论文信息 - Design and Test of an Ultralow Solidity Flow-Controlled Compressor Stator

Design and Test of an Ultralow Solidity Flow-Controlled Compressor Stator

A full annulus fluidic flow-controlled compressor stator ring was designed and tested in the third stage of a four-stage low-speed research compressor. The solidity of the flow-controlled stator was near unity and significantly below design practice with a commensurately high diffusion factor. The design intent was to reduce the vane count by 30% and load the stator to the point of stall at the design point, then employ flow control to restore attached boundary layers and regain design-point stage matching. The flow control applied, which maintained attached flow, was 1% of the compressor mass flow and was introduced via discrete steady jets on the suction side of the stator. The design method used steady Computational Fluid Dynamics (CFD) with the flow control jets simulated to drive stator exit angles, velocities, and blockage to match the baseline machine. The experiment verified the pretest predictions and demonstrated degraded compressor performance without flow control and restoration of the pumping characteristics of the baseline high solidity compressor when flow control was applied. An assessment of the engine cvcle impact of the flow-controlled compressor shows a 2.1 point stage efficiency reduction for the increased loading. Extrapolation of the data and analysis to a high-speed compressor shows a more modest 0.5 point stage efficiency trade.

Hyoun-Woo Shin | B. F. Beacher | Kevin Richard Kirtley | P. Graziosi | Peter Wood

[1] D. MacMartin,et al. Flow Control Opportunities in Gas Turbine Engines , 2000 .

[2] D. C. Wisler,et al. Loss Reduction in Axial-Flow Compressors Through Low-Speed Model Testing , 1985 .

[3] Dennis E. Culley,et al. Active Flow Separation Control of a Stator Vane Using Surface Injection in a Multistage Compressor Experiment , 2003 .

[4] W. Ball. Experimental investigation of the effects of wall suction and blowing on the performance of highly offset diffusers , 1983 .

[5] Mark G. Turner,et al. Three-Dimensional Navier-Stokes Computations of Transonic Fan Flow Using an Explicit Flow Solver and an Implicit κ–ϵ Solver , 1992 .

[6] Ian K. Jennions,et al. An Investigation of Turbulence Modeling in Transonic Fans Including a Novel Implementation of an Implicit k–ε Turbulence Model , 1993 .

[7] B. F. Beacher,et al. The Impact of Forward Swept Rotors on Tip-Limited Low-Speed Axial Compressors , 2003 .

[8] Wing Ng,et al. Aerodynamic performance of a high-turning compressor stator with flow control , 2001 .

[9] Scott D. Hunter,et al. Endwall Cavity Flow Effects on Gaspath Aerodynamics in an Axial Flow Turbine: Part II — Source Term Model Development , 2000 .

[10] Jack L. Kerrebrock,et al. Experimental Investigation of an Aspirated Fan Stage , 2002 .

[11] W. Ball. Tests of wall blowing concepts for diffuser boundary layer control , 1984 .

[12] The Fluid Dynamics of LPT Blade Separation Control Using Pulsed Jets , 2001 .