A pre-form and a method of preparing pre-forms are provided. The pre-forms comprise a resin and at least three layers of oriented fiber tows. The pre-forms comprise fiber tows instead of the traditional prepregs to enhance rearranging of resin and/or fibers during subsequent processing as well as pr
A pre-form and a method of preparing pre-forms are provided. The pre-forms comprise a resin and at least three layers of oriented fiber tows. The pre-forms comprise fiber tows instead of the traditional prepregs to enhance rearranging of resin and/or fibers during subsequent processing as well as provide greater freedom, a price reduction and/or a reduction of waste. The pre-forms may be formed three-dimensionally to enhance coupling to further pre-forms or other structures and/or to enhance shaping of the pre-form to a final three-dimensional shape. The method of preparation of pre-forms involves providing an adhesive between layers of fibers and providing a resin in contact with at least one of the layers of fibers. The resin is preferably provided in a non-continuous layer to allow for removal of gas at least partially in a direction orthogonal to the layers of resin. Advantageously, during manufacturing, the fibers are placed with an exact start and ending location, thereby avoiding waste. The pre-forms are suitable for preparation of composite structures like for example spars for wind turbine blades.
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1. A pre-form, comprising: a resin, an adhesive, and at least four layers of oriented fibre tows, said at least four layers of fibre tows in the pre-form comprising first type fibres and second type fibres provided in separate layers, such that second type fibre layers containing said second type fi
1. A pre-form, comprising: a resin, an adhesive, and at least four layers of oriented fibre tows, said at least four layers of fibre tows in the pre-form comprising first type fibres and second type fibres provided in separate layers, such that second type fibre layers containing said second type fibres are interleaved between first type fibre layers containing said first type fibres so as to define an interleaved region proximate one longitudinal end of the pre-form, said second type fibre layers are separated from one another by said first type fibre layers in the interleaved region, wherein said first type fibre layers include first terminal ends located in the interleaved region and second terminal ends at an opposite longitudinal end of the pre-form from the interleaved region,said adhesive is located between adjacent layers of oriented fibre tows to at least partially immobilize said fibres,a part of the pre-form is formed three-dimensionally so that said part of the pre-form is tapered along a tapered connection surface defined in the interleaved region by the first terminal ends of said first type fibre layers,wherein said second type fibre layers include first terminal ends located on one side of said tapered connection surface and outside the interleaved region, and said second type fibre layers include second terminal ends located in the interleaved region and on an opposite side of said tapered connection surface from the first terminal ends of the second type fibre layers, andwherein said second type fibres do not contain the same fibre material as said first type fibres, and the pre-form is enhanced for coupling of the pre-form at said tapered connection surface to a separate composite member comprising said second type fibres and a resin by having the second type fibre layers extend from the interleaved region through and beyond the tapered connection surface such that the first terminal ends of said second type fibre layers are positioned to extend toward the separate composite member comprising said second type fibres when the separate composite member is coupled to the pre-form at the tapered connection surface. 2. A pre-form according to claim 1, wherein said first type fibres comprise carbon fibres and said second type fibres are selected from the group of glass fibres, aramid-fibres, synthetic fibres, bio fibres, mineral fibres, metal fibres or boron fibres. 3. The pre-form of claim 1, wherein the resin comprises mainly a thermosetting resin. 4. The pre-form of claim 1, wherein said first type fibres comprise carbon fibres. 5. A pre-form according to claim 1, wherein said second type fibres are selected from the group consisting of carbon fibres, glass fibres, aramide fibres, synthetic fibres, bio fibres, mineral fibres, metal fibres and boron fibres. 6. A pre-form according to claim 1, wherein said first-type fibres and said second type fibres are continuous fibres. 7. A pre-from according to claim 1, wherein the resin is mainly an epoxy-based resin or a polyester-based resin. 8. A pre-form according to claim 7, wherein the resin comprises two resin systems. 9. A pre-form according to claim 1, wherein the pre-form is substantially rectangular in shape as observed in plan view from above. 10. A pre-form according to claim 9, wherein the rectangular shape of the pre-form defines a distance between parallel sides of the rectangular shape that is between 3 times and 6 times the length of any of the parallel sides. 11. A pre-form according to claim 1, wherein the pre-form is substantially quadrangular or triangular in shape in plan view as observed from above. 12. A pre-form according to claim 1, wherein the pre-form is substantially trapezoidal in shape when in plan view as viewed from above. 13. The pre-form of claim 12, wherein the trapezoidal shape of the pre-form has at least two interior angles (α, β) which are substantially the same. 14. A pre-form according to claim 1, wherein the fibres of each layer are oriented primarily unidirectionally, respectively. 15. A pre-form according to claim 1, wherein the fibres are oriented substantially orthogonally to an edge of the pre-form. 16. A pre-form according to claim 1, wherein the fibres are oriented substantially parallel to an edge of the pre-form. 17. A pre-form according to claim 1, wherein orientation of fibres is substantially the same in all layers. 18. The pre-form according to claim 1, wherein in the interleaved region, a relative concentration of second type fibres increases towards the tapered connection surface and a relative concentration of first type fibres decreases towards the tapered connection surface, thereby gradually blending material properties of the pre-form from properties of said first type fibres to properties of said second type fibres at a location adjacent to the separate composite member when the separate composite member is coupled to the pre-form at the tapered connection surface. 19. A composite structure configured for use in a wind turbine, comprising: a composite member including second type fibres and a resin; anda pre-form coupled to said composite member at a joint, said pre-form comprising: a resin, an adhesive, and at least four layers of oriented fibre tows, said at least four layers of fibre tows in said pre-form comprising first type fibres and second type fibres provided in separate layers, such that second type fibre layers containing said second type fibres are interleaved between first type fibre layers containing said first type fibres so as to define an interleaved region proximate one longitudinal end of said pre-form, said second type fibre layers are separated from one another by said first type fibre layers in the interleaved region, wherein said first type fibre layers include first terminal ends located in the interleaved region and second terminal ends at an opposite longitudinal end of said pre-form from the interleaved region,wherein said adhesive is located between adjacent layers of oriented fibre tows to at least partially immobilize said fibres,wherein a part of said pre-form is formed three-dimensionally so that said part of said pre-form is tapered along a tapered connection surface defined in the interleaved region by the first terminal ends of said first type fibre layers,wherein said second type fibre layers include first terminal ends located on one side of said tapered connection surface and outside the interleaved region, and said second type fibre layers include second terminal ends located in the interleaved region and on an opposite side of said tapered connection surface from the first terminal ends of the second type fibre layers, andwherein said second type fibres do not contain the same fibre material as said first type fibres, and said pre-form is enhanced for the coupling of said pre-form at said tapered connection surface to said composite member by having the second type fibre layers extend from the interleaved region through and beyond the tapered connection surface,the first terminal ends of said second type fibre layers extend into contact with said composite member when said composite member is coupled to said pre-form at the joint, which is located at tapered connection surface.
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이 특허에 인용된 특허 (14)
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