CN214273855U - Wind power blade with combined web and wind generating set - Google Patents

Abstract

The application discloses wind-powered electricity generation blade and wind generating set with combination formula web. The wind power blade includes: the shell comprises a first half shell and a second half shell which are oppositely arranged and connected with each other; and the web component is arranged between the first half shell and the second half shell and is connected to the first half shell and the second half shell. The web assembly includes: the first web comprises a first connecting section and a first main body section which are sequentially distributed in the length direction of the first web, the first main body section comprises a first core material and a first skin covering the first core material, the first core material is provided with a first transition section at one end close to the first connecting section, and the thickness of the first transition section is gradually reduced along the direction close to the first connecting section; and the second web comprises a second connecting section and a second main body section which are distributed in the length direction of the second web in sequence, the second main body section comprises a second core material and a second skin covering the second core material, and the first web and the second web are connected through the first connecting section and the second connecting section.

Description

Wind power blade with combined web and wind generating set

Technical Field

The application relates to the field of wind power generation, in particular to a wind power blade with a combined web and a wind generating set.

Background

With the continuous development of wind power technology, how to effectively improve the efficiency of wind power generation becomes one of the important development directions of the industry. At present, the most direct mode is to increase the wind sweeping area of an impeller, namely, the length of a wind power blade, but the difficulty of manufacturing and transportation is greatly increased due to the increase of the length of the blade, and the design of the modularized segmented blade is an important idea for solving the problem. The web serves as an important part of the blade, and the segmentation and connection form of the web are important. In the prior art, the segmented webs are directly butted by the adhesive to form the combined web, however, the bonding area between the segmented webs is insufficient, the connection strength is insufficient, reinforcement is required to be carried out at the joint, and the operation process and labor are additionally increased.

SUMMERY OF THE UTILITY MODEL

The application provides a wind-powered electricity generation blade and wind generating set with combination formula web, its joint strength that can improve the combination formula web of wind-powered electricity generation blade simplifies the connection technology of the combination formula web of wind-powered electricity generation blade.

In a first aspect, an embodiment of the present application provides a wind turbine blade with a combined web, which includes: the shell comprises a first half shell and a second half shell which are oppositely arranged and connected with each other; and the web component is arranged between the first half shell and the second half shell and is connected to the first half shell and the second half shell. Wherein, the web subassembly includes: the first web comprises a first connecting section and a first main body section which are distributed in sequence in the length direction of the first web, the thickness of the first connecting section is smaller than that of the first main body section, the first main body section comprises a first core material and a first skin covering the first core material, a first transition section is arranged at one end, close to the first connecting section, of the first core material, and the thickness of the first transition section is gradually reduced along the direction close to the first connecting section; the second web comprises a second connecting section and a second main body section which are distributed in the length direction of the second web in sequence, the second main body section comprises a second core material and a second skin covering the second core material, the first web and the second web are connected through the first connecting section and the second connecting section, and the first connecting section and the second connecting section extend towards each other and are arranged in a stacked mode in the thickness direction of the web assembly.

In some embodiments, the web assembly further comprises a connecting member connecting the first connecting section and the second connecting section. The connecting member includes an adhesive member and/or a fastener.

In some embodiments, the thickness of the second connector segment is less than the thickness of the second body segment. The second core material is provided with a second transition section at one end close to the second connecting section, and the thickness of the second transition section is gradually reduced along the direction close to the second connecting section.

In some embodiments, the first skin includes a thin region and a thick region, and the thick region is connected between the thin region and the first connecting section. The two thin areas are respectively arranged on the two surfaces of the first core material along the thickness direction, and the two thick areas are respectively arranged on the two surfaces of the first core material along the thickness direction. In the thickness direction, the thickness of the first connecting section is greater than the sum of the thicknesses of the two thin regions, and the thickness of the first connecting section is less than or equal to the sum of the thicknesses of the two thick regions. The thick region covers at least the first transition section.

In some embodiments, the first core further has a body section connected to the first transition section and located on a side of the first transition section remote from the first connection section.

In some embodiments, the strength of the body section is less than the strength of the first transition section.

In some embodiments, the first web further comprises a first web flange connected to the first body segment and located outboard of the first body segment in the width direction of the web assembly. The second web plate further comprises a second web plate flange, and the second web plate flange is connected to the second main body section and located on the outer side of the second main body section in the width direction.

In some embodiments, the first web cuff is aligned with and connected to the second web cuff.

In some embodiments, the first web cuff at least partially overlaps and is connected to the second web cuff.

In some embodiments, the first connecting section has a first plane facing the second connecting section, the first body section has a first inclined plane connected to the first plane, and the first plane and the first inclined plane form an obtuse angle. The second connecting section is provided with a second plane facing the first connecting section, the second main body section is provided with a second inclined plane connected with the second plane, and the included angle between the second plane and the second inclined plane is an obtuse angle. The first end part of the first connecting section, which is far away from the first main body section, is attached to the second inclined plane, and the second end part of the second connecting section, which is far away from the second main body section, is attached to the first inclined plane.

