part of wind turbine blade manufactured in two stages

专利摘要:
The present invention relates to a method for manufacturing a part of a wind turbine blade (10). The method comprises the steps of: laminating a primary fiber material into a mold; infusing said primary fiber material with a primary resin; substantially curing the first primary resin in said primary fiber material to form a cured paddle element; laminating a secondary fiber material over at least part of said cured paddle element (60, 160); infusing said secondary fiber material with a secondary resin other than said primary resin, wherein said secondary resin has a higher strength level than said primary resin; and curing said secondary resin in said secondary fiber material to form an integrated reinforced section (70, 170) on said cured paddle element (60, 160).
公开号:BR112016017533B1
申请号:R112016017533-6
申请日:2015-01-30
公开日:2021-07-06
发明作者:Rasmus C Østergaard；Lars Nielsen；Klavs JESPERSEN
申请人:Lm Wp Patent Holding A/S；
IPC主号:

专利说明:

FIELD OF THE INVENTION
[0001] The present invention relates to a method for manufacturing a wind turbine blade and intermediate products of a wind turbine blade. The present invention further relates to a wind turbine blade and intermediate products of the wind turbine blade. BACKGROUND OF THE INVENTION
[0002] Wind turbine blades are generally manufactured according to one of two structural designs, namely a design in which a thin aerodynamic housing is glued to a spar beam or a design in which spar tables, also called main laminates , are integrated into the aerodynamic housing.
[0003] In the first design, the spar beam constitutes the load bearing structure of the blade. The spar beam as well as the aerodynamic housing or parts thereof are manufactured separately. The aerodynamic housing is also manufactured in the form of two housing parts, typically in the form of a pressure side housing part and a suction side housing part. The two frame parts are glued or otherwise connected to the spar beam and additionally glued together along a leading edge and trailing edge of the frame parts. This design has the advantage that the critical load-bearing structure can be manufactured separately and therefore easier to control. In addition, this design allows for several different fabrication methods to produce the beam, such as shaping and filament winding.
[0004] In the second design, the stringer tables or main laminates are integrated into the housing and molded together with the aerodynamic housing. Main laminates generally comprise a high number of fiber layers compared to the rest of the blade and may form a local thickening in the wind turbine housing, at least with respect to the various fiber layers. As such, the laminate can form a fiber insert in the blade. In this design, the main laminates constitute the load-bearing structure. Blade shells are typically designed with a first main laminate, integrated with the pressure side shell part, and a second main laminate, integrated with the suction side shell part. The first main laminate and the second main laminate are generally connected by means of one or more shear meshes, which, for example, can be C-shaped or I-shaped. additionally, along at least part of the longitudinal extent, they comprise an additional first main laminate in the pressure side housing and a second main laminate in the suction side housing. These additional main laminates can also be connected via one or more shear nets. This design has the advantage of allowing more ease to control the aerodynamic shape of the blade by molding the blade housing part.
[0005] Vacuum infusion or VARTM (Vacuum Assisted Resin Transfer Molding) is a method typically used to fabricate composite structures such as a fiber reinforced matrix material.
[0006] During the process of filling the mold, a vacuum is generated, in this context understood as an underpressure or negative pressure, through vacuum outlets in the mold cavity, which causes the liquid polymer to be forced into the cavity of mold through the inlet channels to fill said mold cavity. Leaving the inlet channels, polymer spreads out in all directions in the mold cavity thanks to negative pressure as a flow front moves towards the vacuum channels. Therefore, it is important to optimally position the inlet channels and vacuum channels to obtain complete filling of the mold cavity. Ensuring full distribution of the polymer throughout the mold cavity, however, is often difficult and therefore so-called dry spots, ie areas with fiber material not sufficiently impregnated with resin, often occur. As such, dry spots are areas where the fiber material is not impregnated and where there may be air pockets which are difficult or impossible to remove by controlling the vacuum pressure and possible overpressure on the inlet side. In vacuum infusion techniques using a rigid mold part and a resilient mold part in the form of a vacuum bag, dry spots can be repaired after the process of filling the mold by punching the bag in place and extracting the air , for example, by means of a syringe needle. The liquid polymer can optionally be injected into the respective location, and this can be done, for example, also by means of a syringe needle. This is a time-consuming and tiring process. In the case of large mold parts, the professional team needs to step on the vacuum bag. This is not desirable, especially when the polymer has not yet hardened, as this can result in deformations in the inserted fiber material and therefore local weakening of the structure, which can cause, for example, warping effects.
[0007] In most cases, the polymer or resin applied includes polyester, vinylester or epoxy, but it can also be PUR or pDCPD, and the fiber reinforcement is most often based on glass fibers or carbon fibers. Epoxies are advantageous with respect to various properties such as shrinkage during cure (which in some circumstances can lead to less wrinkles in the laminate), electrical properties, mechanical strength and fatigue strength. Polyester and vinylesters have the advantage of providing better gelcoat binding properties.
[0008] Thus, a gelcoat can be applied to the outer surface of the carcass during the manufacture of this by applying the gelcoat to the mold before disposing the fiber reinforcement material in it. In this way, various post-molding operations, such as painting the paddle, can be avoided. Furthermore, polyesters and vinylesters are more economical than epoxies. Therefore, the manufacturing process can be simplified and costs reduced.
