This invention relates to an article formed from a composite material, and is particularly, although not exclusively, concerned with such an article in the form of an aerofoil component such as a fan blade of a turbofan engine, turbo prop, ducted fans and other such turbomachinery.
Fan blades, particularly those of turbofan engines, turbo props, ducted fans and other such turbomachinery are subjected to significant forces in operation. Such blades must be capable of withstanding not only centrifugal forces and forces generated by the movement of air, but also forces arising from impact by foreign objects, such as birds. Furthermore, if minor damage occurs as a result of foreign object impact, it is important that the damage does not propagate through the blade during continued operation as to diminish its structural and functional integrity.
Composite fan blades are currently manufactured using highly toughened thermosetting epoxy resin pre-impregnated materials which are laid up in a predetermined stacking sequence to ensure careful distribution of ply terminations in order to achieve the required damage tolerance. It is important that ply terminations (ie cut fibre ends) are not concentrated in a single area or plane, since they represent locations of potential weakness in the blade.
Such manufacturing processes are expensive because the materials are costly, deposition rates are slow and there are stringent quality assurance requirements.
According to the present invention there is provided an article formed from a composite material, the article comprising abutting core components, wherein at least one of the core components comprises a pack of reinforcement rods disposed parallel to each other and embedded in a resin matrix, each rod comprising a resin-bonded bundle of reinforcement fibres.
The rods may have a circular cross-section, although other shapes such as square may be used. The rods may have a transverse dimension (diameter or equivalent) which is not less than 1.5 mm and not more than 3.5 mm. The reinforcement fibres may be carbon fibres which run parallel to the rod length.
The resin matrix may be a cured syntactic material, a tough adhesive composition or a composite bulk-moulding compound.
The pack may be one of a plurality of packs forming the article. The or each pack may comprise not less than 100 reinforcement rods. The packs may be overwrapped by braiding or reinforcement fabric. Each individual reinforcement rod may have an overwinding of reinforcing fibres in a resin matrix.
Each rod may comprise a main body provided with spacing projections so that, in the pack, the main bodies of the respective rods are spaced apart from each other by contact between the projections of adjacent rods or by a projection on one rod and the main body of an adjacent rod. The projections may have a spiral form about the longitudinal axis of the rod and may be a separate winding, for example of wire, or an integral formation on the main body.
In one embodiment in accordance with the present invention, the rods extend substantially parallel to a lengthwise direction of the article.
The article may have an outer skin which encloses the or each pack of reinforcement rods. The outer skin may comprise reinforcement fibres in a resin matrix. The reinforcement fibres of the outer skin may be disposed in fabric layers, for example in a multiaxial warp knit fabric (non-crimp fabric), with each fabric layer comprising fibres extending in different orientations. For example, some of the fibres may extend at 90° to the lengthwise directions of the respective rods, and other fibres may extend at angles between 30° and 60° to the lengthwise direction of the rods. In one embodiment, the multiaxial warp knit fabric has fibres extending at +45°/90°/−45° with respect to the rods.
The area weight in the fabric of the 90° fibres may vary in the lengthwise direction of the rods.
The outer skin may comprise separate preforms made up of stacked layers of the fabric, which layers are bonded to one another to form the preform.
The article may be a component of a gas turbine engine, and in particular may be an aerofoil component such as a fan blade of a turbofan engine.
Another aspect of the present invention provides a method of manufacturing an article of composite material, the method comprising:
assembling a plurality of reinforcement rods into a pack in which the rods are parallel to each other, each rod comprising a resin-bonded bundle of reinforcement fibres;
impregnating the pack with a first settable or curable composition, and causing or allowing the composition to set or cure to form a resin matrix in which the rods are embedded;
providing a fibre wrapping around the pack to form a core component;
assembling a core of the article, the core including abutting core components;
assembling a fibre reinforcement over the core;
placing the core with the assembled fibre reinforcement in a mould corresponding to the desired shape of the article; and
admitting a second settable or curable composition into the mould and causing or allowing the second composition to set or cure.
In an embodiment of a method as defined above, the fibre reinforcement comprises a plurality of preforms, each preform being made up of reinforcing fabric layers.
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:
As shown in
As shown in
After forming of the rod assemblies in the resin matrix, the assemblies are individually overbraided with a biaxial or triaxial overbraiding material, or are wrapped in reinforcement fabric or overwrapping 12.
