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Sustainable Combustion Technologies Need Acoustics Research

Heckl, Maria

Authors



Abstract

This paper outlines the challenges of developing hydrogen-fueled combustion systems, which are safe from combustion instabilities. Combustion instabilities can occur in any configuration where a continuously burning flame is housed in an acoustic resonator, such as gas turbine engines, boilers and furnaces. They manifest themselves by large-amplitude oscillations of one or more resonator modes and can cause major damage to the combustion system. Their underlying cause is the following feedback loop: the flow carrying the combustible mixture is perturbed → the flame becomes unsteady and its heat release fluctuates → the fluctuating heat release generates sound → the sound perturbs the flow of the mixture, and the feedback cycle is closed. Various strategies exist to prevent instabilities in conventional combustion systems, which burn hydrocarbon fuels. However, if hydrogen or a hydrogen-blend is used as fuel, the flame's dynamic behaviour changes, and as a consequence, combustion instabilities occur under new and unexpected conditions. In order to give some explicit physical insight, a generic combustion system will be presented and described by an analytical model. Predictions will be made about the impact of hydrogen fuel and other parameters.

Citation

Heckl, M. (2023). Sustainable Combustion Technologies Need Acoustics Research. . https://doi.org/10.3397/in_2022_1010

Conference Name InterNoise22
Conference Location Glasgow, Scotland
Start Date Aug 21, 2023
End Date Aug 23, 2023
Acceptance Date Feb 1, 2023
Online Publication Date Feb 1, 2023
Publication Date Feb 1, 2023
Deposit Date Jan 8, 2024
Volume 265
Pages 6716-6727
DOI https://doi.org/10.3397/in_2022_1010
Keywords Applied Mathematics, General Mathematics