[0009] Generally, composite structures comprise a core material coated with a fiber reinforced material, such as one or more layers of fiber reinforced polymers. The core material can be used as a spacer between said layers to form a sandwich structure and is typically made of a rigid, lightweight material to reduce the weight of the composite structure. In order to ensure an efficient distribution of the liquid resin during the impregnation process, the core material can be provided with a resin distribution network, for example, forming channels or grooves in the surface of the core material.
[0010] As, for example, wind turbine blades have gotten larger and larger over time and can now reach more than 70 meters in length, the impregnation time associated with the manufacture of these blades has increased, since more fiber material needs to be impregnated with polymer. Furthermore, the infusion process has become more complicated, since the impregnation of large carcass members, such as paddles, requires control of the flow fronts to avoid dry spots, said control may include, for example, a control relative to the timing of the inlet channels and vacuum channels. This increases the time required to insert or inject polymer. As a result, the polymer must remain liquid longer, which generally also results in an increase in cure time.
[0011] Resin transfer molding (RTM) is a manufacturing method similar to VARTM. In RTM, the liquid resin is not inserted into the mold cavity by means of a vacuum generated in the mold cavity. Instead, the liquid resin is forced into the mold cavity by overpressure on the inlet side.
[0012] Prepreg molding is a method in which reinforcing fibers are pre-impregnated with a pre-catalyzed resin. The resin is typically solid or nearly solid at room temperature. Prepregs are laid by hand or machine on a mold surface, vacuum bagged, and then heated to a temperature at which the resin can reflow and ultimately cure. This method has the main advantage that the resin content in the fiber material is precisely defined in advance. Prepregs are simple and clean to work with, and they also enable automation and save labor. The disadvantage of prepregs is that the material cost is higher compared to non-impregnated fibers. In addition, the core material needs to be made of a material that is able to withstand the process temperatures necessary to cause the resin to flow again. Prepreg molding can be used in either an RTM or a VARTM process.
[0013] Furthermore, it is possible to produce one-piece hollow moldings using external mold parts and a mold core. Such a method is described, for example, in EP 1 310 351 and can be readily combined with RTM, VARTM and prepreg molding.
[0014] Furthermore, it is common to manufacture blades with two or more types of different fiber material. WO 2003/078832 discloses a fiber reinforced polymer wind turbine blade which includes a first type of fibers such as glass fibers of a first stiffness and a second type of fibers such as carbon fibers of a different rigidity. In a transition region between the two types of fibers, the quantitative ratio of the two types of fibers varies continuously in the longitudinal direction of the blade. In a preferred embodiment described, the laminate comprises several layers, and the boundaries between the layers with the first type of fibers and the layers with the second type of fibers are mutually shifted in the longitudinal direction of the blade so as to obtain a gradual tapered transition. However, it turned out that this transition is not mechanically strong. To compensate for stress concentrations by using reinforcing fibers with diverging elastic moduli in the composites, it is possible to form a local thickening in the transition region between the two different fibers and thus limit the risk of failure due to stress concentrations. A disadvantage of this solution, however, is the greater weight due to the greater use of fibers, eg glass fibers, in the transition region between glass fibers and carbon fibers.
[0015] Document US 2012/0009070 discloses a method for preparing a housing member for a wind turbine blade using sheet material reinforced with precured fibers. In one embodiment, a stepwise brewing process is described in which individual layers are brewed in sequence.
[0016] WO 2012/149939 discloses a method for preparing a hybrid composite laminate with layers of fiber reinforced material of different resin viscosities, wherein the first layers are pre-impregnated with a first resin of a first viscosity and the second layers are impregnated with a second resin of a second viscosity.
[0017] WO 2013/010979 discloses a wind turbine blade with different types of fibers and a beveled transition between the different types of fiber.
[0018] The document US 2012/0082558 discloses a modular wind turbine blade, the parts of which connect together along connecting lines. In one embodiment, the connecting lines are in the form of double beveled joints.
[0019] Furthermore, it is known, based on WO 2013/113817, a method for manufacturing a blade carcass part in a mold system and transferring the cured shovel carcass parts to a post-molding station comprising bases for loading the cured casing parts for further treatment, such as gluing the casing parts together to form the aerodynamic casing of a finished wind turbine blade. The method ensures that the molding cycle time is kept as short as possible, allowing for maximum efficiency in mold use. The method is particularly suitable for blades that are 40 to 50 meters in length, as the laminating process for blades of that length generally takes a third of the total production time, which comprises lamination, infusion and post-molding assembly, in addition to other post-molding operations. This enables a continuous manufacturing process, in which the mold system and post-molding system are used all the time. However, in the case of longer blades, such as blades 60 to 80 meters in length or even longer, the lamination time takes a much higher percentage of the total production time, causing the post-molding system to have a lot of downtime. .
[0020] One of the objectives of the present invention is to partially obtain a new model of blade and intermediate products of this model, as well as a new method to manufacture said wind turbine blades and intermediate products, which overcome or mitigate at least one of the disadvantages prior art or that offer a useful alternative. SUMMARY OF THE INVENTION
[0021] According to one aspect, the present invention proposes a wind turbine blade with a longitudinal direction between a root end and a tip end, wherein the wind turbine blade comprises at least one wind turbine blade component made of fibrous composite material and containing a first type of reinforcing fibers with a first elastic modulus and a second type of reinforcing fibers with a second elastic modulus, wherein the wind turbine blade component comprises a thickness between a first surface and a second surface, wherein the ratio between the first type of reinforcement fibers and the second type of reinforcement fibers gradually changes in a first direction of the wind turbine blade such that the elastic modulus gradually changes in said first direction, in that said gradual change in the first direction is obtained by: a section of first thickness, where the reinforcing fibers of the first type, along a first boundary and In common, they taper towards the first surface of the wind turbine blade component in the first direction and the reinforcement fibers of the second type taper towards the second surface of the wind turbine blade component in an opposite direction to the first, and a section of second thickness, where the reinforcing fibers of the first type, along a second common boundary, taper towards the second surface of the wind turbine component in the first direction and the reinforcing fibers of the second type taper towards the first surface of the turbine component wind in an opposite direction to the first, in which the first type of fibers and the second type of fibers are embedded in a common polymer matrix.
