IMPROVEMENTS RELATING TO REINFORCEMENT OF WIND TURBINE TOWERS

Abstract

A tower section for a wind turbine, comprising a tensioning arrangement having at least one tensioning device attached to three or more attachment points associated with the tower section, wherein those attachment points are located proximate to an end of the tower section. The or each tensioning device is under tension and provides radial stiffness to the tower section. The invention also relates to a method for assembling a tower for a wind turbine, the method comprising: providing a tower section; attaching a tensioning arrangement including at least one tensioning device between three or more attachment points associated with the tower section and located proximate to an end thereof; and applying tension to the at least one tensioning device so as to provide radial stiffness to the

Claims

1. A tower section for a wind turbine, wherein the tower section comprises: a tensioning arrangement comprising one or more tensioning devices attached to three or more attachment points associated with the tower section, wherein those attachment points are located proximate to an end of the tower section, wherein the one or more tensioning device are under tension and provide radial stiffness to the tower section.

2. The tower section of claim 1, wherein the attachment points are located in the same or nearly the same transverse plane of the tower section, that transverse plane being perpendicular to the central axis of the tower section.

3. The tower section of claim 1, wherein at least one of the attachment points is associated with an interior surface of the tower section.

4. The tower section of claim 1, wherein at least one of the attachment points is provided by an additional component separate to the tower section.

5. The tower section of claim 4, wherein the additional component is a flange that affixes to the tower section.

6. The tower section of claim 1, wherein at least one of the tensioning devices is configured such that the tension applied between at least two of the three or more attachment points is adjustable.

7. The tower section of claim 1, wherein at least one of the tensioning devices is a linear member that spans between two of the attachment points.

8. The tower section of claim 1, wherein at least one of the tensioning devices spans between two diametrically opposed attachment points.

9. The tower section of claim 1, wherein at least one of the tensioning devices spans between a pair of attachment points so as to form a chord with respect to the tower section.

10. The tower section of claim 1, wherein at least one of the tensioning devices includes an adjusting mechanism which allows for the tension applied by the respective tensioning device to the tower section to be adjusted.

11. The tower section of claim 10, wherein the adjusting mechanism is selected from one or more of the group of: a turnbuckle; a screw adjuster; a hydraulic adjuster; an electrically-driven adjuster.

12. The tower section of claim 1, wherein the attachment points are brackets to which the tensioning devices is attached.

13. The tower section of claim 12, wherein the brackets are removably attached to the tower section.

14. The tower section of claim 13, wherein the brackets are attached to the tower section with bolts.

15. The tower section of claim 14, wherein the bolts are attached to a flange that affixes to the tower section.

16. A method for assembling a tower for a wind turbine, the method comprising: providing a tower section; attaching a tensioning arrangement including at least one tensioning device between at least three attachment points associated with the tower section and located proximate to an end thereof; and applying tension to the at least one tensioning device so as to provide radial stiffness to the tower section.

17. The method of claim 16, wherein attaching the at least one tensioning device between the at least three attachment points associated with the tower section comprises: attaching the at least one tensioning device to an additional component via at least three attachment points thereof; and attaching the additional component to the tower section.

18. The method of claim 17, wherein the additional component is a flange component of the tower.

19. The method of claim 16, wherein the method further comprises adjusting the tension applied to the at least one tensioning device.

20. The method of claim 16, wherein, following the step of applying tension to the at least one tensioning device, the method comprises a step of lifting the tower section into a position for assembly.

21. The method of claim 20, wherein, following the step of lifting the tower section into position for assembly the method comprises a step of attaching the tower section to one of the foundation or another tower section, and a following step of removing the tensioning arrangement.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0026] The above and other aspects of the invention will now be described, by way of example only, with reference to the accompanying drawings, in which:

[0027] FIG. 1 is a schematic view of a wind turbine in which the embodiments of the invention may be implemented;

[0028] FIGS. 2a to 2c, FIGS. 3a to 3c and FIG. 4 are views of various embodiments of the invention; and

[0029] FIG. 5 is a flowchart of an aspect of the invention.

[0030] In the drawings, the same reference numerals are used to denote features that are common across drawings.

SPECIFIC DESCRIPTION

[0031] FIG. 1 shows a horizontal axis wind turbine 2 in which embodiments of the invention may be implemented. As the skilled person will recognise as being conventional, the wind turbine 2 comprises a tower 4, a nacelle 6 and a set of blades 8. The tower 4 is supported on a foundation in the ground (not shown) and the nacelle 6 is mounted on top of the tower 4. The nacelle 6 houses power generating equipment and a rotor, including a rotor hub 7, to which the blades 8 are attached.