In some embodiments, the first end of the first connector segment remote from the first body segment is disposed obliquely to the length direction of the web assembly, and the first end of the first connector segment is angled from the length direction by 25 ° to 90 °. A second end of the second connecting section remote from the second main body section is parallel to the first end.

In a second aspect, an embodiment of the present application further provides a wind turbine generator set, which includes a wind turbine blade according to any one of the above embodiments.

The web subassembly that this application embodiment provided includes first web and the second web of independent shaping, compares with the web of integral type, and this application can be with single large-scale web mould split into a plurality of independent, small-size web moulds, makes the web mould arrange more in the mill nimble, improves mill space utilization, and the manufacturing cycle of web has been reduced in the part processing of more miniaturization. First linkage segment and second linkage segment are along the range upon range of setting of the thickness direction of web subassembly, compare with the scheme that first linkage segment and second linkage segment followed length direction butt joint, have great connection area between first linkage segment and the second linkage segment to improve the joint strength of first web and second web, reduce the risk that wind-powered electricity generation blade became invalid. In addition, the process of laminating the first connecting section and the second connecting section is more practical, so that the time for connecting the first web and the second web can be effectively shortened, and the labor cost is reduced. It will be appreciated that the web assembly provided herein may be any assembly that extends between the windward and leeward shells of a wind turbine blade, and that serves as a support, shear resistance or anti-buckling.

Drawings

Features, advantages and technical effects of exemplary embodiments of the present application will be described below with reference to the accompanying drawings.

Fig. 1 is a schematic structural diagram of a wind turbine blade according to an embodiment of the present application.

FIG. 2 is a schematic partial cross-sectional view of the wind blade shown in FIG. 1 taken along line L-L.

Fig. 3 is a schematic structural diagram of a web assembly provided according to an embodiment of the present application.

Fig. 4 is a schematic structural view of the first web shown in fig. 3.

Fig. 5 is a structural view of the second web shown in fig. 3.

Fig. 6 is a partial cross-sectional view of the web assembly shown in fig. 3 taken along line a-a.

Fig. 7 is a partial cross-sectional view of the web assembly shown in fig. 3 taken along line B-B.

Fig. 8 is a schematic structural view of a first web and a second web provided in accordance with some embodiments of the present application.

FIG. 9 is a schematic structural view of a first web and a second web provided in accordance with further embodiments of the present application.

FIG. 10 is a schematic illustration of the structures of a first web and a second web provided in accordance with further embodiments of the present application.

Fig. 11 is a schematic structural view of another web assembly provided in accordance with an embodiment of the present application.

Fig. 12 is a partial cross-sectional view of the web assembly shown in fig. 11 taken along line C-C.

Fig. 13 is a schematic structural view of another web assembly provided in accordance with an embodiment of the present application.

Fig. 14 is a schematic structural view of the first web shown in fig. 13.

Fig. 15 is a schematic structural view of the second web shown in fig. 13.

Fig. 16-18 are process flow diagrams of a method of forming a web assembly according to an embodiment of the present application.

Fig. 19 to 22 are process flow charts of a method for forming a web according to an embodiment of the present application.

In the drawings, the drawings are not necessarily drawn to scale.

Detailed Description

Features and exemplary embodiments of various aspects of the present application will be described in detail below, and in order to make objects, technical solutions and advantages of the present application more apparent, the present application will be further described in detail below with reference to the accompanying drawings and specific embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the present application and are not intended to limit the present application. It will be apparent to one skilled in the art that the present application may be practiced without some of these specific details. The following description of the embodiments is merely intended to provide a better understanding of the present application by illustrating examples thereof.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising … …" does not exclude the presence of other identical elements in a process, method, article, or apparatus that comprises the element.

The following description is given with the directional terms as they are used in the drawings and not intended to limit the specific structure of the present application. In the description of the present application, it is also to be noted that, unless otherwise explicitly specified or limited, the terms "mounted" and "connected" are to be interpreted broadly, e.g., as being either fixedly connected, detachably connected, or integrally connected; can be directly connected or indirectly connected. The specific meaning of the above terms in the present application can be understood as appropriate by one of ordinary skill in the art.

The embodiment of the application provides a wind generating set, and wind generating set mainly includes a tower section of thick bamboo, cabin, generator and impeller, and the cabin sets up in the top of tower section of thick bamboo, and the generator sets up in the cabin, can be located the inside in cabin, certainly, also can be located the outside in cabin. The impeller is an energy conversion device of the wind generating set and is used for converting wind energy into mechanical energy and driving the generator to generate electricity by utilizing the rotation of the impeller. The impeller mainly comprises a wind power blade and a hub. More than two wind-powered electricity generation blades are connected with wheel hub respectively, and the wind-powered electricity generation blade drives the wheel hub rotation under the effect of wind-load, and then realizes the electricity generation of generator.