[0022] Therefore, it is clear that the gradual transition is made possible by a combined double tapered thickness section, which has reinforcement fibers of the first type arranged between reinforcement fibers of the second type or vice versa. While this increases the complexity of the fiber lamination procedure, this embodiment offers a more rigid transition of the wind turbine component between the two fiber types, and in addition, the transition may be shorter than in the technique's wind turbine components. front with a simple tapered section. Furthermore, of course double taper is obtained during lamination and the reinforcing material is impregnated with a polymeric resin and then cured or stiffened so that the two types of reinforcing fibers are embedded in a common polymeric matrix. This has the advantage of lowering stress concentrations and, in particular, the energy release rate at the common boundary between the two types of fiber, particularly compared to parts joined together in a tie line.
[0023] Advantageously, the first common limit and the second common limit converge in the first direction or in a direction opposite to the first, more advantageously in the opposite direction to the first direction.
[0024] Preferably, the first direction is in the longitudinal direction of the blade. Therefore, it is noticed that the gradual transition of stiffness is obtained in the longitudinal direction of the blade. Typically, the fiber type with the highest elastic modulus is arranged outside the edge closest to the tip, and the fiber type with the lowest elastic modulus is arranged to the edge closest to the root. However, in embodiments using a glass fiber to carbon fiber transition, the tip end may be reinforced with glass fibers for photoprotection purposes only. Thus, the blade may have a second carbon fiber to glass fiber transition near the tip end.
[0025] According to an advantageous embodiment, the first-thickness and the second-thickness section have a common surface boundary between the first surface and the second surface of the wind turbine blade component. Thus, it can be seen that the two thick sections are layered one over the other.
[0026] Advantageously, the taper sections of the first thickness section and the second thickness section coincide at the common surface boundary. In other words, the taper sections formed by two common boundaries converge at a common apex point.
[0027] In one embodiment, the first-thickness section and/or the second-thickness section comprise a gradual taper between layers containing reinforcement fibers of the first type and reinforcement fibers of the second type. Hence, it will be seen that the gradual transition through the lamination procedure is obtained in the form of a transition as a double lap joint between the two types of fiber.
[0028] However, in a second preferred embodiment, the first thickness section and/or the second thickness section comprise a continuous taper between layers containing reinforcement fibers of the first type and reinforcement fibers of the second type. Hence, it will be seen that the gradual transition through the lamination procedure is obtained in the form of a transition like a double beveled joint between the two types of fiber. Furthermore, it is evident that the different fiber-containing layers need to be tapered at their end sections.
[0029] Preferably, the wind turbine component is a load-bearing structure such as a spar or spar table.
[0030] According to an advantageous embodiment, the reinforcing fibers of the first type are glass fibers. Reinforcing fibers of the second type can be, for example, carbon fibers or a hybrid of carbon fibers and glass fibers.
[0031] In one embodiment, the wind turbine blade component comprises a first section, whose fibrous composite material is mainly reinforced by reinforcing fibers of the first type, and a second section, whose fibrous composite material is mainly reinforced by reinforcing fibers of the second type, in which a gradual change is formed between the first section and the second section.
[0032] The reinforcement fibers of the first type and the reinforcement fibers of the second type are preferably arranged such that the reinforcement fibers of the first type are closer to the root end of the wind turbine blade and the fibers of reinforcement of the second type are closer to the tip end of the blade and such that the elastic modulus increases towards the tip.
[0033] In another advantageous embodiment, the wind turbine blade further comprises a gradual transition comprising a tapered section between reinforcement fibers of the first type and reinforcement fibers of a third type embedded in an additional polymer matrix, different from the polymer matrix in common. Reinforcing fibers of the third type can be, for example, glass fibres.
[0034] The common polymer matrix can advantageously be hardened or cured vinylester or epoxy. The additional polymer matrix can be stiffened or cured polyester. Therefore, it is possible to prefabricate a first part with lower strength and stiffness using more economical material and manufacture the load-bearing part with stiffer fibers and stronger matrix.
Advantageously, the component comprising the reinforcing fibers of the third type embedded in the additional polymer matrix comprises a root end laminate. Hence, the transition to fibers of the first type can be established between the root end laminate and the stringer table of the wind turbine blade. The component containing the fibers of the third type may further comprise an aerodynamic housing part of the wind turbine blade. The stringer table can be adhered, for example, by the common polymer matrix, to the aerodynamic housing.
