Patent Application
20120261854
This application claims priority of European Patent Office application No. 1162812.9 EP filed Apr. 18, 2011. All of the applications are incorporated by reference herein in their entirety.
The present invention is related to a method of manufacturing a bundle of roving yarns, to a bundle of roving yarns and to the use of such bundles of roving yarns. It is further related to a method for manufacturing a work piece, for example a wind turbine rotor blade, and to a work piece.
Fibre reinforced plastic composites are used in a variety of technical products such as cars, wind turbine blades, storage tanks etc. Most products of big size, such as wind turbine blades are manufactured by placing woven glass fabric, delivered on rolls, into one or more moulds. In the common resin injection process known as Vacuum Assisted Resin Transfer Moulding (VARTM), the moulds are closed, and vacuum is applied to the closed mould system. A resin, such as polyester, epoxy, vinyl ester or other, is then injected into the mould cavity, thus filling the space between the fibres in the laminates. In load bearing structures, a unidirectional glass fabric is often used. The glass fibre rovings in the fabric may be stitched together using yarns of polyester or similar material. In a long structure, such as a wind turbine blade, the use multiple layers of unidirectional fibre materials may be used. The weaving process is costly, and often doubles the price of the fibre material.
For achieving high strength, an increased number of unidirectional fibre layers are typically placed in the mould. This requires much labour force, and leads to high cost of the final product.
A method for manufacturing a bundle of roving yarns, a bundle of roving yarns methods for manufacturing a work piece and a work piece are described. The method of manufacturing a bundle of roving yarns includes assembling a number of roving yarns of longitudinal unidirectional fibres and an additional component in the bundle. The longitudinal unidirectional fibres may, for example, be reinforced fibres. For example at least 10 roving yarns are assembled in a bundle. It is also possible that more roving yarns are assembled in a bundle such as 10 to 100. Roving yarns contain thousands of single fibres.
The fibre yarn may be supplied directly into the mould, or a machinery in the vicinity of the mould may be employed for assembling the roving yarns into bundles, that may be placed in the mould in a simple and fast way. Hence, the manufacturing of bundles of roving yarns simplifies the placing of unidirectional fibre material in a mould, for example for manufacturing a wind turbine blade. The bundles may easily be placed in the mould, for example by a robot.
Providing and using longitudinal unidirectional fibres assembled in bundles of 10 to 100 or more roving yarns allows that they may replace woven fabrics, which are typically more expensive than the described bundles of roving yarns. The method of manufacturing bundles of roving yarns provides a cost reducing material which may be used for manufacturing work pieces.
At least one resin distribution means or a thermoplastic material may be placed as additional component in the bundle. Generally, the additional component may be placed in the centre of the bundle. The resin distribution means may for example be a flow enhancing means or a resin transport means, which accommodates the resin flow for the impregnation of the fibres in the surrounding rovings. The resin distribution means or flow enhancing means or a resin transport means may have a higher permeability for liquid resin flow than the longitudinal unidirectional fibres.
In the context of the method of manufacturing a bundle of roving yarns at least one porous yarn and/or at least one fibrous yarn and/or at least one permeable tube and/or at least one resin flow channel may be placed as resin distribution means in the bundle. The additional component may be placed in the middle or in the centre of the roving bundle. The centrally located additional component serves as a fast resin transport channel, in order to reach a fast impregnation of the roving fibres. By means of vacuum and capillary forces the resin may migrate from the centre to the surrounding rovings. As a porous yarn is placed in the centre, there are equal distances to the outmost fibres of the bundle. Instead of a porous yarn, a permeable tube of plastic, paper, or other material could be used.
The resin flow channel in the centre of the roving bundle may be constructed in a way that allows the resin to be drained from the channel by means of capillary forces from the roving area. Either the empty channel space may then be a porous structure, resembling a sandwich foam material, or the channel may be made collapsible. The collapse may for example be initiated by elevated temperatures, a higher vacuum level or other controlled physical changes.
Moreover, at least one thermoplastic fibre and/or at least one thermoplastic sheet may be placed in the bundle as thermoplastic material. The use of thermoplastic material provides the possibility of thermosetting the bundle, for example in the context of a process for manufacturing a work piece.
Generally, glass fibres, carbon fibres, basalt fibres, aramid fibres or natural fibres, for example natural fibres from wood or plants, may be used as roving yarns.
The bundle of roving yarns may be wrapped by a wrapping yarn. The wrapping yarn may be coiled around the bundle. The wrapping yarn may be an elastic yarn. Using an elastic yarn allows the bundle to change its round shape when placed in a mould, so that all bundles fit with no air voids between the bundles. Furthermore, the bundles may be stored on a bobbin and than used later, or the bundles may be transferred directly from a winding machine to a mould. Alternatively, yarns that are not elastic may also be foreseen.
The used roving yarn and/or the used wrapping yarn may comprise randomly oriented fibres or transverse fibres. The randomly oriented fibres or transverse fibres may for example be milled fibres, short fibres or long fibres. They may be placed on the outside of the bundle or in the outmost layer of the roving or may be included in the bundle or attached to the bundle. The use of randomly oriented fibres or longitudinal fibres enhances the shear strength of a laminate to be created via the bundles. Another purpose of these randomly oriented fibres is to improve the crack resistance in these unidirectional fibre laminates. Randomly oriented short or long fibres may also be integrated in or placed on the resin yarn that holds the roving bundle together.
The bundle of roving yarn comprises a number of roving yarns of longitudinal unidirectional fibres and an additional component. Generally, the bundle of roving yarn may be manufactured by the previously described method. For example, the bundle of roving yarn may comprise at least one resin distribution means or a thermoplastic material as the additional component. Moreover, it may comprise at least one porous yarn and/or fibrous yarn and/or permeable tube and/or resin flow channel as resin distribution means. Furthermore, it may comprise at least one thermoplastic fibre and/or thermoplastic sheet as thermoplastic material.