Wind blades are usually externally profiled by an upper and a lower shell, the interior of which is supported by a spar-web structure. The beams are typically constructed of glass fiber composites, carbon fiber composites, or carbon glass hybrid composites, and the webs are typically composed of glass fiber composites and balsa wood cores. With the continuous development of wind power technology, how to effectively improve the efficiency of wind power generation becomes one of the important development directions of the industry. At present, the most direct mode is to increase the wind sweeping area of the impeller, namely, the length of the wind power blade is increased, but the difficulty of manufacturing and transportation is greatly increased due to the increase of the length of the wind power blade, and the design of the modularized segmented wind power blade is an important idea for solving the problem. The web serves as an important part of the wind power blade, and the segmentation and connection form of the web are very important.

Referring to fig. 1 and 2, embodiments of the present application provide a wind turbine blade with a modular web that includes a shell and a web assembly. The housing includes a first half housing 51 and a second half housing 52 which are oppositely disposed and connected to each other. The first half-shell 51 and the second half-shell 52 are butted together and joined by an adhesive. The first and second half shells 51, 52 define a cavity therebetween in which the web assembly is received. One of the first half-shell 51 and the second half-shell 52 is a windward shell, and the other is a leeward shell. The shell is a composite material body mainly composed of skin, core materials and a beam structure, and is usually formed by a vacuum infusion technology and also can be formed by a 3D printing technology.

The web assembly is disposed between and connected to the first and second half shells 51, 52. The web assembly may comprise a first web 1 and a second web 2, the first web 1 being bonded to the first half shell 51 and the second half shell 52 by means of an adhesive 53, and also bonded to the beam structure of the wind turbine blade by means of an adhesive 53. The second web 2 is bonded to the first half shell 51 and the second half shell 52 by means of an adhesive 53, and may also be bonded to the beam structure of the wind turbine blade by means of an adhesive 53. The web assembly in the wind blade may be one or more.

Referring to fig. 3-7, embodiments of the present application provide a web assembly that can be applied to a wind turbine blade. In some embodiments, the web assembly of the present application comprises a first web 1 and a second web 2 connected to the first web 1 and the second web 2.

The first web 1 comprises a first connecting section 12 and a first main body section 11 which are distributed in the length direction of the first web, and the first main body section 11 comprises a first core material 111 and a first skin 112 covering the first core material 111. The length direction of the first web 1 is parallel to the length direction X of the web assembly. In some examples, the first core material 111 is made of lightweight pvc foam to reduce the weight of the first web 1; the first skin 112 is made of a glass fiber composite material and has high strength, so that the strength of the first web 1 is improved.

The second web 2 comprises a second connecting section 22 and a second main body section 21 which are distributed in sequence in the length direction of the second web, and the second main body section 21 comprises a second core material 211 and a second skin 212 which covers the second core material 211. The length direction of the second web 2 is parallel to the length direction X of the web assembly. In some examples, second core material 211 is made of lightweight pvc foam to reduce the weight of second web 2; the second skin 212 is made of a glass fiber composite material and has high strength, so that the strength of the second web 2 is improved.

Referring to fig. 6, the first web 1 and the second web 2 are connected by a first connecting section 12 and a second connecting section 22, and the first connecting section 12 and the second connecting section 22 extend toward each other and are stacked in the thickness direction Z of the web assembly. The thickness direction of the first connecting section 12 and the thickness direction of the second connecting section 22 are both parallel to the thickness direction Z of the web assembly.

The web subassembly that this application embodiment provided includes first web 1 and the second web 2 of independent fashioned, compares with the web of integral type, and this application can be with single large-scale web mould split into a plurality of independent, small-size web moulds, makes the web mould arrange more in the mill nimble, improves mill space utilization, and the manufacturing cycle of web has been reduced in the part processing of more miniaturization. First web 1 and second web 2 can transport alone, transport to the destination after the assembly to the wind-powered electricity generation blade on, help realizing the design of segmentation wind-powered electricity generation blade or modularization wind-powered electricity generation blade, reduce the manufacturing and the transportation degree of difficulty of wind-powered electricity generation blade. First linkage segment 12 and second linkage segment 22 are range upon range of setting along the thickness direction Z of web subassembly, compare with the scheme that first linkage segment 12 and second linkage segment 22 docked along length direction X, have great connection area between first linkage segment 12 and the second linkage segment 22 to improve the joint strength of first web 1 and second web 2, reduce the risk that wind-powered electricity generation blade became invalid. In addition, the process of laminating the first connecting section 12 and the second connecting section 22 is more practicable, so that the time for connecting the first web 1 and the second web 2 can be effectively shortened, and the labor cost can be reduced.

It will be appreciated that the web assembly provided herein may be any assembly that extends between the windward and leeward shells of a wind turbine blade, and that serves as a support, shear resistance or anti-buckling.

In some embodiments, referring to fig. 6, the first core material 111 has a transition section 111a at an end near the first connection section 12, and the transition section 111a has a thickness gradually decreasing in a direction near the first connection section 12. Correspondingly, the thickness of the end of the first main body segment 11 including the transition segment 111a is gradually reduced in a direction approaching the first connection segment 12. By providing the transition section 111a, stress concentration at the junction of the first main body section 11 and the first connection section 12 can be reduced, reducing the risk of tearing at the junction of the first main body section 11 and the first connection section 12. The chamfer ratio of the transition section 111a is 1:1-1:10, i.e. the ratio of the dimension of the transition section 111a in the length direction X to the maximum thickness of the transition section 111a is 1:1-1: 10.

