The present invention relates to a casing for a blade, for example a fan blade as may be used in a turbofan gas turbine engine.
Fan flutter and other vibration continues to be a significant issue. The traditional route to reduce this is to avoid engine running ranges or blade/fan set vibration modes, but this is particularly difficult at take off. Alternative methods include re-camber and increased blade chord.
Turbofan clapperless fan blades may suffer from vibration where aerodynamic forces lead to excitation of a fan blade's natural modes of vibration, e.g. second flap mode, away from coincidence with the harmonics of a fan blades rotational speed, i.e. a non integral vibration.
Flutter has continued to cause difficulties for many years, there is no fundamental solution which can be applied without a major performance penalty. As a result engines are designed as close to the limit as possible. Partial solutions which are used when flutter cannot be designed out include rolling take off and keep out zones, both of which are unattractive from an operational stand point.
Furthermore, re-camber and increased blade chord, reduce efficiency and increase weight respectively.
Accordingly the present invention seeks to address these issues.
According to the present invention there is provided a turbomachine casing assembly comprising a casing adapted to encase an aerofoil structure, the aerofoil structure having a tip, a leading edge and a trailing edge, the casing substantially surrounding the tip of the aerofoil structure, wherein the casing has a set-back portion extending from a position in the region of one of the leading edge and the trailing edge of the aerofoil structure part way towards a position in the region of the other of the leading edge and trailing edge and set back from a portion of the casing adjacent to the aerofoil structure and away from the aerofoil structure, such that the set-back portion permits a flow over a corresponding portion of the tip of the aerofoil structure.
The turbomachine casing assembly may further comprise a porous liner provided in the set-back portion of the casing. The porous liner may be capable of permitting the flow over the tip of the aerofoil structure to pass through the porous liner.
The porous liner may be abradable. The porous liner may comprise an open-celled foam. The porous liner may comprise a honeycomb structure.
A porosity of the porous liner may be selected so that the flow through the porous liner may be dominated by a portion of the flow through the porous liner closer to the tip of the aerofoil structure.
A surface of the porous liner facing the tip of the aerofoil structure may be level with the portion of the casing adjacent to the aerofoil structure. The portion of the casing adjacent to the aerofoil structure may comprise an abradable liner.
The aerofoil structure may rotate with respect to the casing. The aerofoil structure may be a fan blade. A turbomachine may comprise the turbomachine casing assembly described above. A gas turbine engine may comprise the turbomachine casing assembly described above.
In summary, embodiments of the present invention may provide for blade vibration damping by utilising passive modulation of blade tip clearance. Embodiments of the present invention may provide for extended blade life due to reduction in high cycle fatigue, reduced blade generated noise due to blade damping, reduced blade tip generated noise due to disrupted over tip vortex. With embodiments of the present invention problems of reduced fan efficiency and/or increased weight may be at least mitigated. Tip clearance modulation in accordance with embodiments of the present inventions may have a significant effect on blade vibration, for example in fans and/or compressors.
For a better understanding of the present invention, and to show more clearly how it may be carried into effect, reference will now be made, by way of example, to the accompanying drawings, in which:—
A turbofan gas turbine engine 10, as shown in
An exemplary fan blade 26 to which the present invention may relate is shown more clearly in
Aerodynamic disturbances caused by vibration of the blades 26 could excite appropriate modes in the casing 30 that would in turn modulate the tip clearance. It is suspected that changes in tip clearance cause a modulation in the energy loss due to tip leakage and hence a modulation in the aerodynamic loading, particularly around the tip 48. This loading modulation can provide a vibration excitation. Dependent on modal coincidences, mode strengths and exact phasing, the mechanism can provide strong excitation or damping.
Small changes in tip clearance may cause major performance penalties i.e. energy loss. This energy loss may be manifested as a reduction of the blade loading around the tip. A modulation in this energy loss can provide vibration forcing/damping.
