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Attenuation of thermoacoustic instabilities in a swirl-stabilized NH3–CH4–air combustor with secondary air injection

Liu, Chunyu ; Yang, Haojie ; Li, Xuejiao ; Ruan, Can LU ; Yu, Liang and Lu, Xingcai (2024) In Experiments in Fluids 65(6).
Abstract

Ammonia–methane (NH3–CH4) mixtures have potentials to serve as low-carbon fuels for gas turbines. Recent studies demonstrated that secondary air injection was an effective strategy to reduce NOx emissions from the combustion of NH3–CH4–air mixtures. However, the effects of secondary air injection on the performance of thermoacoustic instability of NH3–CH4–air flames remain unknown. To this end, this study experimentally investigated the thermoacoustic instability performance of a premixed, swirl-stabilized NH3–CH4–FF air combustor without and with secondary air injection. Without secondary air injection, thermoacoustic instabilities were widely... (More)

Ammonia–methane (NH3–CH4) mixtures have potentials to serve as low-carbon fuels for gas turbines. Recent studies demonstrated that secondary air injection was an effective strategy to reduce NOx emissions from the combustion of NH3–CH4–air mixtures. However, the effects of secondary air injection on the performance of thermoacoustic instability of NH3–CH4–air flames remain unknown. To this end, this study experimentally investigated the thermoacoustic instability performance of a premixed, swirl-stabilized NH3–CH4–FF air combustor without and with secondary air injection. Without secondary air injection, thermoacoustic instabilities were widely detected at NH3 ratios below 50% (by volume). It was discovered that such instabilities were significantly suppressed by secondary air injection over a wider range of operating conditions. In conjunction with the analysis of the flame and flow dynamics, it was revealed that the secondary air injection suppressed the large amplitude axial oscillations of the flame and the flow field. Combined with the experimental results, it was inferred that the introduction of secondary air changed the velocity and pressure distribution downstream of the primary combustion zone, which in turn affected the formation and evolution of the vortex structures, thereby mitigating thermoacoustic coupling. Finally, emission measurements were discussed and the results indicated that the secondary air injection strategy reduced unburnt NH3 and CO emissions to a certain extent as well as decreased NOx emissions at specific equivalence ratios. Graphical abstract: (Figure presented.)

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organization
publishing date
type
Contribution to journal
publication status
published
subject
in
Experiments in Fluids
volume
65
issue
6
article number
88
publisher
Springer
external identifiers
  • scopus:85194571916
ISSN
0723-4864
DOI
10.1007/s00348-024-03826-9
language
English
LU publication?
yes
id
16340898-eaac-4135-a6d4-a2cc2d28518d
date added to LUP
2024-08-19 14:13:35
date last changed
2024-08-19 14:14:24
@article{16340898-eaac-4135-a6d4-a2cc2d28518d,
  abstract     = {{<p>Ammonia–methane (NH<sub>3</sub>–CH<sub>4</sub>) mixtures have potentials to serve as low-carbon fuels for gas turbines. Recent studies demonstrated that secondary air injection was an effective strategy to reduce NOx emissions from the combustion of NH<sub>3</sub>–CH<sub>4</sub>–air mixtures. However, the effects of secondary air injection on the performance of thermoacoustic instability of NH<sub>3</sub>–CH<sub>4</sub>–air flames remain unknown. To this end, this study experimentally investigated the thermoacoustic instability performance of a premixed, swirl-stabilized NH<sub>3</sub>–CH<sub>4</sub>–FF air combustor without and with secondary air injection. Without secondary air injection, thermoacoustic instabilities were widely detected at NH<sub>3</sub> ratios below 50% (by volume). It was discovered that such instabilities were significantly suppressed by secondary air injection over a wider range of operating conditions. In conjunction with the analysis of the flame and flow dynamics, it was revealed that the secondary air injection suppressed the large amplitude axial oscillations of the flame and the flow field. Combined with the experimental results, it was inferred that the introduction of secondary air changed the velocity and pressure distribution downstream of the primary combustion zone, which in turn affected the formation and evolution of the vortex structures, thereby mitigating thermoacoustic coupling. Finally, emission measurements were discussed and the results indicated that the secondary air injection strategy reduced unburnt NH<sub>3</sub> and CO emissions to a certain extent as well as decreased NOx emissions at specific equivalence ratios. Graphical abstract: (Figure presented.)</p>}},
  author       = {{Liu, Chunyu and Yang, Haojie and Li, Xuejiao and Ruan, Can and Yu, Liang and Lu, Xingcai}},
  issn         = {{0723-4864}},
  language     = {{eng}},
  number       = {{6}},
  publisher    = {{Springer}},
  series       = {{Experiments in Fluids}},
  title        = {{Attenuation of thermoacoustic instabilities in a swirl-stabilized NH<sub>3</sub>–CH<sub>4</sub>–air combustor with secondary air injection}},
  url          = {{http://dx.doi.org/10.1007/s00348-024-03826-9}},
  doi          = {{10.1007/s00348-024-03826-9}},
  volume       = {{65}},
  year         = {{2024}},
}