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Progress in open rotor propulsors: The FAA/GE/NASA open rotor test campaign

Published online by Cambridge University Press:  27 January 2016

D. E. Van Zante*
Affiliation:
NASA Glenn Research Center, Cleveland, USA
F. Collier
Affiliation:
NASA Langley Research Center, Hampton, USA
A. Orton
Affiliation:
Federal Aviation Administration, Washington DC, USA
S. Arif Khalid
Affiliation:
General Electric Aviation, Cincinnati, USA
J. P. Wojno
Affiliation:
General Electric Aviation, Cincinnati, USA
T. H. Wood
Affiliation:
General Electric Global Research, Niskayuna, USA

Abstract

Model scale tests of modern ‘open rotor’ propulsor concepts that have potential for significant fuel burn reduction for aircraft applications were completed at NASA Glenn Research Center. The recent test campaign was a collaboration between NASA, FAA, and General Electric (GE). GE was the primary industrial partner, but other organisations were involved such as Boeing and Airbus who provided additional hardware for fuselage simulations. The open rotor is a modern version of the UnDucted Fan (UDF®) that was flight tested in the late 1980s through a partnership between NASA and GE. The UDF® was memorable for its scimitar shaped propeller blades and its unique noise signature. Design methods of the time were not able to optimise for both high aerodynamic efficiency and low noise simultaneously. Contemporary CFD/CAA based design methods can produce open rotor blade designs that maintain efficiency with acceptable acoustic signatures. Tests of two generations of new open rotor designs were conducted in the 9’ × 15’ Low Speed Wind Tunnel and the 8’ × 6’ Supersonic Wind Tunnel starting in late 2009 and completed in early 2012. Aerodynamic performance and acoustic data were obtained for take-off, approach and cruise conditions in isolated and semi-installed configurations. Additional detailed flow diagnostic measurements and acoustic measurements, including canonical shielding configurations, were obtained by NASA. NASA and GE conducted joint systems analysis to evaluate the performance of the new blade designs on a Boeing 737 class aircraft. The program demonstrated a 2-3% improvement in overall net efficiency relative to the best efficiency designs of the 1980s while nominally achieving 15-17 EPNdB noise margin to Chapter 4 (at a Technology Readiness Level of 5) for a notional aircraft system defined by NASA.

Type
Research Article
Copyright
Copyright © Royal Aeronautical Society 2014 

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