[0036] In the same aspect, the present invention also proposes a method for manufacturing a wind turbine blade component of a wind turbine blade with a longitudinal direction between a root end and a tip end, wherein the blade component The wind turbine comprises a thickness between a first surface and a second surface, the method comprising the steps of: a) constructing a section of first thickness: i) arranging a number of first fiber layers containing reinforcing fibers of a first type, and ii) arranging a number of second fiber layers containing reinforcing fibers of a second type, wherein iii) the first fiber layers and second fiber layers are arranged such that the first fiber layers, along a first common boundary, taper towards the first surface of the wind turbine blade component in a first direction and the second fiber layers taper towards the second surface of the component of wind turbine blade in an opposite direction to the first, and b) constructing a second thickness section: i) arranging a number of additional first fiber layers containing reinforcing fibers of the first type, and ii) arranging a number of second layers of additional fibers containing reinforcing fibers of the second type, wherein iii) the first layers of additional fibers and second layers of additional fibers are arranged such that the first layers of additional fibers, along a second common boundary, taper towards to the second surface of the wind turbine blade component in a first direction and the second layers of additional fibers taper towards the first surface of the wind turbine blade component in an opposite direction to the first, and c) feed a polymeric resin in common to the section of first thickness and to the section of second thickness, and d) cure or stiffen the polymeric resin in common to embed the reinforcing fibers of the first type and the fibers s reinforcements of the second type in a common polymer matrix.
[0037] Thus, a gradual transition is obtained thanks to the double taper with reinforcement fibers of the first type arranged between reinforcement fibers of the second type or vice versa. While this increases the complexity of the fiber lamination procedure, this embodiment allows for a more rigid transition in the wind turbine component, as the two types of reinforcing fibers and the boundary between the fibers are embedded in the same polymer matrix. In addition, the transition may be shorter than prior art wind turbine components with a simple tapered section.
[0038] The polymeric resin can be fed simultaneously in steps (a) and (b), for example, via prepregs. Advantageously, however, the first fibers are arranged in dry form and a liquid resin is then fed. Resin can be injected, for example, using a VARTM method.
[0039] Preferably, the section of first thickness comprises several layers of fibers, wherein the first common boundary is composed of boundaries between the first fiber layers and the second fiber layers mutually displaced in the first direction of the wind turbine blade .
[0040] Similarly, the second thickness section may comprise several layers of additional fibers, wherein the second common boundary is composed of boundaries between the first additional fiber layers and the second additional fiber layers mutually displaced in the first direction of the wind turbine blade.
[0041] Advantageously, the ends of the various fiber layers taper at the common boundary. So the common boundary is in the form of a continuous taper, which provides a stronger transition. Therefore, the first fiber layers and the second fiber layers form a common boundary corresponding to a double beveled joint. In an alternative embodiment, the ends of the various layers do not taper. Therefore, the tapered sections form lap joints, preferably a double lap joint.
[0042] According to another aspect, the present invention proposes a method for manufacturing a part of a wind turbine blade, the method comprising the steps of: laminating a primary fiber material in a mold; infusing said primary fiber material with a primary resin; substantially curing the first primary resin in said primary fiber material to form a cured paddle element; laminating a second secondary fiber material over at least part of said cured paddle element; infusing said secondary fiber material with a secondary resin other than said primary resin, wherein said secondary resin has a higher strength level than said primary resin; and curing said secondary resin in said secondary fiber material to form an integrated reinforced section over said cured paddle element.
[0043] Therefore, it is realized that the cured blade part can be manufactured primarily with a primary fiber material and a matrix material of relatively low strength and therefore according to the relatively low cost production method, whereas the critical integrated reinforcement section is subsequently formed with secondary fiber material and a stronger matrix material. Furthermore, the production of the cured blade part can be made with a special shape, for example with a recess, such that the secondary fiber material can be formed more easily without wrinkling. Strength level preferably refers to tensile strength.
[0044] Note that the two aspects of the present invention use slightly different terms. However, preferably, the following applies:

Advantageously, the cured blade element comprises an aerodynamic blade housing part. Furthermore, the cured paddle element may advantageously comprise a root end laminate. Advantageously, the integrated reinforced section forms at least part of a stringer table or stringer beam of the wind turbine.
[0046] Preferably, said primary resin comprises a relatively low strength resin, eg polyester.
[0047] Preferably, said secondary resin comprises a reactively high strength resin, for example vinylester, epoxy, polyurethane or a hybrid resin.
[0048] Preferably, said primary resin and/or said secondary resin comprise resins cured at room temperature.
[0049] Preferably, said primary fiber material is different from said secondary fiber material.
[0050] Preferably, said secondary fiber material comprises fibers with a higher level of stiffness than the fibers of said primary fiber material.
[0051] Preferably, said fibers of said secondary fiber material have an elastic modulus or stiffness level at least 20% greater than said fibers of said primary fiber material.
[0052] Preferably, said fibers of said primary fiber material have an elastic modulus less than 50,000 MPa, whereas said fibers of said secondary fiber material have an elastic modulus greater than 53,000 MPa and, more preferably, greater that 60,000 MPa.
[0053] Preferably, said primary fiber material is a glass fiber material, eg E glass or H glass.
[0054] Preferably, said secondary fiber material is selected from one or more of the following: H-glass, carbon fibers or steel fibers.
[0055] It should be borne in mind that the secondary fiber material can be in the form of a hybrid of any combination of relatively high stiffness materials. A hybrid of glass and carbon fibers can be particularly advantageous.
[0056] Preferably, the method comprises the step of, after laminating said primary fiber material, applying a primary vacuum bag over it, wherein said step of infusing said primary fiber material with a primary resin comprises a vacuum infusion process. Therefore, the cured blade part can be prefabricated in a first step using, for example, Vacuum Assisted Resin Transfer Molding (VARTM).