In some embodiments, the thickness of the first connection section 12 is less than the thickness of the first body section 11. At this time, the thickness of the first connection section 12 and the second connection section 22 laminated together is small, which can reduce the overall thickness of the web assembly.

In some embodiments, the number of webs in the web assembly is determined according to the requirement, and can also be more than two, for example, the web assembly further comprises a third web, a fourth web and the like. The number of web assemblies is also dependent on the wind blade design and may be more than one group, where one group may also be a small web near the trailing edge.

In some embodiments, the first skin 112 and the first connector segment 12 are of the same material and are integrally provided. The first connecting section 12 and the first skin 112 are integrally formed, so that the process is simplified, the manufacturing cost is reduced, and the connecting strength of the first connecting section 12 and the first main body section 11 is improved. In addition, the first connecting section 12 is made of glass fiber composite material with higher strength, so that the risk of tearing the first connecting section 12 can be reduced.

In some embodiments, the second skin 212 and the second connector segment 22 are of the same material and are integrally disposed. The second connecting section 22 and the second skin 212 are integrally formed, so that the process can be simplified, the manufacturing cost can be reduced, and the connecting strength between the second connecting section 22 and the second main body section 21 can be improved. In addition, the second connecting section 22 is made of a glass fiber composite material with higher strength, so that the risk of tearing the second connecting section 22 can be reduced.

In some embodiments, the web assembly further comprises a connecting member 3, the connecting member 3 connecting the first connecting section 12 and the second connecting section 22.

In some embodiments, the connecting member 3 includes an adhesive member 31, the adhesive member 31 may be formed by an adhesive after curing, and the adhesive member 31 is disposed between the first connecting section 12 and the second connecting section 22 to adhere the first connecting section 12 and the second connecting section 22 together.

In some embodiments, the connecting member 3 includes a fastener 32, the fastener 32 connecting the first connecting section 12 and the second connecting section 22. Optionally, the fastening member 32 includes a bolt 321 and a nut 322, and the first connecting section 12 and the second connecting section 22 are each provided with a through hole for the bolt 321 to pass through. Referring to fig. 7, the bolts 321 are uniformly distributed in the overlapping region of the first connecting section 12 and the second connecting section 22, and the bolts 321 may be arranged in a single row or in multiple rows. The bolt 321 may be a non-metal bolt such as nylon PA66, PP, PVC, PE, or a metal bolt or a bolt made of other materials. The fasteners 32 may also be rivets or other conventional fasteners.

In some embodiments, the connecting member 3 comprises a bonding member 31 and a fastener 32, the primary function of the fastener 32 is to provide a compressive load and a connection constraint when the adhesive is uncured, enabling rapid lifting of the web assembly.

In some embodiments, the connection member 3 further comprises an interlayer 33, the interlayer 33 being disposed between the first connection section 12 and the second connection section 22. In some examples, the interlayer 33 is a gasket that is sandwiched between the first and second connector segments 12, 22 for controlling the thickness of the adhesive between the first and second connector segments 12, 22. In other examples, the interlayer 33 may be a resin strip formed by pultrusion, pouring, molding or other forms, and the first connecting section 12 and the second connecting section 22 need to be kept at a certain distance according to needs, and the resin strip is filled between the first connecting section 12 and the second connecting section 22, so that the amount of adhesive can be reduced. In other examples, the interlayer 33 may be a fiber reinforced composite material, a foam material including all high molecular polymers, or a fiber yarn including various organic fibers such as glass fiber, basalt fiber, carbon fiber, boron fiber, and aramid fiber. In other examples, the structure of the interlayer 33 is bonded to the first connection segment 12 and/or the second connection segment 22, and is formed together with the first connection segment 12 and/or the second connection segment 22.

The connection manner of the first connection section 12 and the second connection section 22 is not limited to fastener connection and adhesion, and in some embodiments, the first connection section 12 and the second connection section 22 may also be formed by vacuum-injecting a resin material therebetween, and the resin material is cured to integrally connect the first connection section 12 and the second connection section 22.

In some embodiments, the thickness of the second connecting section 22 is less than the thickness of the second body section 21. At this time, the thickness of the first connection section 12 and the second connection section 22 laminated together is small, which can reduce the overall thickness of the web assembly.

In some embodiments, the first skin 112 includes a thin region 112a and a thick region 112b, and the thick region 112b is connected between the thin region 112a and the first connection segment 12. The thickness of the thick region 112b is greater than the thickness of the thin region 112 a. The thin regions 112a are two and are respectively disposed on two surfaces of the first core material 111 along the thickness direction Z, and the thick regions 112b are two and are respectively disposed on two surfaces of the first core material 111 along the thickness direction Z. The thick region 112b covers at least the transition section 111 a. The thickness of the transition section 111a is small, and the thick region 112b covers the transition section 111a, which can increase the overall strength of the end of the first body section 11 near the first connection section 12. In addition, the thick region 112b is directly connected to the first connecting section 12, and the larger thickness can bear more stress, so as to reduce the tearing risk.