[0032] As would be known to the skilled person, the tower 4 comprises a plurality of tower sections 10, arranged on top of each other. It is to be understood that the number of tower sections 10 included in the tower 4 is not a critical feature of the invention. Indeed, the tower 4 may comprise only one tower section 10 and still fall within the scope of the appended claims. The tower sections 10 are substantially cylindrical but are tapered slightly in the illustrated embodiment so as to have a slightly larger diameter at their base than at their top. To provide a context, in current manufacturing approaches, tower sections are typically around 10 to 30 metres in height, and around 3 to 6 metres in diameter.

[0033] Turning now to FIG. 2a, an illustrative but somewhat simplified view of one of the tower sections 10 is shown. The skilled person would appreciate that the tower section may comprise other components that are not illustrated here for the sake of clarity, for example access ladders, cable support brackets, floor joists and so on. The tower section 10 comprises a cylindrical tower wall 12 that defines an internal surface 14 and an external surface 16. The strength of the tower section 10 is largely derived from the thickness of the cylindrical wall, and so a lighter tower section with a thinner wall will inherently be more flexible in the transverse or radial direction. This means that the tower section is vulnerable to being deformed out of a true circular cross section. This is particularly the case during transportation where it is conventional to convey tower sections oriented horizontally, for example on the back of a flatbed trailer. In such a scenario, it will be appreciated that the tower section is susceptible to deforming into an oval shape under its own weight. However, such deformation may also occur during operation of the wind turbine.

[0034] The inventive concept addresses this problem by equipping the tower section with a tensioning arrangement, shown generally as 18, that applies a force to multiple points, zones or regions on the internal surface of the tower section. The force applied to those points is directed in a radially inwards direction, for example towards the centre of the tower, and preferably directed towards the tower axis. Significantly, the force applied to the tower at multiple points spaced at pre-determined angularly-spaced intervals enables the ovality of the tower to be controlled during transportation and tower construction, but also increases the in stiffness of the tower during use. This may be achieved in various ways, as will be described below with reference to the illustrated embodiments.

[0035] The tower section in FIG. 2a is equipped with an elegantly simple tensioning arrangement 18 which includes a plurality of a tensioning devices 20. Each of the tensioning devices 20 is connected to and therefore acts between two opposed respective attachment points 22 (not all of which are labelled on FIG. 2a, for clarity) associated with the internal surface 14 of the tower section 10. As shown, the tensioning devices 20 are attached to attachment points 22 that are located towards or proximate to the top end 23 of the tower section 10. The terms ‘located towards’ and ‘proximate’ should be interpreted functionally, and it is not intended that the attachment points 22 need to be located immediately next to the upper edge of the tower wall 12. From a broad perspective, locating the attachment points 22 at or near to the top end 13 of the tower section 10 means that tension is applied at a cross sectional plane where it is important that a circular cross section should be maintained because it is at the open top end 13 of the tower section 10 where it is connected to another tower section. It will be appreciated that this is most easily achieved if the two adjoining parts of the neighbouring tower sections are precisely circular in transverse cross section when they are mated. Functionally, therefore, the attachment points 22 should be located near to the top end 13 of the tower section 10 so as to achieve this objective, and the precise location may depend on the construction of the tower. For example, the objective might be achieved if the attachment points 22 are located within a distance from the top end 13 of the tower section that is 5% of the overall height of the tower section. In other embodiments, the objective might be achieved if the attachment points 22 are located within a distance that is 10%, or even 25% of the height of the tower section 10.

[0036] In other arrangements, however, the attachment points 22 may be located at other levels along the height of the internal surface 14 of the tower wall 12.

[0037] Preferably, each of the tensioning devices 20 is attached to diametrically opposed points as, in this arrangement, the radially inward force applied to the tower via the attachment points 22 is perpendicular to the wall and so is most effective at compensating for any deformation of the tower. In the illustrated embodiment, therefore, the tensioning devices 20 span across the central axis of the tower section 10. The number of attachment points 22 apply a radial force to the tower wall in many different radial planes which provides very effective control over the ovality of the increased stiffness of the tower section.

[0038] Each of the plurality of tensioning devices 20 extends across the centre of the tower at a different angle. As shown here, there are four separate tensioning devices 20 which are equi-angularly spaced. However, this is not essential, and the angular spacing could be unequal. It should also be noted that the attachment points 22 are located in the same or nearly the same transverse plane of the tower section 10, that transverse plane being perpendicular to the central axis of the tower section 10. The phrase ‘the same transverse plane’ is meant to be interpreted functionally, as there may be some slight vertical offset between the attachment points 22 relative to one another. However, it is anticipated that some deviation from being in the same plane is acceptable.