The bundle of roving yarn may comprises at least one wrapping yarn, which may be coiled around a bundle.
Furthermore, the roving yarn may comprise randomly oriented fibres or transverse fibres. The wrapping yarn may also comprise randomly oriented fibres or transverse fibres.
Regarding further properties and advantages of the bundles of roving yarn it is referred to the previously described method.
The method for manufacturing a work piece by vacuum assisted resin transfer moulding comprises the steps of placing at least one bundle of roving yarn as previously described in a mould of a closed mould system, applying vacuum to the closed mould system and injecting resin into a mould cavity. The work piece may, for example, be a wind turbine rotor blade. The bundles of roving yarn may be transferred directly from a winding machine into the mould. Generally, the bundles may be placed in the mould by means of a robot. After placing the bundles in the mould, the at least one bundle of roving yarn or the number of roving yarn bundles may be compacted. This may be performed by means of vacuum.
An alternative method for manufacturing a work piece comprises the steps of placing at least one previously described bundle of roving yarn which comprises thermoplastic material in a mould and thermosetting the thermoplastic material. The thermosetting is performed by consolidating the material by initial heating and melting the thermoplastic material, followed by cooling the material In order to melt the thermoplastic material, the thermoplastic fibres mixed with reinforcement fibres may be heated, to for example 200° C. Then, the liquid thermoplastic material may flow in between the reinforced fibres, for example under vacuum. When cooled and solidified, the work piece is finished. This method provides a cheap and easily performable method for manufacturing a longitudinal unidirectional fibre material.
The work piece is manufactured by one of the previously described methods. The work piece may be manufactured at comparably low costs since expensive woven fibre material may be replaced by bundles of roving yarn.
A fast production rate may be obtained with bundles instead of single roving laid in the mould. Moreover, an improved linear fibre orientation is obtained as no stitching yarns are creating waviness or resin rich pockets. Furthermore, a faster impregnation of the fibres may be done, due to a proper combination of vacuum channels and capillary forces. Laminates with extremely high stiffness (E-Modulus) may be fabricated.
Further features, properties and advantages will become clear from the following description of embodiments in conduction with the companying drawings. The described features may be in any combination with each other.
Elements of the different figures and embodiment which correspond to each other are designated with the same reference numeral.
A first embodiment will now be described with reference to
The roving yarn 1 may comprise glass fibre, carbon fibre, basalt fibre, aramid fibre or nature fibre, for example from wood or plants. The roving yarn 1 comprises longitudinal unidirectional reinforced fibres. The bundle 5 may comprises at least 10 roving yarns 1. However, more roving yarns 1 such as 10 to 100 roving yarns 1 may be used. The wrapping yarn 3 may be an elastic yarn. This allows the bundle 5 to change its round shape when placed in a mold, so that all bundles 5 fit with no air voids between the bundles. Yarns 3 that are not elastic may although be foreseen.
The centrally placed flow yarn 2 may for example be a porous or fibrous yarn. It may be placed in a middle of the roving bundle 5. The central yarn serves as a fast resin transport channel, in order to reach a fast impregnation of the roving fibres 1. By means of vacuum and capillary forces the resin will migrate from the centre to the surrounding roving. As the porous yarn is placed in the centre, there are equal distances to the outmost fibres 1 of the bundles 5. Instead of a porous yarn, a permeable tube of plastic, paper, or other material may be used.
A further variant of the wrapped roving bundle will now be described with reference to
The wrapped roving bundle 15 comprises unidirectional roving 1, a central resin flow channel 2 and a number of transverse fibres 9. For example, only on the outside of the bundle 15 or in the outmost layers of roving 1 the transverse or randomly oriented fibres 9 are present. The transverse or randomly oriented fibres 9 may, for example, milled fibres, short fibres or long fibres. They may be included or attached to the bundle 15, in order to enhance the shear strength of the laminate to be created. Another purpose of these randomly oriented fibres 9 may be to improve crack resistance in these unidirectional fibre laminates.
A variant which may be applied to all embodiments will now be described with reference to
The bundle 25 may have the properties of the bundle 5, which was previously described in
A further embodiment will now be describes with reference to
The method for manufacturing a bundle of roving yarns may also be used for a mixture of reinforced fibres 1 and thermoplastic fibres 36, thermoplastic sheets, or thermoplastic materials in general as, for example, shown in
Additionally to thermosetting the material, liquid resin may be infused into the fibre filled mold cavity of a closed mould system.
All previously described bundles of roving 5, 15, 25, 35, 45 and 55 may be used for manufacturing a work piece, for example a wind turbine rotor blade, by means of Vacuum Assisted Resin Transfer Moulding (VARTM). In this context fibre material, for example a number of unidirectional fibre layers and/or a number of bundles of roving 5, 15, 25, 35, 45 and 55, are placed in a mould shell. A mould core may be placed onto the fibre material. Then the mould may be closed and vacuum may be applied to the closed mould cavity. Then, resin, such as polyester resin, epoxy resin, vinyl ester or other resin, may be injected into the mould cavity, filing the space between the fibres in the laminate.
Alternatively or additionally, thermoplastic material may be mixed with the fibre reinforced material or may be placed between fibre layers. In this case, the thermoplastic material may be heated and melted. Then, the mixture between thermoplastic fibres and reinforced fibre material is consolidated by initial heating and melting the thermoplastic material, followed by the solidification by cooling the material. Then, the mixture between thermoplastic fibres and reinforcement fibre material is forming a rigid composite material.
| Number | Date | Country | Kind |
|---|---|---|---|
| EP11162812 | Apr 2011 | EP | regional |
