Large-eddy simulation and acoustic analysis of a turbulent flow field in a swirl-stabilized combustor
Jong-Chan Kim, Kwang-Hee Yoo and Hong-Gye Sung*
The Journal of Mechanical Science and Technology, vol. 25, no. 10, pp.2703-2710, 2011
Abstract : To conduct a comprehensive study on the flow characteristics and acoustic oscillation in a gas turbine combustor, a 3D large-eddy simulation
(LES) was implemented. The formulation consists of the Favre-filtered conservation equations of mass, momentum, and energy.
The subgrid-scale dynamics are modeled using a compressible flow version of the Smagorinsky model. To investigate the dominant
coherent structure, the proper orthogonal decomposition (POD) method was used for post-processing. The combustor of concern is the
LM6000, lean-premixed dry low-NOx annular combustor, developed by General Electric Aircraft Engines (GEAE). Four important
characteristics of swirl flow are visualized: vortex breakdown, procession and dissipation of vortical structures, recirculation zones, and
helical waves immediately downstream of the swirl injector. It is shown that the turbulent motion of swirl flow directly affects acoustic
oscillation through the cycle and spectral analysis. The four most dominant acoustic modes are extracted from the flow field by the POD
analysis. The transverse modes in the y and z directions are dominant in all four modes, since the pressure fields are significantly affected
by swirl flow.
Keyword : Acoustic oscillation; Large-eddy simulation (LES); Proper orthogonal decomposition (POD); Swirl flow |