[0057] Preferably, the method comprises the step of, after curing said primary resin, removing said primary vacuum bag before laminating said secondary fiber material.
[0058] Preferably, the method comprises the step of, after laminating said secondary fiber material, applying a secondary vacuum bag over it, wherein said step of infusing said secondary fiber material with a primary resin comprises a vacuum infusion process. Therefore, the critical integrated reinforced section is subsequently manufactured by a corresponding molding process.
[0059] Preferably, the method comprises the step of, after curing said secondary resin, removing said secondary vacuum bag.
[0060] Preferably, the method comprises the step of, after curing said primary resin in said primary fiber material to form a cured paddle element, removing said cured paddle element from said mold and transferring it to a secondary support. As the secondary fiber material is disposed over the cured blade portion, it is not necessary for the blade portion to continue occupying the mold. Instead, it is possible to move the cured paddle part to the holder and continue the lamination process on it. This may be particularly relevant if the cured blade part, for example, forms part of the aerodynamic blade housing. Thus, molding time can be reduced, thus increasing the productivity of the manufacturing facility. This is particularly relevant for relatively long blades, eg blades at least 60 meters long, as the lamination procedure takes up a large part of the total manufacturing time. Therefore, it is efficient if some part of the lamination and subsequent infusion procedure can be moved to secondary support.
[0061] The secondary support can comprise a secondary mold, a support table, a support base, a frame etc., for example, a post-molding system as described in WO 2013/113817.
[0062] Preferably, said step of laminating said primary fiber material comprises arranging it in said mold so as to define a recess for receiving a reinforcement section, wherein said step of laminating said secondary fiber material understands to have it in that recess. As such, the secondary material can be disposed within said recess, which will simplify the lamination procedure and ensure that an adequate transition from the cured blade portion to the fully formed reinforcing section is achieved.
[0063] Preferably, said steps of laminating the fiber material are carried out in such a way that said cured blade element comprises at least a part of a wind turbine blade housing and said reinforced section in said blade element cured comprises a main laminated section of said wind turbine blade housing. In addition, the cured paddle element may comprise a root end laminate.
[0064] Preferably, the method comprises the step of treating a surface of said at least a part of the cured paddle element prior to said step of laminating said secondary fiber material, wherein said treating step serves to increase the connection between said reinforced section and said cured paddle element after said step of curing said secondary resin. This can improve the bond between the two parties.
[0065] Preferably, said step of treating comprises surface grinding, application of primers, application of a highlight canvas during infusion (to leave a surface pattern) and application of an adhesion layer (e.g., a fabric impregnated with a prepreg solution).
[0066] In addition, or alternatively, said step of laminating said secondary fiber material comprises arranging said secondary fiber material so as to form a structural flange of said cured paddle element, e.g., an adhesive flange, wherein said step of curing said secondary fiber material forms a reinforced structural flange of said cured paddle element.
Preferably, said step of laminating said secondary fiber material to form a structural flange comprises arranging said secondary fiber material so that a primary side of said secondary fiber material is applied over at least one part of said cured paddle element and a secondary end of said secondary fiber material is free of said cured paddle element.
[0068] According to said other aspect, the present invention also proposes a method for manufacturing a wind turbine blade: obtaining a first blade element; and obtaining a second blade element, wherein at least one of the first and second blade elements comprises a cured blade element having a reinforced section manufactured in accordance with the above method, and assembling said first and second blade elements to form a wind turbine blade.
[0069] In addition, the present invention also proposes a part of a wind turbine blade, preferably a wind turbine blade housing, manufactured according to the above method.
[0070] Finally, the present invention proposes a wind turbine with at least one wind turbine blade manufactured in accordance with the above method.
[0071] Of course, the present invention is particularly suitable for large structures. Therefore, the present invention preferably relates to wind turbine blades, as well as intermediate structures, with a total length of at least 30 meters, 40 meters, 45 meters, 50 meters, 55 meters or 60 meters. DETAILED DESCRIPTION OF THE INVENTION
[0072] Hereinafter, the present invention will be explained in detail with reference to an embodiment illustrated in the drawings, among which: Fig. 1 illustrates a wind turbine, Fig. 2 illustrates a schematic view of a turbine blade wind turbine according to the present invention; Fig. 3 illustrates lamination of fiber material to form a cured paddle element, Fig. 4 illustrates lamination of fiber material to form a reinforced section integrated into the cured paddle element of Fig. 3, Fig. 5 illustrates a cross-section of the cured blade element and integrated reinforced section, Fig. 6 illustrates a schematic view of a blade housing portion comprising the cured blade element and integrated reinforced section, Fig. 7 illustrates a schematic view of the lamination of fibers of a first thickness section of a blade component, Fig. 8 illustrates a schematic view of the lamination of fibers of a second thickness section of a blade component, and Figs. 9a to 9d illustrate different variations of embodiments according to the present invention.
[0073] Fig. 1 illustrates a wind turbine in front of the conventional and modern tower according to the so-called "Danish concept", with a tower 4, a nacelle 6 and a rotor with a substantially horizontal rotor shaft. The rotor includes a hub 8 and three blades 10 which extend radially from hub 8, each with a blade root 16, closest to the hub, and a blade tip 14, farthest from hub 8. The radius of the rotor is indicated by R.
