Due to their inherent noise challenge and potential for significant reductions in fuel burn, counter-rotating propfans (CRPs) are currently being investigated as potential alternatives to high-bypass turbofan engines. This paper introduces an integrated noise and performance assessment methodology for advanced propfan powered aircraft configurations. The approach is based on first principles and combines a coupled aircraft and propulsion system mission and performance analysis tool with 3D unsteady, full-wheel CRP computational fluid dynamics computations and aeroacoustic simulations. Special emphasis is put on computing CRP noise due to interaction tones. The method is capable of dealing with parametric studies and exploring noise reduction technologies. An aircraft performance, weight and balance, and mission analysis was first conducted on a candidate CRP powered aircraft configuration. Guided by data available in the literature, a detailed aerodynamic design of a pusher CRP was carried out. Full-wheel unsteady 3D Reynolds-averaged Navier-Stokes (RANS) simulations were then used to determine the time varying blade surface pressures and unsteady flow features necessary to define the acoustic source terms. A frequency domain approach based on Goldstein’s formulation of the acoustic analogy for moving media and Hanson’s single rotor noise method was extended to counter-rotating configurations. The far field noise predictions were compared to measured data of a similar CRP configuration and demonstrated good agreement between the computed and measured interaction tones. The underlying noise mechanisms have previously been described in literature but, to the authors’ knowledge, this is the first time that the individual contributions of front-rotor wake interaction, aft-rotor upstream influence, hub-endwall secondary flows, and front-rotor tip-vortices to interaction tone noise are dissected and quantified. Based on this investigation, the CRP was redesigned for reduced noise incorporating a clipped rear-rotor and increased rotor-rotor spacing to reduce upstream influence, tip-vortex, and wake interaction effects. Maintaining the thrust and propulsive efficiency at takeoff conditions, the noise was calculated for both designs. At the interaction tone frequencies, the redesigned CRP demonstrated an average reduction of 7.25 dB in mean sound pressure level computed over the forward and aft polar angle arcs. On the engine/aircraft system level, the redesigned CRP demonstrated a reduction of 9.2 dB in effective perceived noise (EPNdB) and 8.6 EPNdB at the Federal Aviation Regulations (FAR) 36 flyover and sideline observer locations, respectively. The results suggest that advanced open rotor designs can possibly meet Stage 4 noise requirements.
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e-mail: (zolti@mit.edu)
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January 2012
Research Papers
Rotor Interaction Noise in Counter-Rotating Propfan Propulsion Systems
Andreas Peters,
Andreas Peters
Department of Aeronautics and Astronautics, Gas Turbine Laboratory,
Massachusetts Institute of Technology
, Cambridge, MA 02193
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Zoltán S. Spakovszky
Zoltán S. Spakovszky
Department of Aeronautics and Astronautics, Gas Turbine Laboratory,
e-mail: (zolti@mit.edu)
Massachusetts Institute of Technology
, Cambridge, MA 02193
Search for other works by this author on:
Andreas Peters
Department of Aeronautics and Astronautics, Gas Turbine Laboratory,
Massachusetts Institute of Technology
, Cambridge, MA 02193
Zoltán S. Spakovszky
Department of Aeronautics and Astronautics, Gas Turbine Laboratory,
Massachusetts Institute of Technology
, Cambridge, MA 02193e-mail: (zolti@mit.edu)
J. Turbomach. Jan 2012, 134(1): 011002 (12 pages)
Published Online: May 24, 2011
Article history
Received:
July 8, 2010
Revised:
September 5, 2010
Online:
May 24, 2011
Published:
May 24, 2011
Citation
Peters, A., and Spakovszky, Z. S. (May 24, 2011). "Rotor Interaction Noise in Counter-Rotating Propfan Propulsion Systems." ASME. J. Turbomach. January 2012; 134(1): 011002. https://doi.org/10.1115/1.4003223
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