Affiliation:
1. Rolls-Royce plc, Derby, DE24 8BJ England
Abstract
In modern gas turbine engines, up to 20% of the core airflow is bled off from various compressor stages to facilitate internal cooling, bearing chamber, and rim sealing, as well as axial load management. As this secondary airflow makes no direct contribution to engine thrust, there are strong economic incentives to reduce the quantity and quality of offtake air and maximize its effective use. Secondary airflows are commonly bled off via circular drillings in the compressor rotor, thereby augmenting their swirl velocity. This results in the creation of vortices within the rotor cavity and strong radial pressure gradients opposing inflow. In the present work the relative performance of a series of noncircular offtake passages has been assessed using CFD techniques. The results of this work demonstrate the degree of control that may be exercized over swirl uptake, which can be used to suppress the creation of vortices in rotor cavities.
Reference10 articles.
1. Brillert, Reichert, and Simon, 1999, “Calculation of Flow Losses in Rotating Passages of Gas Turbine Cooling Systems,” ASME Paper 99-GT-251.
2. ICEM CFD Tutorial Manual, 2000, Direct CAD Interfaces, Version 4.0, ICEM CFD, Mar.
3. ICEM CFD Tutorial Manual, 1999, Meshing Modules, Version 4.0, ICEM CFD, Feb.
4. Chew, and Snell, 1988, “Prediction of Pressure Distribution for Radial Inflow between Co-Rotating Discs,” ASME Paper 88-GT-127.
5. Chew, and Owen, 1989, “The Use of De-Swirl Nozzles to Reduce the Pressure Drop in a Rotating Cavity with Radial Inflow, Farthing,” ASME Paper 89-GT-184.
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