[0074] Fig. 2 illustrates a schematic view of a first embodiment of a wind turbine blade 10 according to the present invention. The wind turbine blade 10 is shaped like a conventional wind turbine blade and comprises a root region 30 closer to the hub, an airfoil region 34 further away from the hub, and a transition region 32 between the regions. of root 30 and airfoil 34. Blade 10 comprises a leading edge 18, facing the direction of rotation of blade 10 when installed on the hub, and a trailing edge 20, facing away from leading edge 18.
[0075] The airfoil region 34 (also called the profiled region) has an ideal or nearly ideal blade shape for generating lift, whereas the root region 30, due to structural considerations, has a substantially circular cross-section or elliptical, which, for example, makes it easier and safer to mount the paddle 10 on the hub. The diameter (or chord) of the root region 30 is constant throughout. The transition region 32 has a transitional profile that gradually shifts from the circular or elliptical shape of the root region 30 to the airfoil profile of the airfoil region 34. The chord length of the transition region 32 typically increases with distance r with respect to the cube increases. The airfoil region 34 has an airfoil profile with a chord that extends between the leading edge 18 and the trailing edge 20 of the blade 10. The width of the chord decreases as the distance from the hub increases.
[0076] Shoulder 40 of blade 10 is defined as the position where blade 10 has the longest length of rope. Shoulder 40 typically is formed at the boundary between transition region 32 and airfoil region 34.
[0077] It should be borne in mind that the strings of different sections of the blade normally do not lie in a common plane, as the blade can be twisted and/or bent (i.e., pre-arched), thus providing the chord plane of a correspondingly twisted and/or curved course, which is most often the case to compensate for the fact that the local blade speed depends on the radius relative to the cube.
[0078] The blade is generally made of a pressure side casing part 36 and a suction side casing part 38 which are glued together along connecting lines at leading edge 18 and trailing edge of the shovel 20.
[0079] In the following, the present invention will be explained with respect to the manufacture of the pressure side housing part 36 or the suction side housing part 38.
[0080] Figs. 3 and 4 illustrate the lamination process involved in fabricating a blade housing portion of a wind turbine blade and illustrate a cross-sectional portion of a blade mold.
[0081] The process involves the steps of laminating a primary fiber material into a mold 50. The primary fiber material comprises a number of outer skin layers 52 which form an outer part of the blade carcass part. The outer skin layers 52 can be made, for example, from biaxially oriented glass fibers. A plurality of reinforcement layers 54, preferably made of glass fibers, are disposed over the outer skin layers 52. The reinforcement layers 54 are preferably made of unidirectionally arranged glass fibers extending substantially in the longitudinal direction of the portion. of blade housing in order to provide rigidity in the span direction of the finished blade. The ends of the various reinforcement layers are preferably tapered and arranged to form a tapered section 56. A number of inner skin layers 58 are disposed over the reinforcement layers. The inner skin layers can also be made from biaxially oriented glass fibers. The inner skin layers 58 can, as illustrated in Fig. 3, be disposed over the ends of the reinforcement layers 54 such that the inner skin layers form part of the tapered section 56.
[0082] Subsequently, a number of resin inlets (not shown) and vacuum outlets (not shown) are arranged on the primary fiber material and finally a vacuum bag (not shown) is arranged above. Next, the primary fiber material is infused with a primary resin, advantageously a polyester resin, via a VARTM process, and the resin is cured to form a cured paddle element 60. In the illustrated embodiment, the outer skin layers 56 form part of the aerodynamic housing of the finished wind turbine blade, while the fiber reinforcement layers 54 form part of a wind turbine blade root laminate.
[0083] In a second step, the fiber material that is part of the weight-bearing structure, for example, a stringer table, is disposed on the cured paddle element 60, as shown in Fig. 4. The second step involves inserting a second secondary fiber material over at least part of said cured blade element 60. The secondary fiber material comprises a number of fiber reinforcement layers 62. The fiber reinforcement layers 62 may advantageously be made of fiber reinforcement layers 62. unidirectionally arranged carbon or hybrid ply containing glass fibers and carbon fibers. Finally, a number of additional inner skin layers 64 are disposed over the fiber reinforcement layers 62. Subsequently, a number of resin inlets (not shown) and vacuum outlets (not shown) are disposed over the fiber material. secondary and finally a vacuum bag (not shown) is arranged above. The secondary fiber material is then infused with a secondary resin, advantageously a vinylester resin, via a VARTM process, and the resin is cured to form an integrated reinforced section 70 over the cured paddle element 60. The reinforced section Integrated can advantageously form part of the spar, spar table or main laminate of the finished wind turbine blade. The secondary resin has a higher strength level than said primary resin.
[0084] The ends of the fiber reinforcement layers 62 of the secondary fiber material also taper, thus forming a gradual transition between the reinforcement fibers of the primary fiber material and the reinforcement fibers of the secondary fiber material. In addition, a gradual transition is formed between the primary resin and the secondary resin with a higher strength level.
The cured paddle element 60 may, as shown in Fig. 4, remain in the mold 50 during the second step. However, according to an advantageous embodiment, the cured paddle element 60 is removed from said mold 50 and transferred to a secondary support, for example a support base, where the second step is carried out.
[0086] Fig. 5 illustrates a cross-section through the mold in a part of the airfoil region of the finished blade, and Fig. 6 illustrates a perspective view of a blade housing part, which is composed of the blade element. cured 60, which comprises an aerodynamic carcass part and a root laminate, and by the integrated reinforced section 70, which forms a spar table or main laminate of the blade carcass part. As can be seen, the cured blade element 60 may also comprise a plurality of inter-arranged core materials 66 disposed on the sides of the integrated reinforced section 70.
