BLADE COMPONENT

Abstract

A blade component has a longitudinal axis and extends between a root end and a tip end. The component comprises a composite laminate structure, the laminate structure comprising a plurality of plies of fibres in a matrix, wherein all the plies are arranged such that the fibres in respective plies are oriented symmetrically relative to the component axis at respective layup angles, the layup angles being in the range of 19 to 25 and 19 to 25 respectively relative to the component axis.

Claims

1. A blade component having a longitudinal axis and extending between a root end and a tip end, the component comprising a composite laminate structure, the laminate structure comprising a plurality of plies of fibres in a matrix, wherein all the plies are arranged such that the fibres in respective plies are oriented symmetrically relative to the component axis at respective layup angles, the layup angles being in the range of 19 to 25 and 19 to 25 respectively relative to the component axis.

2. A blade component as claimed in claim 1, wherein the plurality of plies comprises one or more first plies each comprising fibres aligned at a layup angle relative to the component axis and one or more second plies each comprising fibres aligned at a layup angle of relative to the component axis.

3. A blade component as claimed in claim 2 wherein the plurality of plies further comprises one or more third plies comprising fibres aligned at a layup angle of relative to the component axis and one or more fourth plies comprising fibres aligned at a layup angle of relative to the component axis and wherein is different from , wherein and are both in the range of 19 to 25 and 19 to 25

4. A blade component as claimed in claim 1, wherein alternating plies are arranged symmetrically relative to the component axis.

5. A blade component as claimed in claim 1, wherein the layup angle is in the range 20 to 23.

6. A method of manufacturing a blade component having a longitudinal axis and extending between a root end and a tip end, the method comprising: laying a plurality of plies of fibres on a core, all the plies being arranged such that the fibres in the plies are oriented symmetrically relative to the component axis at respective layup angles, the layup angles being in the range of 19 to 25 and 19 to 25 respectively relative to the component axis; and curing the component with the plies to form a laminated structure on the core.

7. A method of manufacturing a blade component as claimed in claim 6, wherein the plurality of plies comprises one or more first plies each comprising fibres aligned at a layup angle a relative to the component axis and one or more second plies each comprising fibres aligned at a layup angle of relative to the component axis.

8. A method of manufacturing a blade component as claimed in claim 7, wherein the plurality of plies further comprises one or more third plies comprising fibres aligned at a layup angle of relative to the component axis and one or more fourth plies comprising fibres aligned at a layup angle of relative to the component axis.

9. A method of manufacturing a blade component as claimed in claim 6, wherein alternating plies are oriented symmetrically relative to the component axis.

10. A method of manufacturing a blade component as claimed in claim 6, wherein the layup angle is in the range 20 to 23

11. A blade component or method as claimed in claim 6, wherein the plies are formed from sheets or tapes of fibre material.

12. A method as claimed in claim 11, wherein the plies are pre-impregnated with a resin or wherein a resin is applied to the plies for curing.

13. A method of manufacturing a blade component as claimed in claim 6, wherein the blade component is a propeller blade component or a fan blade component.

14. A method of manufacturing a blade component as claimed in claim 6, wherein the blade component is a blade spar.

15. A blade component as claimed in claim 1, wherein the blade component is a propeller blade component or a fan blade component.

16. A blade component as claimed in claim 1, wherein the blade component is a blade spar.

17. A blade component as claimed in claim 14, wherein the laminate structure is provided on a core of the spar.

Description

BRIEF DESCRIPTION OF DRAWINGS

[0020] Some embodiments of the disclosure will now be described by way of example only and with reference to the accompanying drawings in which:

[0021] FIG. 1 shows a lay-up of fibre plies for a propeller blade component according to the prior art;

[0022] FIG. 2 shows a lay-up of fibre plies for a propeller blade component according to this disclosure;

[0023] FIG. 3 shows a propeller blade component and plies oriented at different angles relative to the component axis; and

[0024] FIG. 4 shows a propeller blade component and composite tapes oriented at different angles relative to the component axis.

DETAILED DESCRIPTION

[0025] With reference to FIGS. 2 to 4, FIG. 2 shows an exemplary laminate structure 20 for a propeller blade component such as a structural spar 30 as illustrated in FIGS. 3 and 4.

