This paper describes stall flutter, which can occur at part speed operating conditions near the stall boundary. Although it is called stall flutter, this phenomenon does not require the stalling of the fan blade in the sense that it can occur when the slope of the pressure rise characteristic is still negative. This type of flutter occurs with low nodal diameter forward traveling waves and it occurs for the first flap (1F) mode of blade vibration. For this paper, a computational fluid dynamics (CFD) code has been applied to a real fan of contemporary design; the code has been found to be reliable in predicting mean flow and aeroelastic behavior. When the mass flow is reduced, the flow becomes unstable, resulting in flutter or in stall (the stall perhaps leading to surge). When the relative tip speed into the fan rotor is close to sonic, it is found (by measurement and by computation) that the instability for the fan blade considered in this work results in flutter. The CFD has been used like an experimental technique, varying parameters to understand what controls the instability behavior. It is found that the flutter for this fan requires a separated region on the suction surface. It is also found that the acoustic pressure field associated with the blade vibration must be cut-on upstream of the rotor and cut-off downstream of the rotor if flutter instability is to occur. The difference in cut off conditions upstream and downstream is largely produced by the mean swirl velocity introduced by the fan rotor in imparting work and pressure rise to the air. The conditions for instability therefore require a three-dimensional geometric description and blades with finite mean loading. The third parameter that governs the flutter stability of the blade is the ratio of the twisting motion to the plunging motion of the 1F mode shape, which determines the ratio of leading edge (LE) displacement to the trailing edge (TE) displacement. It will be shown that as this ratio increases the onset of flutter moves to a lower mass flow.
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February 2016
Research-Article
Aeroelastic Instability in Transonic Fans
Mehdi Vahdati,
Mehdi Vahdati
Mechanical Engineering Department,
Imperial College London,
Exhibition Road,
London SW7 2AZ, UK
e-mail: m.vahdati@imperial.ac.uk
Imperial College London,
Exhibition Road,
London SW7 2AZ, UK
e-mail: m.vahdati@imperial.ac.uk
Search for other works by this author on:
Nick Cumpsty
Nick Cumpsty
Mechanical Engineering Department,
Imperial College London,
Exhibition Road,
London SW7 2AZ, UK
e-mail: n.cumpsty@imperial.ac.uk
Imperial College London,
Exhibition Road,
London SW7 2AZ, UK
e-mail: n.cumpsty@imperial.ac.uk
Search for other works by this author on:
Mehdi Vahdati
Mechanical Engineering Department,
Imperial College London,
Exhibition Road,
London SW7 2AZ, UK
e-mail: m.vahdati@imperial.ac.uk
Imperial College London,
Exhibition Road,
London SW7 2AZ, UK
e-mail: m.vahdati@imperial.ac.uk
Nick Cumpsty
Mechanical Engineering Department,
Imperial College London,
Exhibition Road,
London SW7 2AZ, UK
e-mail: n.cumpsty@imperial.ac.uk
Imperial College London,
Exhibition Road,
London SW7 2AZ, UK
e-mail: n.cumpsty@imperial.ac.uk
Contributed by the Turbomachinery Committee of ASME for publication in the JOURNAL OF ENGINEERING FOR GAS TURBINES AND POWER. Manuscript received July 13, 2015; final manuscript received July 21, 2015; published online September 7, 2015. Editor: David Wisler.
J. Eng. Gas Turbines Power. Feb 2016, 138(2): 022604 (14 pages)
Published Online: September 7, 2015
Article history
Received:
July 13, 2015
Revised:
July 21, 2015
Citation
Vahdati, M., and Cumpsty, N. (September 7, 2015). "Aeroelastic Instability in Transonic Fans." ASME. J. Eng. Gas Turbines Power. February 2016; 138(2): 022604. https://doi.org/10.1115/1.4031225
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