The overbraided or overwrapped rod packs 4 are then assembled together, and with the other components 6, to form the core 2. The other components 6 may be unreinforced mouldings formed from the resin used for the matrix of the rod packs 4, for example a cured syntactic paste. Alternatively, they may be made from different materials, or they may be replaced by further rod packs 4. Thus in one embodiment, all of the components of the core 2 may be rod packs 4.
The rods 8 themselves, as shown in
Furthermore, the rods 8 may be additionally overwound or moulded with a wire or thread (not shown) in a spiral fashion to provide spacing projections which engage the corresponding projections, or main bodies, of adjacent rods in order to maintain a spacing between the main bodies of the rods to allow penetration of the resin matrix material during manufacture of the rod packs 4.
In one embodiment the core 2 shown in
The preforms 16, 18 may be made from a multi-axial warp knit fabric/non-crimp fabric as diagrammatically represented in
As diagrammatically indicated in
Two cut-outs 26, 28 are represented in
Because the skin formed from the preforms 16, 18 contains only +45° and −45° fibre orientations, the tensile and compressive strain allowable in the spanwise direction of the finished blade can be expected to be relatively high, for example approximately 0.6%.
To avoid stress differentials in the lay-up of the preforms 16, it is desirable for differently “handed” fabrics to be supplied for cutting-out of the pieces 26, 28. Thus, on one side of the central plane of each preform 16, 18, a left-handed fabric is laid-up, and on the other side of the central plane a right-handed fabric is laid-up. The terms left-handed and right-handed are used for convenience to distinguish the two different fabrics. It will be appreciated that if a fabric is constructed in which the lower ply is at +45° to the warp direction X, and the upper ply is at −45° to the warp direction X, this relationship will remain even if the fabric is turned over. In other words, it is not possible to lay-up the fabric so that the lower ply is at −45° to the warp direction. Consequently, the use of matched left and right handed pairs of fabrics as described above provides a balanced symmetric lay-up within the preform 16,18.
Once the preforms have been made, they are placed on opposite sides of the core 2, as shown in
If desired, stitching or tufting may be applied after RTM moulding, in order to secure the outer skin to the core 2 to enhance damage tolerance. In this process, a single needle and reinforcement thread of carbon fibre, glass fibre or aramid/para-aramid are pushed through the skin into the core 2. The friction between the thread and the skin holds the thread in place as the needle is withdrawn, forming a loop or tuft bridging the skin and core 2.
In the finished fan blade represented in
Furthermore, the resin matrix 10 within the which the rods 8 are embedded is effective in transferring loads between adjacent rods, while accepting relatively high strain without failure.
The resin forming the resin matrix 10 can be selected or formulated to provide desired damping characteristics in the structure. The material may be a syntactic gap filling polyurethane or epoxy paste, or a syntactic film may be used in the manufacture of honeycombed sandwich panel composites for the purpose of stabilising or joining core materials. The material may also be of thermoplastic composition.
As an alternative to using such a material, the rod packs 4 may be formed by compression moulding the rods 8 within a bulk moulding compound containing chopped fibre, so creating a quasi-homogenous composite matrix surrounding the rods 8. The chopped fibre may be glass, carbon or a hybrid of the two. The matrix resin is preferably compatible with the rods 8 themselves. A suitable material is available under the name HexMC®, available from Hexcel Corporation of Stamford, Conn., USA.
In the blade shown in
The skins formed from the preforms 16, 18, with the ±45°, 90° fibre reinforcements, provide flutter resistance and torsional stiffness to the component. While the process described above refers to the preforms 16, 18 being applied in dry form (apart from the heat or pressure sensitive bonding material between the fabric layers), it is possible for these skins to be formed by other processes for example pre-preg lay-up or overbraiding.
When the skin is formed from preforms 16, 18 as described in
In an alternative embodiment, as shown in
As in the embodiment shown in
As shown in
While the unnotched in-plane properties of chopped pre-preg compression moulding compounds may be inferior to those of conventional continuous fibre quasi-isotropic laminates as described above with reference to
Of course, the core 2 shown in
Although the fabric shown in
Although the present invention has been described in connection with the manufacture of a fan blade for a turbofan engine, it will be appreciated that other articles could be manufactured in the same manner. For example, blades for open-rotor and propeller structures (for example turbo prop, ducted fans and other such turbomachinery) could be manufactured by the processes described with reference to
The manufacturing process may also be suitable for static aerofoil structures and non-aerofoil components, such as blade containment structures for gas turbine engines or, indeed, any components where it is desirable to separate and protect the integrity of elements which provide axial or radial strength of the component from specific damage threats.
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0805604.6 | Mar 2008 | GB | national |
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