Numerical study of the effect of inlet geometry on combustion instabilities in a lean premixed swirl combustor

The effects of flow structure and flame dynamics on combustion instabilities in a lean premixed swirl combustor were numerically investigated using Large eddy simulation (LES) by varying the inlet geometry of combustor. The dynamic k sgs -equation and G-equation flamelet models were respectively emp...

Full description

Saved in:
Bibliographic Details
Published in:Journal of mechanical science and technology 2016, 30(11), , pp.5293-5303
Main Authors: Lee, Chang-Eon, Park, Seul-Hyun, Hwang, Cheol-Hong
Format: Article
Language:English
Subjects:
Combustion
Combustion chambers
Computational fluid dynamics
Computer simulation
Control
Deformation mechanisms
Dynamic structural analysis
Dynamical Systems
Dynamics
Engineering
Flame-vortex interaction
Geometry
Industrial and Production Engineering
Inlets
Instability
Large eddy simulation
Mathematical models
Mechanical Engineering
Parameter modification
Pressure oscillations
Stability
Turbulence
Unsteady
Vibration
기계공학
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:The effects of flow structure and flame dynamics on combustion instabilities in a lean premixed swirl combustor were numerically investigated using Large eddy simulation (LES) by varying the inlet geometry of combustor. The dynamic k sgs -equation and G-equation flamelet models were respectively employed as the LES subgrid models of turbulence and combustion. The divergent half angle (α) in the combustor inlet was varied systematically from 30° to 90° to quantify the effect of inlet geometry on the combustion instabilities. This variation caused considerable deformation in recirculation zones in terms of their size and location, leading to significant changes in flame dynamics. Analysis of unsteady pressure distributions in the combustor showed that the largest damping caused by combustion instabilities takes place at α = 45°, and the amplitude of acoustic pressure oscillation is largest at α = 30°. Examination of local Rayleigh parameters indicated that controlling flame-vortex interactions by modifying inlet geometry can change the local characteristics of combustion instabilities in terms of their amplification and suppression, and thus serve as a useful approach to reduce the instabilities in a lean premixed swirl combustor. These phenomena were studied in detail through unsteady analysis associated with flow and flame dynamics.
ISSN:1738-494X
1976-3824
DOI:10.1007/s12206-016-1048-y