The present invention relates to component structures, and more particularly to structures such as those utilised in gas turbine engines.
Referring to
The gas turbine engine 10 works in a conventional manner so that air entering the intake 11 is accelerated by the fan 12 which produce two air flows: a first air flow into the intermediate pressure compressor 13 and a second air flow which provides propulsive thrust. The intermediate pressure compressor compresses the air flow directed into it before delivering that air to the high pressure compressor 14 where further compression takes place.
The compressed air exhausted from the high pressure compressor 14 is directed into the combustion equipment 15 where it is mixed with fuel and the mixture combusted. The resultant hot combustion products then expand through, and thereby drive, the high, intermediate and low pressure turbines 16, 17 and 18 before being exhausted through the nozzle 19 to provide additional propulsive thrust. The high, intermediate and low pressure turbine 16, 17 and 18 respectively drive the high and intermediate pressure compressors 14 and 13, and the fan 12 by suitable interconnecting shafts.
In view of the above it will be appreciated that blades and in particular compressor blades within a gas turbine engine need to be sufficiently rigid to define a shape for function. In such circumstances the blades have tended to incorporate a reinforcing girder-like structure.
Such rigid structures including a girder core, and possibly a filling for damping, have tended not to be optimised to achieve best damping within the structure. It will be appreciated that a robust internal girder structure is rigid and so does not permit damping materials held within the cavity of the blade structure to operate effectively. Rigidity denies flexibility and therefore there may be additional problems with regard to cracking and early fatigue within the blade structure. The rigidity of the blade's structure prevents it transmitting loads in shear, which is the principal mechanism by which the damping medium operates.
A further disadvantage of rigid, girder-like structures is that they typically divide the internal space of the structure into a plurality of separate cavities. If a damping medium is to be used, each of these cavities must be separately filled with the damping medium, which greatly increases the time and cost to manufacture such structures.
If, by contrast, no internal structure is provided, all the radial loads on the blade in use must be carried by the outer skins, which must therefore be thicker and heavier. Also, there is nothing to prevent movement of the damping medium within the blade structure.
It is therefore an object of this invention to provide a component structure that will reduce, or preferably overcome, the disadvantages of known arrangements as described above.
In accordance with the invention there is provided a component structure as set out in the claims.
The invention will now be described, by way of example only, with reference to the accompanying drawings in which:
As indicated above, prior component structures such as those used in blades have not fully utilised damping materials and media in the structure; so it is desirable to provide some flexibility in the structure. However, that flexibility must not be at the expense of achieving adequate blade definition and shaping for function. The invention provides flexibility through use of a web former which presents a skin of a structure using bond areas suspended upon a membrane. Thus, in comparison with prior girder structures, the presentation and support of the skin forming the blade structure is discontiguous and suspended on the membrane.
The web former can be made from any appropriate material, and comprises a single layer or multiple layers, normally of perforated metallic or non-metallic web. Generally, the web former is secured to at least one skin through diffusion bonding, or possibly by an appropriate adhesive.
The web former 31 has membrane sections 35 which angularly extend between the bond areas 33, 34. In such circumstances, the bond areas 33, 34 are effectively suspended upon the web membranes 35, extending between them. In such circumstances, the bond areas 33, 34 are laterally displaced relative to each other. The degree of such lateral spacing is dependent upon the membranes 35, and therefore it will be appreciated that the web former 31—through appropriate shaping in terms of depth, angle and size of membranes 35—along with bond areas 33, 34 can define a shape for skins 32 or layers as required.
Normally, at least one of the bond areas 33, 34 is secured to a skin 32; whilst the other skin may simply be offset by abutment of a bond pad with the skins to provide even greater flexibility in the structural parts of the blade structure 30, and to utilise the damping capabilities of the damping material located about and embedding the web former 31.
As illustrated in
It will be appreciated that the robustness of presentation and shaping of the bond structure in accordance with the invention depends, as indicated, upon the dimensions and angles of the membranes extending between bond areas. There will be a limit to the capabilities of such configurations. Thus, to achieve appropriate or desired shaping, as depicted in
As indicated above, generally the web formers will be surrounded or embedded in a damping material. Thus, as the structure flexes the membranes will similarly flex to allow the damping material to absorb vibrations and acoustic noise. It is also possible to provide—either between the bonding areas in engagement with the skin, or between bonding areas engaging each other in stacks or web formers as depicted in FIG. 4—a layer of damping material 55. As depicted in
As indicated above, web formers in accordance with the invention are generally secured at least to one skin defining the shape for the blade structure. Thus, as depicted in
It will be appreciated that the invention depends upon the bonding areas providing anchors or support positions for the skin of the blade structure. Particularly where the bond areas are secured to the skin, care must be taken that the flexing of the associated web membranes does not overly stress the skin or the membrane itself. In such circumstances, as depicted in
An alternative form of web former in accordance with the invention is to use an undulating strip or ribbon as depicted in
Typically, in order to provide appropriate support over the full width and length of a blade structure it will be appreciated that a plurality of undulating strips or ribbons will be provided. Thus, as illustrated in
The choice and position of the undulating strips 92, 102, 106 is dependent upon desired reinforcement and presentation utilisation, in association with damping materials, in a blade structure 90, 100. In such circumstances for appropriate shaping, as indicated, the undulating strips or ribbons act as web formers which are distributed appropriately to define the shape and can have different undulation spacing and sizing as appropriate.
