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Abstract
Accurate prediction of heat transfer in compressor cavities is crucial to the design of efficient and reliable aircraft engines. The heat transfer affects the thermal expansion of the compressor rotor and, in turn, the tip clearance of the compressor blades. This paper presents a novel, physically-based predictive theoretical model of heat transfer and flow structure in an open compressor cavity, which can be used to accurately calculate disc temperatures. The radially higher region of the cavity is dominated by buoyancy effects created by the temperature difference between the hot mainstream flow and the axial through flow used to cool the turbine. Strong interaction between the air in the cavity and this through flow creates a mixing region at low radius. For a given geometry, the heat transfer and flow physics are governed by four parameters: the rotational Reynolds number Re ϕ, the buoyancy parameter βΔT, the compressibility parameter χ, and the Rossby number Ro. The model quantifies both the buoyancy- and throughflow-induced mass and heat transfer, producing a reliable prediction of the disc and air temperatures. The model takes into account a two-fold effect of the throughflow: being entrained into the cold radial plumes directly and creating a toroidal vortex in the radially lower region of the cavity. The exchange of mass between the cavity and throughflow is related to the mass flow rate in the radial plumes in the buoyancy-induced region, considering the effect of flow reversal at low Ro. The model is validated using data collected in the Bath Compressor Cavity Rig and can be incorporated in engine design codes to robustly compute the thermal stress and expansion of the compressor rotor, contributing to more efficient engine designs.
Original language | English |
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Article number | 041001 |
Journal | Journal of Turbomachinery: Transactions of the ASME |
Volume | 146 |
Issue number | 4 |
Early online date | 15 Dec 2023 |
DOIs | |
Publication status | Published - 30 Apr 2024 |
Funding
The research presented in this paper was supported by the UK Engineering and Physical Sciences Research Council and in collaboration with Rolls-Royce plc, under the grant number EP/P003702/1. The authors are very grateful for the support of Carl Sangan, Oliver Pountney and, especially, the late Professor J Michael Owen.
Keywords
- buoyancy-induced flow
- high-pressure compressor
- rotating cavity
- theoretical modelling
ASJC Scopus subject areas
- General Engineering
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Modelling of Buyancy-Induced Flow in Compressor Rotors - Surrey/RR
Lock, G. (PI), Sangan, C. (CoI), Scobie, J. (CoI) & Wilson, M. (CoI)
Engineering and Physical Sciences Research Council
11/01/17 → 31/12/20
Project: Research council