TY - GEN
T1 - LES and RANS of premixed combustion in a gas-turbine like combustor using the flamelet generated manifold approach
AU - Cardoso de Souza, T.
AU - Bastiaans, R.J.M.
AU - Geurts, B.J.
AU - Goey, de, L.P.H.
PY - 2011
Y1 - 2011
N2 - Dry-low NOx gas turbine technology relies on lean premixed
combustion of fuel. Additionally the accurate prediction of turbulent
premixed combustion is still very difficult. In the present
paper the calculation of reduced chemistry is assessed efficiently
through the use of the flamelet generated manifold (FGM), which
is used in conjunction with a CFD code in a RANS as well as in
an LES context. In order to predict the combustion phenomena
in a high swirl and high Reynolds number flow (the SimVal setup,
at atmospheric pressure with elevated temperature), the present
model is used concomitantly with a pre-assumed PDF for which
fluctuations are completely determined in terms of an algebraic
model. The mixing model for the variance has an arbitrary model
constant, and the results show that the flame stabilization is not
very sensitive to the model parameter present in the model. Sta-
bilization of the combustion occurs at a location comparable to
that found in experiments. In order to investigate the effects of
this parameter on the numerical solutions, first RANS simulations
were addressed considering arbitrary values for this parameter,
defined within a certain range, and in a next step the
grid resolution was changed. LES calculations were also performed
showing similar features predicted in RANS. It is found
that with the use of FGM combustion features in gas turbine conditions
can be reproduced in a robust way.
AB - Dry-low NOx gas turbine technology relies on lean premixed
combustion of fuel. Additionally the accurate prediction of turbulent
premixed combustion is still very difficult. In the present
paper the calculation of reduced chemistry is assessed efficiently
through the use of the flamelet generated manifold (FGM), which
is used in conjunction with a CFD code in a RANS as well as in
an LES context. In order to predict the combustion phenomena
in a high swirl and high Reynolds number flow (the SimVal setup,
at atmospheric pressure with elevated temperature), the present
model is used concomitantly with a pre-assumed PDF for which
fluctuations are completely determined in terms of an algebraic
model. The mixing model for the variance has an arbitrary model
constant, and the results show that the flame stabilization is not
very sensitive to the model parameter present in the model. Sta-
bilization of the combustion occurs at a location comparable to
that found in experiments. In order to investigate the effects of
this parameter on the numerical solutions, first RANS simulations
were addressed considering arbitrary values for this parameter,
defined within a certain range, and in a next step the
grid resolution was changed. LES calculations were also performed
showing similar features predicted in RANS. It is found
that with the use of FGM combustion features in gas turbine conditions
can be reproduced in a robust way.
M3 - Conference contribution
SP - GT2011-46355-1/9
BT - Proceedings of ASME Turbo Expo 2011, June 6-10, 2011, Vancouver, Canada
ER -