In the thickness direction Z, the thickness of the first connection section 12 is greater than the sum of the thicknesses of the two thin regions 112a to ensure that the first connection section 12 has sufficient strength. The first connection section 12 and the first skin 112 are integrally provided, and in some examples, the thickness of the first connection section 12 is less than or equal to the sum of the thicknesses of the two thick regions 112 b.

In some embodiments, the first core 111 further has a body section 111b, and the body section 111b is connected to the transition section 111a and located on a side of the transition section 111a away from the first connection section 12. In some examples, the strength of the body section 111b is less than the strength of the transition section 111 a. Compared with the transition section 111a, the body section 111b is far from the first connecting section 12 and has smaller stress, so the body section 111b can be made of light material with smaller strength to reduce the overall weight of the first web 1. Optionally, the first core 111 further has an extension section 111c, the extension section 111c is connected between the body section 111b and the transition section 111a, and the extension section 111c is made of the same material as the transition section 111a and has higher strength than the body section 111 b. Optionally, thick region 112b covers extension 111 c.

In some embodiments, the first and second webs 1, 2 are substantially identical in structure. Referring to fig. 5 and 6, the second core material 211 has a transition section 211a at an end adjacent to the second connection section 22. The transition section 111a of the first core material 111 may be referred to as a first transition section, and the transition section 211a of the second core material 211 may be referred to as a second transition section. The thickness of the second transition section decreases in a direction approaching the second connecting section 22. In other embodiments, second core 211 further includes a body segment 211b and an extension segment 211c, and the transition segment 211a, the extension segment 211c, and the body segment 211b are sequentially disposed in a direction away from the second connection segment 22. The second skin 212 includes a thin region 212a and a thick region 212b connected between the thin region 212a and the second connection section 22.

In some embodiments, referring to fig. 4 and 7, the first web 1 further comprises a first web flange 13, the first web flange 13 being connected to the first body section 11 and located outside the first body section 11 in the width direction Y of the web assembly. The first web flange 13 is arranged at an angle to the first main portion 11. The first web flange 13 is used for connecting to a shell of the wind turbine blade to increase the connecting area of the first web 1 and the shell. In some examples, the first web flange 13 is one and is provided on one side of the first body section 11 in the width direction Y of the web assembly; in other examples, the first web flanges 13 are two and located on both sides of the first body section 11 in the width direction Y of the web assembly.

Referring to fig. 5 and 7, the second web 2 further includes a second web flange 23, and the second web flange 23 is connected to the second main body segment 21 and located outside the second main body segment 21 in the width direction Y. The second web flange 23 is arranged at an angle to the second body section 21. The second web flange 23 is intended to be connected to the shell of the blade in order to increase the connection area of the second web 2 to the shell. In some examples, the second web flange 23 is one and is provided on one side of the second main body section 21 in the width direction Y; in other examples, the second web flanges 23 are two and located on both sides of the second main body section 21 in the width direction Y, respectively.

In some embodiments, the first connecting section 12 is located between two second web flanges 23 and is laminated with the second connecting section 22.

In some embodiments, referring to fig. 4 and 7, the first web flange 13 at least partially overlaps and connects with the second web flange 23. Each first web flange 13 comprises a first portion 131 connected to the first body section 11 and a second portion 132 connected to the first connecting section 12, the second portion 132 being bent with respect to the first connecting section 12. Referring to fig. 5 and 7, each second web flange 23 includes a third portion 231 connected to the second body segment 21 and a fourth portion 232 connected to the second connector segment 22, the fourth portion 232 being bent with respect to the second connector segment 22.

In some examples, the second portion 132 may be inserted inside the fourth portion 232 and connected to the fourth portion 232 by the adhesive member 31. The second portion 132 and the fourth portion 232 are arranged in an overlapping manner along the thickness direction of the second portion 132, so that the connecting area of the first web flange 13 and the second web flange 23 can be increased, and the connecting strength of the first web plate 1 and the second web plate 2 can be improved.

In some embodiments, the first web flange 13 is aligned with and connected to the second web flange 23. For example, referring to fig. 8, the second portion 132 of the first web flange 13 may be omitted such that the first web flange 13 does not overlap the second web flange 23. Optionally, a fiber cloth coated with an adhesive is bonded to the first web flange 13 and the second web flange 23 to connect the first web flange 13 and the second web flange 23.

In some embodiments, referring to fig. 9, the second portion 132 of one first web flange 13 is omitted, and the first portion 131 of the first web flange 13 is aligned with and connected to the fourth portion 232 of one second web flange 23. The fourth portion 232 of the further second web flange 23 is omitted and the third portion 231 of the second web flange 23 is aligned with and connected to the second portion 132 of the further first web flange 13.

In some embodiments, a portion of the second portion 132 and a portion of the fourth portion 232 may also be removed simultaneously, such that the remaining portion of the second portion 132 is aligned with and connected to the remaining portion of the fourth portion 232.