[0087] It can also be seen that a recess may be formed in the cured paddle element 60 and that secondary fiber material may be disposed in said recess. This method has an advantage over prior art methods in that the less critical step of forming the aerodynamic shell and the more critical step of forming the load-bearing structure can be separated. By forming a recess in the aerodynamic housing, the secondary fiber material can be disposed more easily without the fiber layers wrinkling or forming mechanically brittle areas. Also, as mentioned above, the two steps can be performed on different workstations, which means that the two steps can be performed in sequence and productivity is increased since it is possible to work on two different blade parts at the same time. .
[0088] Although the two-step fabrication method offers an advantage over prior art fabrication methods, the beveled joint has been found to be a transition between glass fibers and carbon fibers or hybrid of carbon fibers and carbon fibers. glass may, in some circumstances, not provide enough strength. Therefore, although not illustrated in the figures, an over-lamination or local thickening is usually necessary. Furthermore, it is not necessarily advantageous to have a transition between both fiber types and resin types in the same tapered section.
[0089] Therefore, the present invention also proposes a method for manufacturing a wind turbine blade component, in particular a stringer table or main laminate, of a wind turbine. The fiber lamination process involved in the manufacturing method is illustrated in Figs. 7 and 8.
[0090] The wind turbine blade has a longitudinal direction between a root end and a tip end of the wind turbine blade. As before, a stringer table 170 is formed by disposing secondary fiber material in a recess of a cured paddle element 160. The method involves a first step illustrated in Fig. 7 of constructing a first thickness section 171 having a number of first fiber layers 173 containing reinforcing fibers of the first type, preferably glass fibers, and arranging a number of second fiber layers 174 containing reinforcing fibers of a second type, preferably carbon-glass hybrid plies or glass fibers . The first fiber layers 173 and second fiber layers 174 have tapered ends and are arranged so that the first fiber layers 173, along a first common boundary or tapered section 175, taper towards the first surface 172 of the fiber component. wind turbine blade in the longitudinal direction of the blade and the second layers of fibers 174 taper towards the second surface 182 of the wind turbine blade component 170 in an opposite direction in the longitudinal direction.
[0091] Then, as illustrated in Fig. 8, a second thickness section 181 is constructed by arranging a number of additional first fiber layers 183, containing the reinforcing fibers of the first type, and arranging a number of second fiber layers additional 184, containing the reinforcing fibers of the second type. The first additional fiber layers 183 and the second additional fiber layers 184 have tapered ends and are arranged so that the additional first fiber layers 183, along a second common boundary or second tapered section 185, taper towards the second surface 182 of the wind turbine blade component 170 in the longitudinal direction of the blade and the second additional fiber layers 184 taper towards the first surface 172 of the wind turbine blade component 170 in an opposite direction in the longitudinal direction. The first thickness section 171 and the second thickness section taper along a common boundary 186. In addition, a number of inner skin layers 164 can be disposed over the layers containing first type reinforcing fibers and reinforcing fibers of the second type.
[0092] Subsequently, a number of resin inlets (not shown) and vacuum outlets (not shown) are disposed on the secondary fiber material and finally a vacuum bag (not shown) is arranged above. Then, the secondary fiber material containing the first thickness section 171 and the second thickness section 181 is infused with a secondary resin, advantageously a vinylester resin, through a VARTM process, and the resin is cured to form the component. of wind turbine blade 170, which has the reinforcement fibers of the first type and the reinforcement fibers of the second type embedded in a common polymer matrix.
[0093] Therefore, it is noticed that the gradual transition is formed by a tapered section of double thickness 171, 181 with reinforcement fibers of a first type arranged between reinforcement fibers of a second type or vice versa. While this increases the complexity of the fiber lamination procedure, this embodiment allows for a more rigid transition in the wind turbine component between the two types of fibers and, in addition, the transition may be shorter than in prior art wind turbine components. with a simple tapered section. Furthermore, it is evident that double taper is obtained during lamination and that the reinforcing material is impregnated with a polymeric resin and then cured or stiffened in such a way that the two types of reinforcing fibers are embedded in a polymeric matrix in common.
[0094] As before, the first layers of fibers and the second layers of fibers advantageously comprise fibers arranged unidirectionally to provide stiffness in the span/longitudinal direction of the blade. The inner skin layers can comprise biaxially oriented glass fibers.
[0095] Although the embodiment represented with a double tapered lap joint with two types of fibers embedded in a common matrix has been illustrated, a strong transition can also be obtained by means of a double lap joint as a transition between the two types of fibers.
[0096] As a whole, it can be seen that the present invention proposes a wind turbine blade component with three different types of fiber-resin zones. The first zone comprises glass fibers embedded in polyester resin, the second zone comprises glass fibers embedded in vinylester resin, and the third zone comprises hybrid material of glass-carbon fibers or carbon fibers embedded in vinylester resin.
[0097] Although the preferred embodiment is illustrated in Figs. 7 and 8, it is clear that the above three-part transition can be achieved in various ways using the aforementioned two-step fabrication method in accordance with the present invention. Transitions can be achieved, for example, with two simple tapered sections, as illustrated in Figs. 9a and 9b, of which Fig. 9a illustrates a "short" transition and Fig. 9b illustrates a long transition. The preferred embodiment with two tapered thickness sections may also be provided with a "short" transition as shown in Fig. 9c or a "long" transition as shown in fig. 9d.
