.
,
1997
, “
Nonlinear Self-Excited Oscillations of a Ducted Flame
,”
J. Fluid Mech.
,
346
, pp.
271
290
.
12.
Marble
,
F. E.
, and
Candel
,
S. M.
,
1977
, “
Acoustic Disturbances from Gas Non-Uniformities Convected through a Nozzle
,”
J. Sound Vib.
,
55
, No.
2
, pp.
225
243
.
Copyright © 2003
 by ASME
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