The shape of the first web flange 13 and the shape of the second web flange 23 can be set as desired. For example, in some examples, referring to fig. 7, the first web flanges 13 are folded over entirely to one side and the second web flanges 23 are folded over entirely to one side. In other embodiments, referring to fig. 10, the first web flange 13 is divided into two layers and the two layers of the first web flange 13 are folded in opposite directions, respectively, and the second web flange 23 is divided into two layers and the two layers of the second web flange 23 are folded in opposite directions, respectively.

In some embodiments, referring to fig. 11 and 12, the first connecting section 12 has a first plane 122 facing the second connecting section 22, the first main body section 11 has a first inclined surface 113 connected to the first plane 122, and the first plane 122 and the first inclined surface 113 form an obtuse angle. The first flat surface 122 and a sloped surface 113 form a first recess. In some examples, the surface of the first connection segment 12 facing away from the second connection segment 22 is flush with the surface of the thick region 112 b.

The second connecting section 22 has a second plane 222 facing the first connecting section 12, the second main body section 21 has a second inclined surface 213 connected to the second plane 222, and the angle between the second plane 222 and the second inclined surface 213 is an obtuse angle. The second plane 222 and the second inclined plane 213 form a second recess. In some examples, the surface of the second connector segment 22 facing away from the first connector segment 12 is flush with the thick area of the second skin 212.

A first end of the first connecting section 12 away from the first main body section 11 is attached to the second inclined surface 213, and a second end of the second connecting section 22 away from the second main body section 21 is attached to the first inclined surface 113. The first connecting section 12 is inserted into the second recess, and the second connecting section 22 is inserted into the first recess, so that the extra occupied space of the first connecting section 12 and the second connecting section 22 in the thickness direction Z can be reduced, and the maximum size of the web assembly in the thickness direction Z can be reduced. In addition, the first and second inclined surfaces 113 and 213 may also serve as a positioning and guiding function during the process of assembling the first and second webs 1 and 2.

In some embodiments, referring to fig. 13 and 14, the first end 121 of the first connecting section 12 remote from the first body section 11 is disposed obliquely to the length direction X of the web assembly, and the first end 121 of the first connecting section 12 is at an angle α of 25 ° to 90 ° to the length direction X. Referring to fig. 14 and 15, the second end 221 of the second connecting section 22 remote from the second body section 21 is parallel to the first end 121. The second end 221 is angled 25-90 degrees from the length direction X. Optionally, the first end 121 includes an angle α of 25 ° to 65 ° with respect to the length direction X. At this time, the whole overlapping area of the first connecting section 12 and the second connecting section 22 is obliquely arranged; the joint of the first connecting section 12 and the second connecting section 22 mainly bears shearing force, and the overlapping area is arranged obliquely, so that the overlapping area can bear larger shearing force, and the risk of tearing the first connecting section 12 and the second connecting section 22 is reduced. In addition, when the wind power blade is damaged and cracks are generated at the joint of the first connecting section 12 and the second connecting section 22, the overlapping area is obliquely arranged, so that the crack propagation can be effectively reduced.

In some embodiments, referring to fig. 13 and 14, both edges of the first connection section 12 in the width direction Y of the web assembly are inclined toward a direction in which they approach each other. Correspondingly, the two second portions 132 connected to the two edges are also inclined toward each other. At this time, the two first web flanges 13 are more easily inserted between the two second web flanges 23, simplifying the assembly process of the first web 1 and the second web 2. The second portion 132 is angled from the length direction X by an angle beta of 1-15 deg..

The application also provides a molding method of the web component. Referring to fig. 16 to 18, a method of forming a web assembly of an embodiment of the present application includes:

s110: providing a first web plate 1, wherein the first web plate 1 comprises a first connecting section 12 and a first main body section 11 which are distributed in sequence in the length direction of the first web plate 1, the first main body section 11 comprises a first core material 111 and a first skin 112 covering the first core material 111, the first core material 111 is provided with a transition section 111a at one end close to the first connecting section 12, and the thickness of the transition section 111a is gradually reduced along the direction close to the first connecting section 12;

s120: providing a second web 2, wherein the second web 2 comprises a second connecting section 22 and a second main body section 21 which are distributed in the length direction of the second web 2 in sequence, and the second main body section 21 comprises a second core material 211 and a second skin 212 which covers the second core material 211;

s130: arranging the first connecting section 12 of the first web 1 and the second connecting section 22 of the second web 2 in an opposite direction, and then laminating the first connecting section 12 and the second connecting section 22 in the thickness direction;

s140: connecting the first connecting section 12 and the second connecting section 22.

In the forming method of the web plate assembly provided by the embodiment of the application, a single large-scale web plate die can be split into a plurality of independent and small-volume web plate dies, so that the web plate dies are more flexibly arranged in a factory, the space utilization rate of the factory is improved, and the manufacturing period of the web plate is shortened by processing more miniaturized parts. First linkage segment 12 and second linkage segment 22 are range upon range of the setting along the thickness direction of web subassembly, compare with the scheme that first linkage segment 12 and second linkage segment 22 docked along length direction, have great connection area between first linkage segment 12 and the second linkage segment 22 to improve the joint strength of first web 1 and second web 2, reduce the risk that wind-powered electricity generation blade became invalid. In addition, the process of laminating the first connecting section 12 and the second connecting section 22 is more practicable, so that the time for connecting the first web 1 and the second web 2 can be effectively shortened, and the labor cost can be reduced.