[0098] The various tapered sections can be advantageously tapered with a thickness-to-length ratio of 1:5 to 1:50, advantageously around 1:20.
[0099] The present invention has been described with reference to advantageous embodiments. However, the scope of the present invention is not limited to the illustrated embodiments, and changes and modifications can be made without departing from the scope of the present invention. REFERENCE NUMBERS LIST 2 wind turbine 4 tower 6 nacelle 8 hub 10 blade 14 blade tip 16 blade root 18 leading edge 20 trailing edge 22 pitch axis 30 root region 32 transition region 34 airfoil region 36 housing pressure side 38 suction side housing 40 shoulder 50 mold 52 outer skin layers 54 reinforcement layers 56 tapered section 58 inner skin layers 60, 160 cured paddle element 62 reinforcement layers 64, 164 inner skin layers 66 inter-arranged core material 70, 170 integrated reinforced section / stringer table / main laminate 171 first thickness section 172 first surface 173 first fiber layers containing reinforcement fibers of the first type 174 second fiber layers containing reinforcement fibers of the second type 175 first common boundary / first common taper section 181 first thickness section 182 second surface 183 first additional fiber layers containing reinforcing fibers of the first type 184 additional second fiber layers containing second type reinforcing fibers 185 second common boundary / second common taper section 186 common surface boundary

权利要求:
Claims (14)
[0001]
1. Method for manufacturing a part of a wind turbine blade (10), characterized by comprising the steps of: laminating a primary fiber material into a mold; infusing said primary fiber material with a primary resin; substantially curing said primary resin in said primary fiber material to form a cured blade element (60, 160) comprising at least a portion of a wind turbine blade casing; laminating a secondary fiber material over at least part of said cured paddle element; infusing said secondary fiber material with a secondary resin other than said primary resin, wherein said secondary resin has a higher strength level than said primary resin; and curing said secondary resin in said secondary fiber material to form an integrated reinforced section (70, 170) on said cured blade element (60, 160), the integrated reinforced section (70, 170) comprising a stringer table of the wind turbine blade casing.
[0002]
2. Method according to claim 1, characterized in that the integrated reinforced section (70, 170) forms at least part of a stringer table or stringer beam of the wind turbine.
[0003]
3. Method according to claim 1 or 2, characterized in that said primary resin comprises a relatively low strength resin, for example, polyester.
[0004]
4. Method according to any one of the preceding claims, characterized in that said resin comprises a reactively high strength resin, for example, vinylester, epoxy, polyurethane or a hybrid resin.
[0005]
5. Method according to any one of the preceding claims, characterized in that it comprises the step of, after laminating said primary fiber material, applying a primary vacuum bag over it and in that said step of infusing said Primary fiber material with a primary resin comprises a vacuum infusion process.
[0006]
The method of claim 5, characterized in that it comprises the step of, after curing said primary resin, removing said primary vacuum bag prior to laminating said secondary fiber material.
[0007]
7. Method according to any one of the preceding claims, characterized in that it comprises the step of, after laminating said secondary fiber material, applying a secondary vacuum bag over it and in that said step of infusing said Secondary fiber material with a secondary resin comprises a vacuum infusion process.
[0008]
A method according to any one of the preceding claims, characterized in that it comprises the step of, after curing said primary resin in said primary fiber material to form a cured paddle element, removing said cured paddle element from said mold and transfer it to a secondary support.
[0009]
9. Method according to any one of the preceding claims, characterized in that said step of laminating said primary fiber material comprises arranging it in said mold so as to define a recess for receiving a reinforcement section and by the fact that said step of laminating said secondary fiber material comprises arranging it in said recess.
[0010]
A method according to any one of the preceding claims, characterized in that it comprises the step of treating a surface of said at least a portion of said cured paddle element prior to said step of laminating said secondary fiber material, wherein the said treating step acts to increase the bond between said reinforced section and said cured paddle element after said step of curing said secondary resin.
[0011]
11. Method according to any one of the preceding claims, characterized in that said step of laminating said secondary fiber material comprises arranging it to form a structural flange of said cured paddle element, for example, an adhesive flange, wherein said step of curing said secondary fiber material forms a reinforced structural flange of said cured paddle element.
[0012]
12. Method for manufacturing a wind turbine blade, characterized in that it comprises: obtaining a first blade element; and obtaining a second blade element, wherein at least one of said first and second blade elements comprises a cured blade element having a reinforced section fabricated as defined in any one of the methods of claims 1 to 11, and assembling said first and second blade elements to form a wind turbine blade.
[0013]
13. Part of a wind turbine blade, in particular a wind turbine blade housing, characterized in that it is manufactured by the method as defined in any one of claims 1 to 11.
[0014]
14. Wind turbine, characterized in that it comprises at least one wind turbine blade manufactured by the method as defined in claim 12.

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PL3099471T3|2021-05-31|

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法律状态:
2019-12-17| B06U| Preliminary requirement: requests with searches performed by other patent offices: procedure suspended [chapter 6.21 patent gazette]|

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2021-05-04| B09A| Decision: intention to grant [chapter 9.1 patent gazette]|

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2021-07-06| B16A| Patent or certificate of addition of invention granted [chapter 16.1 patent gazette]|Free format text: PRAZO DE VALIDADE: 20 (VINTE) ANOS CONTADOS A PARTIR DE 30/01/2015, OBSERVADAS AS CONDICOES LEGAIS. |

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EP14153437|2014-01-31|

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