[0026] With reference to FIG. 3, the structural spar 30 includes a root 32 and a tip 34 and a body 33 extending from the root 32 to the tip 34. The body 33 extends along an axis 100 defining 0 orientation with respect to the ply lay-up. The axis may be in the perpendicular plane of the propeller blade rotation axis or, in the case of curved blades, may have a local blade axis at any given point defined perpendicular to the local blade section. The root 32 comprises or is attached to a retention element 35 which retains the blade in a hub in use. The blade is usually rotatable about the axis 100, for example to allow the blade to be feathered.

[0027] Returning to FIG. 2, the laminate structure 20 includes a first ply 22 and a second ply 24. The first ply 22 comprises a plurality of fibres shown schematically at 26. The fibres 26 may, for example, comprise carbon fibres, glass fibres, aramid fibres or the like. The fibres 26 of the first ply 22 are aligned along a single direction shown by the arrow 23. That is, a majority of or substantially all the fibres 26 are aligned in the same direction throughout the first ply 22. For example, at least 90% of the fibres are aligned in the same direction and up to 10% of the fibres might be arranged at about 90 to the remaining fibres. The first ply 22 is oriented relative to a central axis 21 such that a layup angle + is defined between the central axis 21 and the direction 23 of the fibres 26. The axis 21 is aligned with a longitudinal axis of the component, for example the axis 100 of the spar 30 as illustrated in FIGS. 3 and 4.

[0028] The second ply 24 comprised a plurality of fibres shown schematically at 28. The fibres 28 may also, for example, comprise carbon fibres, glass fibres, aramid fibres. In the embodiment, the fibres 28 of the second ply 24 are substantially the same as the fibres 26 of the first ply 22. The fibres 28 of the second ply 24 are aligned along a single direction shown by the arrow 25. That is a majority of or substantially all the fibres 28 are aligned in the same direction throughout the second ply 24. The second ply 24 is oriented relative to the central axis 21 such that a layup angle (i.e. the opposite of angle ) is defined between the central axis 21 and the direction 25 of the fibres 28.

[0029] Thus the first ply 22 and the second ply 24 are arranged symmetrically relative to the central axis 21 of the structure.

[0030] The plies may be applied to a core to form the laminated structure. In the case of a spar as illustrated in FIG. 3, the pliers 22, 24 may be applied to a lightweight core, for example a foam core. The first and second pliers 22, 24 may then be braided on to or otherwise attached to the core. In embodiments, the plies 22, 24 might include dry fibres, such as carbon fibres, braided onto the outer surface of the core. Resin may be subsequently injected into the pliers 22, 24. Alternatively, the pliers 22, 24 may be formed from a pre-impregnated fabric material, such as a resin impregnated carbon fibre fabric.

[0031] As shown in FIGS. 3 and 4, the pliers 22, 24 might be attached to the core in the form of sheets 38 or tapes 138. The pliers 22, 24 may be attached to the core such that they surround the entire circumference of the core.

[0032] In embodiments, the laminate structure 20 has a uniform thickness for a given cross section along the spar 30. The first and second pliers 22, 24 may also have the same thickness. It will be appreciated, however, that the thickness of the laminate structure 20 might be varied achieved by applying plies of uniform thickness only in specific areas on the core, for example.

[0033] After resin injection or application of pre-impregnated material, the spar 30 is heated or cured to set the laminate structure 20.

[0034] Although the laminate structure 20 illustrated includes two pliers 22, 24, it is envisaged that any number of plies may be used. For example, in a propeller blade spar the laminate structure 20 may include between 15 and 30 plies. In another example, a laminate structure for use in a fan blade may include up to and in excess of 80 plies.

[0035] The plies are arranged such that the fibres of all the plies are oriented at an angle of between 19 and 25 from the axis of the spar 30 in either direction. In embodiments, the fibres may be oriented at an angle of 20, 22 or 23 from the central axis 21. None of the plies is arranged such that the fibres are aligned with the axis 21 (i.e. at 0).

[0036] In particular embodiments, there may only be first and second plies 22, 24 having fibres 26, 28 arranged at the same angle relative to the central axis at respective layup angles of , to the central axis 21. In embodiments, there may be multiple first and second plies with such orientations.

[0037] In some multiple ply arrangements, the orientation of the plies relative to the central axis 21 may alternate (for example, ). In other multiple ply arrangements, the order may not alternate between adjacent plies (for example )

[0038] Embodiments having pliers 22, 24 that are oriented at just one angle around the axis 21 may be easier to form. In particular it may be easier to maintain the symmetry of the lay-up throughout the pliers 22, 24, particularly when compared to structures containing 0 fibres.

