This invention relates to containment systems for gas turbine engines.
The mounting of gas turbine engines above the fuselage of an aircraft has advantages with respect to noise reduction. However, there may be some issues concerning rotor failures that need to be addressed.
According to one aspect of this invention, there is provided a containment system for a gas turbine engine, the containment system comprising a force absorbing arrangement for absorbing the force exerted thereon by an ejected portion of a failed component of the engine, wherein the force absorbing arrangement circumferentially surrounds at least a major proportion of the axial length of the engine.
The aforesaid component may comprise a high energy component. The component may comprise a disk. The component may comprise a compressor or a turbine disk.
Preferably, the force absorbing arrangement extends substantially the axial length of the engine.
Preferably, the force absorbing arrangement comprises a force absorbing material. A suitable material is a polyamide, such as an aramid, typically a para-aramid. In one embodiment, the force absorbing material may comprise poly-paraphenylene terephthalamide. An example of such a material is sold under the registered trade mark KEVLAR.
The engine may include rotary driving components. A casing may surround the rotary driving components. The rotary driving components may comprise a fan, a compressor arrangement, and a turbine arrangement.
The casing may comprise radially inner and outer skins. The force absorbing arrangement may be provided on the casing, preferably between the inner and outer skins of the casing. In one embodiment, the casing may comprise a nacelle for surrounding the engine. The force absorbing arrangement may be provided as a layer on one of the inner and/or outer skins. Desirably, the force absorbing arrangement is provided on the inner skin.
Alternatively or in addition, the force absorbing arrangement may comprise a corrugated outer skin of the casing.
A plurality of support members may be provided within the casing. Each support member may extend circumferentially around the casing, and may extend from the inner skin to the outer skin. In a preferred embodiment, the support members provide strengthening between the inner and outer skins. Each support member may constitute a bulkhead extending from the inner skin to the outer skin of the casing.
The support members may be spaced from one another axially along the casing. The support members may divide the casing into a plurality of compartments. A pedestal may extend from the casing to mount the engine on an aircraft. In one embodiment, support members extend to the pedestal. Thus, in this embodiment, each support member transmits loads thereon to the pedestal.
The provision of the support members provides the advantage in an embodiment of the invention that a load exerted on the force absorbing arrangement is constrained by the support members to prevent excessive deformation of the casing and of force absorbing material.
Where the engine includes a fan, the force absorbing arrangement may comprise a portion of the force absorbing material surrounding the fan, and a further portion of the force absorbing material circumferentially surrounding the remainder of the rotary components.
Where the gas turbine engine includes an intermediate case, arranged between the high pressure and intermediate pressure compressor, the force absorbing material may comprise a first portion of the force absorbing material extending from a region surrounding the fan to a region surrounding the intermediate pressure compressor of the engine. The force absorbing arrangement may comprise a second portion of the force absorbing material extending from a region surrounding the high pressure compressor to a region surrounding or downstream of the low pressure turbine.
The force absorbing material may be wrapped around the engine with appropriate tension to allow the force absorbing material to deform radially outwardly within the casing when absorbing the force of the ejected portion of the failed component. The outer skin of the casing may be formed of a corrugated material to allow radially outward deformation thereof if the force absorbing material impacts thereon on radially outwardly formation of the force absorbing material. The engine may be secured to the case by strengthening arrangements. Each strengthening arrangement may comprise an A frame extending from the engine to the casing. In one embodiment, the force absorbing portion may comprise a corrugated outer skin.
According to another aspect of this invention, there is provided an engine arrangement comprising a gas turbine engine having a containment system as described above: and a pedestal to support the engine on an aircraft.
Preferably, the containment system includes a casing extending circumferentially around rotary driving components of the engine, as a plurality of support members extending circumferentially around the casing wherein each support member extends to the casing. Thus, loads of support members can be transmitted to the pedestal.
The engine arrangement may include a chamber externally of the engine to include ancillary components of the engine. The ancillary components may include a power off take arrangement to extract power from a main shaft of the engine. The power off take arrangement may include an off take shaft extending from the aforesaid main shaft of the engine to the chamber, and a gear arrangement to transmit rotary power from the shaft to further components.