In accordance with the invention, by positioning of the bonding areas along with the membranes between them, in terms of width, orientation and angle, adequacy of reinforcement whilst maintaining flexibility for use in combination with a damping material is achieved. The bond areas are effectively suspended upon the membranes between for flexibility. The distribution of the bond areas will be chosen dependent upon expected impact levels and other factors with regard to the component structure.
As indicated, the positioning in the bond areas and their retention is important within a blade structure in accordance with the invention. There will be flexibility about the membranes between the bond areas, and therefore, as indicated above, radial bonding features 89 can be provided to avoid stressing. It will also be understood that a keyed association between skins or panels and the bonding area parts of the web may be provided. As depicted in
The area of the wells 110 will generally be smaller than that of the bond areas. In a typical embodiment, the area of the wells 110 will be about one-fifth the area of the bond areas.
Component structures in accordance with the invention may be formed from ready machined and shaped elements secured together as appropriate.
Alternatively, expansive plastic deformation techniques such as superplastic forming (SPF) can be utilised in order to create the blade structure. In this case, respective panels or skins of material will be presented with membrane former members in a flat state between them. The former members will be secured by appropriate techniques such as diffusion bonding or adhesive at the desired locations and the arrangement sealed about its edge. In such circumstances, once an expansive gas is presented between the skins or panels the arrangement will expand, with retention of the bonding at the bond areas, in order to create the web formers in accordance with the invention. The spacing and sizes of the bond areas, along with inflation pressure etc., will define the shape of the blade. The interconnecting membrane formers between the bond areas will then retain that component structure shape as required. In accordance with the invention, the shaped component structure will then be filled with a damping material. Alternatively, and possibly more conveniently, the damping material may be utilised as the means by which expansion of the component structure is achieved. In such circumstances, subsequent to the bonding process to secure the precursor web formers to the skins or panels and sealing as appropriate the damping material will be forcefully injected between the panels in order to create the structural shape in accordance with the invention. It will be understood that the elastic deformation process may be provided within a shaping mould to limit strain upon the bonding areas in engagement with the skin or panel.
With regard to ribbon or strip web formers, the membranes between the bonding areas will be used in conjunction with a damping filler to achieve a desired structural shaping. These ribbons may be straight or curved or otherwise configured to provide the desired structure. The ribbons can have a regular repeat spacing or non-regular spacing of waves and undulations as required to support and present the structure. The ribbon membranes, in association with a damping filler, will carry some radial load and therefore prevent separation and de-bonding by the damping filler from association with inner surfaces of the blade structure, as well as interlock the damping material as a mechanical feature within the structure. Similarly, a mesh web former will act two dimensionally in order to carry some radial load and therefore prevent separation of the damping filler within the bond structure, as well as interlock the damping filler within the structure for better integration.
By provision of a structure in accordance with the invention, it will be appreciated that the structure can flex in all directions by transmitting shear forces to the internal damping material. Prior blade structures, due to their more rigid girder reinforcement, tend not to flex evenly. By combining the benefits of a web former with a damper material, in accordance with the invention, improved overall performance is achieved without separation, as a result of the load being taken by the web former in combination with the damping filler. The damping medium is inhibited from separating from the structure subsequent to an impact or through normal operational stressing. The damping material is effectively mechanically keyed into the internal structure of the component and is therefore stabilised and bonded into that structure.
It will be appreciated that damping materials in accordance with the invention as well as the use of the web former has little weight penalty compared with an existing structure incorporating robust girders for shaping.
Although a component, and in particular a blade structure, has been utilised as an exemplary embodiment of a hollow structure in accordance with the invention, it will be appreciated that the combination of a web former and damper filler can also be utilised in other structures where greater flexibility for absorption, rather than absolute rigidity, will allow more efficient and effective operation. The invention may be utilised in any hollow structure which is internally supported and where there may be vibrations or impacts which could be beneficially dealt with by absorption rather than simply robustness. Some examples include within gas turbine engine fan blades, containment rings, outlet guide vanes and hollow static structures within the engine.
Modifications and alterations to the embodiments of the invention as described above will be appreciated by those skilled in the art. Thus, for example, typically the web formers will be formed from the same metal or non-metallic material, but it may be desirable to provide different response or mechanical properties in different parts of the structure through the materials or thicknesses of materials or treatments of materials used at those parts.
The skilled person would further recognise that instead of securing the web formers to the skins, at the bond areas using diffusion bonding or adhesive, as described above, they could equally well be secured using another suitable technique, such as brazing or welding.
In the embodiments shown in
Number | Date | Country | Kind |
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0808840.3 | May 2008 | GB | national |
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