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Publikationstyp:	Beitrag in wissenschaftlicher Zeitschrift
Art der Begutachtung:	Peer review (Publikation)
Titel:	The effect of hydrogen on nonlinear flame saturation
Autor/-in:	Æsøy, Eirik Indlekofer, Thomas Bothien, Mirko Dawson, James R.
et. al:	No
DOI:	10.1115/1.4063316 10.21256/zhaw-29606
Erschienen in:	Journal of Engineering for Gas Turbines and Power
Band(Heft):	145
Heft:	11
Erscheinungsdatum:	2023
Verlag / Hrsg. Institution:	The American Society of Mechanical Engineers
ISSN:	0742-4795 1528-8919
Sprache:	Englisch
Schlagwörter:	Hydrogen; Flame transfer function; Nonlinear; Saturation; Thermoacoustics
Fachgebiet (DDC):	620: Ingenieurwesen
Zusammenfassung:	We investigate the effect of increasing levels of hydrogen enrichment on the nonlinear response and saturation of premixed bluff-body stabilized methane/hydrogen flames submitted to acoustic forcing. The thermal power is kept approximately constant to preserve the nozzle velocity while increasing the flame speed through hydrogen enrichment. The flame describing function (FDF) is measured for a fixed frequency and three hydrogen–methane blends ranging from 10% to 50% by power, corresponding to 25% to 75% by volume. We show that when the flame is forced at the same frequency at similar power and bulk velocities, increasing levels of hydrogen enrichment increase the saturation amplitude of the flame. To provide insight into the flame dynamics responsible for the change in the global nonlinear response and saturation amplitude, the flames were investigated using high-speed imaging in combination with OH planar laser-induced fluorescence (OH-PLIF) at a range of forcing amplitudes. At lower hydrogen concentrations, the flame is stabilized along the inner shear layer and saturation in the heat release rate (HRR) occurs at lower forcing amplitudes due to large-scale flame–vortex interactions causing flame annihilation as observed in several previous studies. At increased levels of hydrogen enrichment, distinctly different flame dynamics are observed. In these cases, the flame accelerates and propagates across to the outer shear layer, which acts to suppress large-scale flame annihilation during roll-up of both the inner and outer shear layers. This results in a coherent increase in flame surface area with forcing amplitudes significantly increasing the saturation amplitude of the flame. These results show that high levels of hydrogen increase the amplitude response to acoustic forcing leading to higher saturation amplitudes. This suggests that substituting natural gas with hydrogen in gas turbines increases the risk of much higher limit-cycle amplitudes if self-excited instabilities occur.
URI:	https://digitalcollection.zhaw.ch/handle/11475/29606
Volltext Version:	Akzeptierte Version
Lizenz (gemäss Verlagsvertrag):	CC BY 4.0: Namensnennung 4.0 International
Departement:	School of Engineering
Organisationseinheit:	Institut für Energiesysteme und Fluid-Engineering (IEFE)
Enthalten in den Sammlungen:	Publikationen School of Engineering

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