In some embodiments, step S140 includes:

s141: referring to fig. 16, through holes H are formed in the first connection section 12 and the second connection section 22;

s142: referring to fig. 17, the first connection section 12 and the second connection section 22 are separated, the bolt 321 is inserted into the through hole H of the first connection section 12, and the gasket 331 is fitted over the bolt 321;

s143: coating an adhesive on the surface of the first connecting section 12;

s144: referring to fig. 18, the first connection section 12 and the second connection section 22 are aligned in the thickness direction, a bolt 321 is passed through a through hole H of the second connection section 22, a nut 322 is mounted on the bolt 321 and tightened to connect the first connection section 12 and the second connection section 22, and an adhesive and a gasket 331 are sandwiched between the first connection section 12 and the second connection section 22.

In step S141, a through hole H may be formed in the first and second connection sections 12 and 22 using an electric drill or a punch. A spacer 331 is sandwiched between the first connecting section 12 and the second connecting section 22 for controlling the thickness of the adhesive between the first connecting section 12 and the second connecting section 22. The adhesive is cured to form the adhesive member 31.

In some embodiments, step S140 further comprises step S145: an adhesive is applied at the nut 322 to prevent the nut 322 from loosening.

After step S144 or S145, the adhesive may be cured by direct heating, or the formed web assembly may be hoisted into the wind turbine blade mold and adhered to the beam structure of the wind turbine blade by the adhesive, and then the adhesive between the first connecting section 12 and the second connecting section 22 and the adhesive between the web assembly and the beam structure are cured simultaneously.

The application also provides a forming method of the web. The molding method of the web plate comprises the following steps:

s210: referring to fig. 19, a first fiber layer 41 is laid on the mold;

s220: referring to fig. 20, a core material 42 is placed on a first fiber layer 41, and one end of the core material 42 has a transition section 421 having a gradually decreasing thickness;

s230: referring to fig. 21 and 22, a second fiber layer 43 is laid over the first fiber layer 41 such that the core material 42 is wrapped between the first fiber layer 41 and the second fiber layer 43;

s240: introducing a resin into the first fiber layer 41 and the second fiber layer 43, and then heat-curing the resin to join the first fiber layer 41 and the second fiber layer 43 and prepare the web 4, the joined first fiber layer 41 and second fiber layer 43 forming a skin 44 covering the core material 42 and a connecting section 45 extending from the skin 44, the transition section 421 having a thickness gradually decreasing in a direction approaching the connecting section 45.

The web 4 produced by the molding method of the embodiment of the present application may be connected to other webs by connecting segments 45. By providing the transition section 421, the stress concentration at the transition section 421 can be reduced, and the risk of tearing the connecting section 45 and the skin 44 can be reduced. Two webs 4 produced by the forming method of the embodiment of the present application may be connected by a connecting section 45 to form a larger-sized web assembly. In other words, the molding method of the embodiment of the application can reduce the web die, so that the web die is more flexibly arranged in a factory, the space utilization rate of the factory is improved, and the manufacturing period of the web is shortened by more miniaturized part processing.

In the web assembly of the embodiment of the present application, at least one of the first web 1 and the second web 2 is formed by the above-described web forming method.

In step S220, referring to fig. 20, the core member 42 includes a plate-shaped body section 422 and a transition section 421, and the body section 422 and the transition section 421 are independently provided and have different materials. The body section 422 may be of a less strong lightweight material to reduce the overall weight of the web 4. The transition section 421 is close to the connecting section 45 and is subjected to a large force, and the transition section 421 can be made of a material with high strength to improve the deformation resistance.

In some embodiments, in step S240, the resin is introduced into the first fiber layer 41 and the second fiber layer 43 by a vacuum infusion process.

In some embodiments, referring to fig. 19, step S210 includes:

s211: laying the first lower fibre layer 411 on the mould;

s212: the first upper fiber layer 412 is laid on the first lower fiber layer 411, the size of the first upper fiber layer 412 is smaller than that of the first lower fiber layer 411 in the length direction of the first lower fiber layer 411, the first upper fiber layer 412 is laid on the end of the first lower fiber layer 411 in the length direction, and the first upper fiber layer 412 and the first lower fiber layer 411 constitute the first fiber layer 41.

Referring to fig. 20, step S220 includes: the core material 42 is placed onto the first lower fiber layer 411 and the first upper fiber layer 412 with at least the transition 421 located on the first upper fiber layer 412.

The first lower fiber layer 411 and the first upper fiber layer 412 can increase the thickness of the web 4 near the transition section 421, improve the strength of the web 4 at the transition section 421, and reduce the tearing risk.

In some embodiments, the first upper fiber layers 412 are disposed in a plurality and stacked manner, and two adjacent first upper fiber layers 412 are disposed in a staggered manner in the length direction. The first lower fiber layer 411 needs to be attached to the core material 42, and then the first lower fiber layer 411 needs to be bent along the end of the first upper fiber layer 412; by arranging the plurality of first upper fiber layers 412 in a staggered manner, the bent portions of the first lower fiber layers 411 can be made smoother, and stress concentration can be reduced.

