Abstract
Combustion noise is becoming increasingly important as a major noise source in aeroengines and
ground based gas turbines. This is partially because advances in design have reduced the other noise
sources, and partially because next generation combustion modes burn more unsteadily, resulting in
increased external noise from the combustion. This review reports recent progress made in understanding
combustion noise by theoretical, numerical and experimental investigations. We first discuss the fundamentals
of the sound emission from a combustion region. Then the noise of open turbulent flames is summarized.
We subsequently address the effects of confinement on combustion noise. In this case not only is the
sound generated by the combustion influenced by its transmission through the boundaries of the combustion
chamber, there is also the possibility of a significant additional source, the so-called ‘indirect’ combustion
noise. This involves hot spots (entropy fluctuations) or vorticity perturbations produced by temporal
variations in combustion, which generate pressure waves (sound) as they accelerate through any restriction
at the exit of the combustor. We describe the general characteristics of direct and indirect noise. To gain
further insight into the physical phenomena of direct and indirect sound, we investigate a simple configuration
consisting of a cylindrical or annular combustor with a low Mach number flow in which a flame
zone burns unsteadily. Using a low Mach number approximation, algebraic exact solutions are developed
so that the parameters controlling the generation of acoustic, entropic and vortical waves can be investigated.
The validity of the low Mach number approximation is then verified by solving the linearized Euler
equations numerically for a wide range of inlet Mach numbers, stagnation temperature ratios, frequency
and mode number of heat release fluctuations. The effects of these parameters on the magnitude of the
waves produced by the unsteady combustion are investigated. In particular the magnitude of the indirect
and direct noise generated in a model combustor with a choked outlet is analyzed for a wide range of frequencies,
inlet Mach numbers and stagnation temperature ratios. Finally, we summarize some of the
unsolved questions that need to be the focus of future research
Original language | English |
---|---|
Pages (from-to) | 65-100 |
Number of pages | 36 |
Journal | Proceedings of the Combustion Institute |
Volume | 35 |
Issue number | 1 |
Early online date | 22 Nov 2014 |
DOIs | |
Publication status | Published - 2015 |