A numerical investigation of a low NOx partially premixed fuel nozzle for heavy-duty gas turbine applications is presented in this paper. Availability of results from a recent test campaign on the same fuel nozzle architecture allowed the exhaustive comparison study presented in this work. At first, an assessment of the turbulent combustion model was carried out, with a critical investigation of the expected turbulent combustion regimes in the system and taking into account the partially premixed nature of the flame due to the presence of diffusion type pilot flames. In particular, the fluent partially premixed combustion model and a flamelet approach are used to simulate the flame. The laminar flamelet database is generated using the flamelet generated manifold (FGM) chemistry reduction technique. Species and temperature are parameterized by mixture fraction and progress variable. Comparisons with calculations with partially premixed model and the steady diffusion flamelet (SDF) database are made for the baseline configuration in order to discuss possible gains associated with the introduced dimension in the FGM database (reaction progress), which makes it possible to account for nonequilibrium effects. Numerical characterization of the baseline nozzle has been carried out in terms of NOx. Computed values for both the baseline and some alternative premixer designs have been then compared with experimental measurements on the reactive test rig at different operating conditions and different split ratios between main and pilot fuel. Numerical results allowed pointing out the fundamental NOx formation processes, both in terms of spatial distribution within the flame and in terms of different formation mechanisms. The obtained knowledge would allow further improvement of fuel nozzle design.
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January 2016
Research-Article
Design Improvement Survey for NOx Emissions Reduction of a Heavy-Duty Gas Turbine Partially Premixed Fuel Nozzle Operating With Natural Gas: Numerical Assessment
Alessandro Innocenti,
Alessandro Innocenti
Department of Industrial Engineering,
University of Florence,
Via S. Marta 3,
Florence 50139, Italy
e-mail: alessandro.innocenti@htc.de.unifi.it
University of Florence,
Via S. Marta 3,
Florence 50139, Italy
e-mail: alessandro.innocenti@htc.de.unifi.it
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Antonio Andreini,
Antonio Andreini
Department of Industrial Engineering,
University of Florence,
Via S. Marta 3,
Florence 50139, Italy
University of Florence,
Via S. Marta 3,
Florence 50139, Italy
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Bruno Facchini,
Bruno Facchini
Department of Industrial Engineering,
University of Florence,
Via S. Marta 3,
Florence 50139, Italy
University of Florence,
Via S. Marta 3,
Florence 50139, Italy
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Matteo Cerutti,
Matteo Cerutti
GE Oil & Gas Nuovo Pignone s.r.l.,
Via F. Matteucci 2,
Florence 50127, Italy
Via F. Matteucci 2,
Florence 50127, Italy
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Gianni Ceccherini,
Gianni Ceccherini
GE Oil & Gas Nuovo Pignone s.r.l.,
Via F. Matteucci 2,
Florence 50127, Italy
Via F. Matteucci 2,
Florence 50127, Italy
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Giovanni Riccio
Giovanni Riccio
GE Oil & Gas Nuovo Pignone s.r.l.,
Via F. Matteucci 2,
Florence 50127, Italy
Via F. Matteucci 2,
Florence 50127, Italy
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Alessandro Innocenti
Department of Industrial Engineering,
University of Florence,
Via S. Marta 3,
Florence 50139, Italy
e-mail: alessandro.innocenti@htc.de.unifi.it
University of Florence,
Via S. Marta 3,
Florence 50139, Italy
e-mail: alessandro.innocenti@htc.de.unifi.it
Antonio Andreini
Department of Industrial Engineering,
University of Florence,
Via S. Marta 3,
Florence 50139, Italy
University of Florence,
Via S. Marta 3,
Florence 50139, Italy
Bruno Facchini
Department of Industrial Engineering,
University of Florence,
Via S. Marta 3,
Florence 50139, Italy
University of Florence,
Via S. Marta 3,
Florence 50139, Italy
Matteo Cerutti
GE Oil & Gas Nuovo Pignone s.r.l.,
Via F. Matteucci 2,
Florence 50127, Italy
Via F. Matteucci 2,
Florence 50127, Italy
Gianni Ceccherini
GE Oil & Gas Nuovo Pignone s.r.l.,
Via F. Matteucci 2,
Florence 50127, Italy
Via F. Matteucci 2,
Florence 50127, Italy
Giovanni Riccio
GE Oil & Gas Nuovo Pignone s.r.l.,
Via F. Matteucci 2,
Florence 50127, Italy
Via F. Matteucci 2,
Florence 50127, Italy
1Corresponding author.
Contributed by the Combustion and Fuels Committee of ASME for publication in the JOURNAL OF ENGINEERING FOR GAS TURBINES AND POWER. Manuscript received July 15, 2015; final manuscript received July 22, 2015; published online August 12, 2015. Editor: David Wisler.
J. Eng. Gas Turbines Power. Jan 2016, 138(1): 011501 (9 pages)
Published Online: August 12, 2015
Article history
Received:
July 15, 2015
Revision Received:
July 22, 2015
Citation
Innocenti, A., Andreini, A., Facchini, B., Cerutti, M., Ceccherini, G., and Riccio, G. (August 12, 2015). "Design Improvement Survey for NOx Emissions Reduction of a Heavy-Duty Gas Turbine Partially Premixed Fuel Nozzle Operating With Natural Gas: Numerical Assessment." ASME. J. Eng. Gas Turbines Power. January 2016; 138(1): 011501. https://doi.org/10.1115/1.4031144
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