In some embodiments, the first lower fiber layer 411 is multiple and arranged in layers.

In some embodiments, step S230 includes:

s231: laying a second lower fiber layer 431 over the first upper fiber layer 412 such that the first upper fiber layer 412 and the second lower fiber layer 431 cover the transition section 421 from both sides;

s232: a second upper fiber layer 432 is laid over the second lower fiber layer 431, the second upper fiber layer 432 covers the core material 42, and the second lower fiber layer 431 and the second upper fiber layer 432 constitute a second fiber layer 43.

Referring to fig. 22, in step S240, a first lower fiber layer 411, a first upper fiber layer 412, a second lower fiber layer 431, and a second upper fiber layer 432 are sequentially stacked on the connecting segment 45. The multi-layered structure may increase the overall strength of the connection section 45.

In some embodiments, both the second lower fiber layer 431 and the second upper fiber layer 432 are plural.

In accordance with the embodiments of the present application as described above, these embodiments are not exhaustive and do not limit the application to the specific embodiments described. Obviously, many modifications and variations are possible in light of the above teaching. The embodiments were chosen and described in order to best explain the principles of the application and its practical application, to thereby enable others skilled in the art to best utilize the application and its various modifications as are suited to the particular use contemplated. The application is limited only by the claims and their full scope and equivalents.

Claims (10)

1. A wind turbine blade with a composite web, comprising:

the shell comprises a first half shell and a second half shell which are oppositely arranged and connected with each other;

a web assembly disposed between and connected to the first and second half shells;

wherein the web assembly comprises:

the first web comprises a first connecting section and a first main body section which are distributed in sequence in the length direction of the first web, the thickness of the first connecting section is smaller than that of the first main body section, the first main body section comprises a first core material and a first skin covering the first core material, the first core material is provided with a first transition section at one end close to the first connecting section, and the thickness of the first transition section is gradually reduced along the direction close to the first connecting section;

the second web comprises a second connecting section and a second main body section which are distributed in the length direction of the second web in sequence, the second main body section comprises a second core material and a second skin covering the second core material, the first web is connected with the second web through the first connecting section and the second connecting section, and the first connecting section and the second connecting section extend towards each other and are stacked in the thickness direction of the web assembly.

2. Wind turbine blade according to claim 1,

the web assembly further comprises a connecting member connecting the first connecting section and the second connecting section;

the connecting member includes an adhesive member and/or a fastener.

3. The wind blade as set forth in claim 1 wherein the second connecting section has a thickness less than the thickness of the second main body section, and the second core material has a second transition section at an end adjacent to the second connecting section, the thickness of the second transition section decreasing in a direction adjacent to the second connecting section.

4. Wind turbine blade according to claim 1,

the first skin comprises a thin region and a thick region, and the thick region is connected between the thin region and the first connecting section;

the two thin areas are respectively arranged on two surfaces of the first core material along the thickness direction, and the two thick areas are respectively arranged on two surfaces of the first core material along the thickness direction;

in the thickness direction, the thickness of the first connecting section is greater than the sum of the thicknesses of the two thin areas, and the thickness of the first connecting section is less than or equal to the sum of the thicknesses of the two thick areas;

the thick region covers at least the first transition section.

5. Wind turbine blade according to claim 1,

the first core material is also provided with a body section which is connected to the first transition section and is positioned on one side of the first transition section, which is far away from the first connecting section;

the strength of the body section is less than the strength of the first transition section.

6. Wind turbine blade according to claim 1,

the first web plate also comprises a first web plate flange which is connected with the first main body section and is positioned on the outer side of the first main body section along the width direction of the web plate component;

the second web plate further comprises a second web plate flange, and the second web plate flange is connected to the second main body section and located on the outer side of the second main body section in the width direction.

7. Wind turbine blade according to claim 6,

the first web flange and the second web flange are aligned and connected; or,

the first web flange and the second web flange at least partially overlap and are connected.

8. Wind turbine blade according to claim 1,

the first connecting section is provided with a first plane facing the second connecting section, the first main body section is provided with a first inclined plane connected with the first plane, and the included angle between the first plane and the first inclined plane is an obtuse angle;

the second connecting section is provided with a second plane facing the first connecting section, the second main body section is provided with a second inclined plane connected with the second plane, and the included angle between the second plane and the second inclined plane is an obtuse angle;

the first end part, far away from the first main body section, of the first connecting section is attached to the second inclined plane, and the second end part, far away from the second main body section, of the second connecting section is attached to the first inclined plane.

9. Wind turbine blade according to any of claims 1 to 8,

a first end of the first connecting section, which is far away from the first main body section, is obliquely arranged relative to the length direction of the web plate assembly, and the included angle between the first end of the first connecting section and the length direction is 25-90 degrees;

a second end of the second connector segment distal from the second body segment is parallel to the first end.

10. A wind park comprising a wind blade according to any of claims 1-9.

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