Combined with the use of renewable energy sources for its production, hydrogen represents a possible alternative gas turbine fuel for future low-emission power generation. Due to the difference in the physical properties of hydrogen compared to other fuels such as natural gas, well-established gas turbine combustion systems cannot be directly applied to dry low NOx (DLN) hydrogen combustion. The DLN micromix combustion of hydrogen has been under development for many years, since it has the promise to significantly reduce NOx emissions. This combustion principle for air-breathing engines is based on crossflow mixing of air and gaseous hydrogen. Air and hydrogen react in multiple miniaturized diffusion-type flames with an inherent safety against flashback and with low NOx emissions due to a very short residence time of the reactants in the flame region. The paper presents an advanced DLN micromix hydrogen application. The experimental and numerical study shows a combustor configuration with a significantly reduced number of enlarged fuel injectors with high-thermal power output at constant energy density. Larger fuel injectors reduce manufacturing costs, are more robust and less sensitive to fuel contamination and blockage in industrial environments. The experimental and numerical results confirm the successful application of high-energy injectors, while the DLN micromix characteristics of the design point, under part-load conditions, and under off-design operation are maintained. Atmospheric test rig data on NOx emissions, optical flame-structure, and combustor material temperatures are compared to numerical simulations and show good agreement. The impact of the applied scaling and design laws on the miniaturized micromix flamelets is particularly investigated numerically for the resulting flow field, the flame-structure, and NOx formation.
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June 2017
Research-Article
Experimental and Numerical Study on Optimizing the Dry Low NOx Micromix Hydrogen Combustion Principle for Industrial Gas Turbine Applications
Masahide Kazari,
Masahide Kazari
Corporate Technology Division,
Kawasaki Heavy Industries, Ltd.,
1-1 Kawasaki-chi,
Akashi, Hyogo 673-8666, Japan
e-mail: Kazari_masahide@khi.co.jp
Kawasaki Heavy Industries, Ltd.,
1-1 Kawasaki-chi,
Akashi, Hyogo 673-8666, Japan
e-mail: Kazari_masahide@khi.co.jp
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Junichi Kitajima,
Junichi Kitajima
Corporate Technology Division,
Kawasaki Heavy Industries, Ltd.,
1-1 Kawasaki-chi,
Akashi, Hyogo 673-8666, Japan
e-mail: kitajima_junichi@corp.khi.co.jp
Kawasaki Heavy Industries, Ltd.,
1-1 Kawasaki-chi,
Akashi, Hyogo 673-8666, Japan
e-mail: kitajima_junichi@corp.khi.co.jp
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Atsushi Horikawa,
Atsushi Horikawa
Corporate Technology Division,
Kawasaki Heavy Industries, Ltd.,
1-1 Kawasaki-chi,
Akashi, Hyogo 673-8666, Japan
e-mail: horikawa_a@khi.co.jp
Kawasaki Heavy Industries, Ltd.,
1-1 Kawasaki-chi,
Akashi, Hyogo 673-8666, Japan
e-mail: horikawa_a@khi.co.jp
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Kunio Okada
Kunio Okada
Corporate Technology Division,
Kawasaki Heavy Industries, Ltd.,
1-1 Kawasaki-chi,
Akashi, Hyogo 673-8666, Japan
e-mail: okada_kunio@khi.co.jp
Kawasaki Heavy Industries, Ltd.,
1-1 Kawasaki-chi,
Akashi, Hyogo 673-8666, Japan
e-mail: okada_kunio@khi.co.jp
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Harald H. W. Funke
Jan Keinz
Karsten Kusterer
Anis Haj Ayed
Masahide Kazari
Corporate Technology Division,
Kawasaki Heavy Industries, Ltd.,
1-1 Kawasaki-chi,
Akashi, Hyogo 673-8666, Japan
e-mail: Kazari_masahide@khi.co.jp
Kawasaki Heavy Industries, Ltd.,
1-1 Kawasaki-chi,
Akashi, Hyogo 673-8666, Japan
e-mail: Kazari_masahide@khi.co.jp
Junichi Kitajima
Corporate Technology Division,
Kawasaki Heavy Industries, Ltd.,
1-1 Kawasaki-chi,
Akashi, Hyogo 673-8666, Japan
e-mail: kitajima_junichi@corp.khi.co.jp
Kawasaki Heavy Industries, Ltd.,
1-1 Kawasaki-chi,
Akashi, Hyogo 673-8666, Japan
e-mail: kitajima_junichi@corp.khi.co.jp
Atsushi Horikawa
Corporate Technology Division,
Kawasaki Heavy Industries, Ltd.,
1-1 Kawasaki-chi,
Akashi, Hyogo 673-8666, Japan
e-mail: horikawa_a@khi.co.jp
Kawasaki Heavy Industries, Ltd.,
1-1 Kawasaki-chi,
Akashi, Hyogo 673-8666, Japan
e-mail: horikawa_a@khi.co.jp
Kunio Okada
Corporate Technology Division,
Kawasaki Heavy Industries, Ltd.,
1-1 Kawasaki-chi,
Akashi, Hyogo 673-8666, Japan
e-mail: okada_kunio@khi.co.jp
Kawasaki Heavy Industries, Ltd.,
1-1 Kawasaki-chi,
Akashi, Hyogo 673-8666, Japan
e-mail: okada_kunio@khi.co.jp
Contributed by the Heat Transfer Division of ASME for publication in the JOURNAL OF THERMAL SCIENCE AND ENGINEERING APPLICATIONS. Manuscript received August 14, 2015; final manuscript received August 17, 2016; published online December 7, 2016. Assoc. Editor: Ali Siahpush.
J. Thermal Sci. Eng. Appl. Jun 2017, 9(2): 021001 (10 pages)
Published Online: December 7, 2016
Article history
Received:
August 14, 2015
Revised:
August 17, 2016
Citation
Funke, H. H. W., Keinz, J., Kusterer, K., Ayed, A. H., Kazari, M., Kitajima, J., Horikawa, A., and Okada, K. (December 7, 2016). "Experimental and Numerical Study on Optimizing the Dry Low NOx Micromix Hydrogen Combustion Principle for Industrial Gas Turbine Applications." ASME. J. Thermal Sci. Eng. Appl. June 2017; 9(2): 021001. https://doi.org/10.1115/1.4034849
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