Embodiments of the invention will now be described by way of example only, with reference to the accompanying drawings, in which:
Referring to
Some of the air driven by the fan 14 passes along the bypass duct 18 to be exhausted through an exhaust nozzle 32 to provide a propulsive force. The remainder of the air driven by the fan 14 passes through the engine core 16 to the exhaust via the exhaust nozzle 32.
The fan 14, the compressors 23, 24 and the turbines 26, 28, 30 are mounted on rotating discs.
In each embodiment shown in
The nacelle 12 is formed of inner and outer skins 36, 38, and the force absorbing material is provided as a layer between the inner and outer skins 36, 38 on the inner skin 36.
The force absorbing material 34 is in the form of poly-paraphenylene terephthalamide. A suitable such material is sold under the registered trade mark KEVLAR.
The force absorbing material is wrapped around the inner skin 36 of the nacelle 12 with appropriate low tension to allow it to deform radially outwardly in the event of impact thereon by a failed fragment of a rotating component such as a compressor or turbine disc.
The force absorbing material 34 extends substantially the axial length of the engine, to the region upstream of the fan 14 to a region downstream of the low pressure turbine 30. Thus, the rotating components of the engines 10A and 10B are circumferentially surrounded by the force absorbing material 34.
In the embodiment shown in
In the embodiment shown in
In the above described embodiment, the ancillary components of the engine, such as the power take off gearbox are held within a chamber in the aircraft fuselage, and this is described in more detail below with reference to
Referring to
The inner and outer skins 36, 38 define between them a circumferentially extending space 46, and within the space 46 are provided a plurality of support members in the form of annular bulkheads 48, 50, 52, 53 each of which extends around the nacelle 12. The bulkheads 48, 50, 52, 53 provide support and strengthening to the nacelle 12, in that in the event of the force absorbing material 34 being radially outwardly deformed by an impact thereon, the bulkheads 48, 50, 52, 53 resist the deformation of the inner skin to maintain the integrity of the nacelle 12.
Referring to
The nacelle 12 is supported by a pedestal 56 which provides a means of attachment of the engine to the fuselage of an aircraft.
Referring to
Referring to
A trap door 62 provides an opening 63 to allow access from the chamber 60 to the engines 10X, 10Y. The trapdoor 62 can be connected by a hinge 64 to the fuselage 58.
The trap door 62 is connected by releasable hinges 64 to each opposite side of the opening 63, thus allowing it to be opened in either direction, as shown in solid lines and in broken lines in
When it is desired to carry out maintenance on the right hand engine 10Y (as shown in
If the maintenance worker desires to work on the left hand engine 10X, the trapdoor 62 can be closed and the left hand hinge re-engaged with the trap door 62. The right hand hinge can then be released to allow the trapdoor 62 to be swung outwardly towards the engine 10X to the position shown in broken lines in
Each of the engines 10a, 10b can be located in its correct position on the fuselage 58 by dowels 64 provided at opposite end regions of the pedestal 56 at the interface between the pedestal 56 and the fuselage 58. The dowels 64 extend into suitable recesses in the respective pedestal 56 of each of the engines 10a, 10b.
Referring to
There is thus described a simple and effective way to contain fragments of failed components of a gas turbine engine to prevent the failed components bursting from the engine and causing damage elsewhere, for example to the fuselage, wings or tail fins of the aeroplane, or to the adjacent other engine. A further modification is that other force absorbing materials could be used, for example metallic or non-metallic structures, knitted structures, feather type armour, or bulk head containment. In the further modification, a tie member could extend between the engines to share the load.
Whilst endeavouring in the foregoing specification to draw attention to those features of the invention believed to be of particular importance it should be understood that the Applicant claims protection in respect of any patentable feature or combination of features hereinbefore referred to and/or shown in the drawings whether or not particular emphasis has been placed thereon.
Number | Date | Country | Kind |
---|---|---|---|
0602362.6 | Feb 2006 | GB | national |