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High Efficiency Centrifugal Compressor for Rotorcraft ApplicationsThe report "High Efficiency Centrifugal Compressor for Rotorcraft Applications" documents the work conducted at UTRC under the NRA Contract NNC08CB03C, with cost share 2/3 NASA, and 1/3 UTRC, that has been extended to 4.5 years. The purpose of this effort was to identify key technical barriers to advancing the state-of-the-art of small centrifugal compressor stages; to delineate the measurements required to provide insight into the flow physics of the technical barriers; to design, fabricate, install, and test a state-of-the-art research compressor that is representative of the rear stage of an axial-centrifugal aero-engine; and to acquire detailed aerodynamic performance and research quality data to clarify flow physics and to establish detailed data sets for future application. The design activity centered on meeting the goal set outlined in the NASA solicitation-the design target was to increase efficiency at higher work factor, while also reducing the maximum diameter of the stage. To fit within the existing Small Engine Components Test Facility at NASA Glenn Research Center (GRC) and to facilitate component re-use, certain key design parameters were fixed by UTRC, including impeller tip diameter, impeller rotational speed, and impeller inlet hub and shroud radii. This report describes the design effort of the High Efficiency Centrifugal Compressor stage (HECC) and delineation of measurements, fabrication of the compressor, and the initial tests that were performed. A new High-Efficiency Centrifugal Compressor stage with a very challenging reduction in radius ratio was successfully designed, fabricated and installed at GRC. The testing was successful, with no mechanical problems and the running clearances were achieved without impeller rubs. Overall, measured pressure ratio of 4.68, work factor of 0.81, and at design exit corrected flow rate of 3 lbm/s met the target requirements. Polytropic efficiency of 85.5 percent and stall margin of 7.5 percent were measured at design flow rate and speed. The measured efficiency and stall margin were lower than pre-test CFD predictions by 2.4 percentage points (pt) and 4.5 pt, respectively. Initial impressions from the experimental data indicated that the loss in the efficiency and stall margin can be attributed to a design shortfall in the impeller. However, detailed investigation of experimental data and post-test CFD simulations of higher fidelity than pre-test CFD, and in particular the unsteady CFD simulations and the assessment with a wider range of turbulence models, have indicated that the loss in efficiency is most likely due to the impact of unfavorable unsteady impeller/diffuser interactions induced by diffuser vanes, an impeller/diffuser corrected flow-rate mismatch (and associated incidence levels), and, potentially, flow separation in the radial-to-axial bend. An experimental program with a vaneless diffuser is recommended to evaluate this observation. A subsequent redesign of the diffuser (and the radial-to-axial bend) is also recommended. The diffuser needs to be redesigned to eliminate the mismatching of the impeller and the diffuser, targeting a slightly higher flow capacity. Furthermore, diffuser vanes need to be adjusted to align the incidence angles, to optimize the splitter vane location (both radially and circumferentially), and to minimize the unsteady interactions with the impeller. The radial-to-axial bend needs to be redesigned to eliminate, or at least minimize, the flow separation at the inner wall, and its impact on the flow in the diffuser upstream. Lessons were also learned in terms of CFD methodology and the importance of unsteady CFD simulations for centrifugal compressors was highlighted. Inconsistencies in the implementation of a widely used two-equation turbulence model were identified and corrections are recommended. It was also observed that unsteady simulations for centrifugal compressors require significantly longer integration times than what is current practice in industry.
Document ID
20180001471
Acquisition Source
Glenn Research Center
Document Type
Contractor Report (CR)
Authors
Gorazd Medic
(United Technologies Research Center East Hartford, Connecticut, United States)
Om P Sharma
(United Technologies Research Center East Hartford, Connecticut, United States)
Joo Jongwook
(United Technologies Research Center East Hartford, Connecticut, United States)
Larry W Hardin
(United Technologies Research Center East Hartford, Connecticut, United States)
Duane C McCormick
(United Technologies Research Center East Hartford, Connecticut, United States)
William T Cousins
(United Technologies Research Center East Hartford, Connecticut, United States)
Elizabeth A Lurie
(United Technologies Research Center East Hartford, Connecticut, United States)
Aamir Shabbir
(United Technologies Research Center East Hartford, Connecticut, United States)
Brian M Holley
(United Technologies Research Center East Hartford, Connecticut, United States)
Paul R Van Slooten
(United Technologies Research Center East Hartford, Connecticut, United States)
Date Acquired
February 26, 2018
Publication Date
October 1, 2017
Publication Information
Publisher: National Aeronautics and Space Administration
Subject Category
Aircraft Propulsion And Power
Report/Patent Number
E-18856-1
NASA/CR-2014-218114/REV1
GRC-E-DAA-TN31660
Report Number: E-18856-1
Report Number: NASA/CR-2014-218114/REV1
Report Number: GRC-E-DAA-TN31660
Funding Number(s)
WBS: 380046.02.03.02.01.02
CONTRACT_GRANT: NNC08CB03C
Distribution Limits
Public
Copyright
Public Use Permitted.
Keywords
Centrifugal compressor
Compressor aerodynamics
Turbomachinery
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