[0039] In yet further embodiments however, the laminate structure 20 might include one or more first pliers 22 oriented at an angle , one or more second pliers 24 oriented at , one or more third plies (not shown) oriented at an angle and one or more fourth plies (not shown) oriented at , being different from .

[0040] Having the fibres 26, 28 of all the pliers 22, 24 oriented at an angle of between 19 and 25 from the axis 21 may improve the inter-laminar shear strength of the laminate structure 20 as the maximum angle between two fibres of the structure is less than 90.

[0041] Moreover, the curing thermal stressing between plies may be reduced or even eliminated in the case of interlacing fibres.

[0042] A further advantage of embodiments having the plies oriented at angles between 19 and 25 is that cutting of pliers 22, 24 during application to a core, will result in lower scrap material when compares to plies that are oriented at 45, for example. This is best shown in FIG. 3 in which a first ply 38 is shown oriented at 19-25 from the blade axis and a second ply 36, outside the scope of the disclosure, is oriented at 45 from the blade axis. As can be seen from the lay-up of both plies, the first ply 38 requires less cutting of the ply material and thus less waste may be produced.

[0043] An embodiments where the plies are formed from tapes, is illustrated in FIG. 4. As shown, a first tape 136 is arranged at 45 relative to the axis 100 and a second tape 138 is arranged at between 19 and 25 relative to the axis 100. The tapes may be automatically laid on a core surface using a tape-laying apparatus. By having the angle between the tape 138 and the central axis 100 reduced, for example when the fibres of the tape are aligned along the length of the tape, fibre deposit speed can be increased and the steering of the apparatus across the surface of the core may be simplified and reduced. Moreover, it will be seen that the second tape 136 extends along a greater length of the core structure and therefore fewer tapes and less steering of the deposition apparatus may be required than in laying down tapes 136 at a greater angle, outside the scope of this disclosure.

[0044] In embodiments where the plies are braided, only one braiding machine may be needed to lay the plies, particularly in embodiments where the fibres are aligned symmetrically about the spar axis 100.

[0045] From the above, it will be recognised that there is proposed a laminate structure wherein plies have fibres oriented at opposite angles relative to a central axis, the angle being in the range of 19 to 25. In particular embodiments, the fibres within the plies are oriented at a single angle either side of the axis of the component to form a symmetrical laminate structure. The mechanical characteristics of such laminate structures have to been found to be comparable to the known 045 lay-up and further have considerable performance and manufacturing advantages as described above. Table 1 shows a number of mechanical characteristics of components having laminate structures in accordance with the disclosure compared to the characteristics of components having the conventional 045 lay-up. The characteristics of the components according to this disclosure were found to be comparable within acceptable limits for a variety of applications.

TABLE-US-00001 TABLE 1 [0, +/45] [0, +/45] [0, +/45] [0, +/45] Lamination Type (50%/50%) [+/23] (50%/50%) [+/22] (60%/40%) [+/20] (50%/50%) [+/20] Type of Fibre Carbon HR Carbon HR Carbon IM Carbon IM Carbon HR Carbon HR Carbon IM Carbon IM Volume of Fibre 60% 60% 60% 60% 60% 60% 60% 60% 1. Rigidity E1 (blade axis) 83 80 96 94 97 95 112 107 E2 (chord direction) 24 10 26 9.4 22 10 23 10 G12 (torsional stiffness) 21 22 24 24 18 19 21 21 Poisson's Ratio 0.7 1.5 0.75 1.7 0.68 1.4 0.72 1.6 2. Strength (Static Force) Ultimate blade axis (MPa) 680 490 1473 950 820 630 1770 1140 First Ply Failure blade axis (Mpa) 470 490 770 950 550 630 895 1140 Ultimate chord direction (Mpa) 290 47 379 47 240 46 340 46 First Ply Failure chord direction 110 47 131 47 100 46 114 46 (Mpa) 3. Coefficient of Expansion Blade Axis 1.7 3.5 0.23 2.15 0.7 2.9 0.25 1.84 Chord Axis 23.5 22.7 5.23 16.4 9.8 24.2 6.3 17.1

[0046] While the disclosure has been particularly directed to a structural spar of a propeller blade, it may be used for other blade components, for example an external skin for a propeller blade. The principles of the invention may also be applied to fan blades, particularly those manufactures by Automatic Fibre Placement (AFP) process.