A simplified illustration is shown in
Since this is frequency doubled, it can have no effect on the blade vibration in the flap mode. However, in accordance with the present invention it has been appreciated that it is desirable to modulate once per cycle. Such a modulation has the potential to provide an aerodynamic forcing which is at the same frequency as the blade vibration and the phase of this forcing may be changed by 180° to provide damping.
The real situation is more complex than is illustrated in
With a simple model, the effect from the leading and trailing edges would however be equal and opposite so would cancel each other out. Asymmetry in geometry or local aerodynamic loading could lead to an out of balance effect that will result in blade forcing. This may be likely to occur in existing designs and may be the root of some vibration problems. However, in accordance with the present invention, this effect may be enhanced by deliberately increasing the tip clearance towards the leading or trailing edge such that it would reduce the effect in that region, leaving the other edge to dominate and provide a useful effect.
Accordingly, with reference to
The casing 30 comprises a set-back portion 54 extending from a position in the region of one of the leading edge 44 and the trailing edge 46 of the aerofoil structure 26 part way towards a position in the region of the other of the leading edge 44 and trailing edge 46 and set back from a portion of the casing adjacent to the aerofoil structure (i.e. the remainder of the casing) and away from the aerofoil structure 26. In the example shown in
In the specific embodiment described, and shown in
The set-back portion 54 permits a deliberate flow beyond that which would otherwise occur due to leakage over a corresponding portion of the tip 48 of the aerofoil structure 26. The corresponding portion is a portion of the tip 48, which is opposite the set back portion of the casing. The set-back portion may for example be dimensioned to increase the tip clearance area (compared to a casing without the set-back portion) vis-à-vis the casing equivalent to 1% of the aerofoil structure (e.g. fan) area.
The present invention may have the effect of creating an imbalance between the opposing forces at the leading and trailing edge as the aerofoil structure vibrates. For example, as shown in
However, the set back portion 54 may have the drawback of changing depth with any rub and subsequent removal of the abradable lining of casing 30. This change in depth would change the effectiveness of the mechanism or require an excessively deep cut back which would cause a fan efficiency loss. To alleviate this, the cut back 54 may be filled with a porous or flow reducing medium, which may be level with the abradable lining and may also be abradable by tip rubs.
Accordingly, with reference to
The porous liner 56 may be abradable. As such, the thickness T of the porous liner may be abraded by the blade tip 48. A surface of the porous liner facing the tip 48 of the aerofoil structure 26 may be level with the remainder of the casing 30. The remainder of the casing 30 may comprise an abradable liner 60. The porous filler 56 may be an open celled foam.
With reference to
The porous lining 56 may comprise a honeycomb structure with suitable passages made between the cells. These may be made below the level where the material is intended to be abraded so that they may not change as the material is removed.
The present invention alleviates or reduces blade flutter by a purely passive means. In other words, the present invention damps blade vibration by utilising passive modulation of the blade tip clearance. As a result, the blade life may be extended due to a reduction in high cycle fatigue. Likewise, noise levels may be reduced due to the blade damping and the disrupted over tip vortex. The present invention may achieve these advantages without reducing the fan efficiency and/or increasing the weight, which may be the case for current solutions to the aforementioned problem.
The present invention is for example applicable to clapperless fan blades which lead to excitation of other natural modes of vibration, e.g. first flap mode, third flap mode, first torsion mode, second torsion mode or combinations thereof or any of the first ten fundamental vibration modes. The present invention is applicable to metal fan blades and fan blades having a hybrid structure, e.g. composite fan blades. In the case of some designs of hybrid structured fan blades there may be other natural modes of vibration that are not easy to describe using first flap mode, second flap mode, third flap mode, first torsion mode or second torsion mode because the complex structure of these hybrid structured fan blades may distort such mode shapes out of recognition.
The present invention is however also applicable to other fan or turbine applications or turbomachinery blades, including e. g. fans in ventilation subsystems or automotive applications, centrifugal compressors etc.
Number | Date | Country | Kind |
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1014022.6 | Aug 2010 | GB | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP2011/063429 | 8/4/2011 | WO | 00 | 2/22/2013 |
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WO2012/025358 | 3/1/2012 | WO | A |
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