[0039] In this embodiment, each tensioning device 20 is a single arm-like linear member that may be a rigid element such as a rod made from metal or plastic, although any suitably rigid material would suffice. It is also envisaged that a flexible or resilient element such as a plastic (e.g. Nylon) or metal fabric would be acceptable. Where the tensioning device 20 is resilient, it may be stretched when attached to the respective attachment points 22 so that it applies a tensioning force to the tower section 10 when suitably attached to it. Similarly, a rigid rod-like tensioning member with a length the same as the diameter of the tower would apply a tension to the tower as soon as the tower starts to deform.

[0040] In the embodiment of FIG. 2a, the attachment points 22 are provided on the internal surface 14 of the tower wall 12. However, it should be noted that this is not essential and that other arrangements are possible such that any internal surface of the tower section is useful for attachment of the tensioning device. For example, attachment points may be provided on a radial flange extending inwardly from the tower wall 12 either somewhere between the top and bottom ends of the tower wall, or at the top and/or bottom ends, or on a flange that is a separate component from the tower wall, but affixed to it during construction. Such embodiments will be covered in the discussion that follows.

[0041] It should be noted that although the tensioning arrangement 18 shown in FIG. 2a is relatively simple, it may be suitable to achieve the intended result depending on the inherent radial stiffness of the tower. However, other embodiments are envisaged that use more sophisticated tensioning arrangements.

[0042] It may be the case that the tensioning arrangement 18 does not comprise members that span between diametrically opposed points on the internal surface tower section 10. FIG. 2b shows an embodiment of a tensioning arrangement 18 having four tensioning devices 20 arranged in a rectilinear formation, more specifically a square. The tensioning devices 20 forming the edges of the square formation span across the tower sections 10 as chords, rather than spanning between diametrically opposed points. In this embodiment, although the tensioning force will act on the attachment points 22 along the linear members 18, the overall force on the tower section 10 still acts towards the centre of the tower section 10, and therefore perpendicular to the tower wall 12, since each tensioning device 20 extends away from its respective attachment point 22 at an equivalent angle to its neighbouring tensioning device 20. At this point, it should be noted that only the configuration of the tensioning arrangement 18 in this embodiment is different. Therefore, the tensioning arrangement 18 may be affixed to the attachment points 22 in the same manner as the other embodiments.

[0043] FIG. 2c shows a further embodiment of the tensioning arrangement 18, in which a tensioning device 20 has a so-called ‘hub and spoke’ configuration. As such, the tensioning device 20 comprises a central hub 24, from which radiate a plurality of arms or spokes 26. Here, the tensioning device 20 comprises six spokes 26 extending between the central hub 24 and respective attachment points 22 (only two of which are labelled in FIG. 2c). The hub 24 and the spokes may be the same or different material. For example, the hub 24 may be a rigid ring of metal or composite, and the spokes may be fabric straps. Although six spokes are shown in this embodiment, it is envisaged that at least three spokes should be provided in order to result in a balanced radial tension on the tower section. Again, in a three-spoked embodiment, it is envisaged that angularly equi-spaced attachment points 22 would provide the most radially balanced tension. So, each attachment point 22 could be spaced from neighbouring attachment points by 120 degrees. Other arrangements would be possible, however.

[0044] In in embodiments of FIGS. 2a to 2c, the tensioning devices 20 may be attached to the respective attachment points 22 in any way suitable to affix them in place such that the tension applied by the tensioning devices 20 causes an inward radial force to act on the tower section 10 thereby improving its radial stiffness and providing better control over the ovality of the tower section. Some variants will now be described in more detail with reference to FIGS. 3a to 3c.

[0045] In one embodiment, as shown in FIG. 3a, the attachment points 22 may take the form of bores or holes formed in the tower wall 12 within which an end of a respective tensioning device 20 is received. One option is for the ends of the tensioning device 20 to be provided with external threads that can be screwed into complementary internally threaded holes. Another option is for the ends of the tensioning devices 20 to be mechanically bonded to the holes by way of a suitable technique, for example with adhesive or by welding.

[0046] In another embodiment, as shown in FIG. 3b, the attachment points 22 may also take the form of brackets to which the tensioning device 20 is attached. Any suitable mechanical fastening system may be used, such as bolts or welding. The brackets may either be integral with or removably attached to the tower section 10.

[0047] The bolts may be attached to flanges that affixes to the tower section. More specifically, flanges at the open end of the tower section. The flanges are equipped with a plurality of holes for the bolts that hold the tower section to the foundation or another tower section upon assembly (not shown). The holes are vacant during until assembly and it is therefore convenient to use bolts temporarily inserted in the holes to temporarily attach the brackets to the tower section.

[0048] In a further embodiment, as shown in FIG. 3c, the tensioning arrangement 18 may span between attachment points 22 that are provided in a radially inward facing surface of a flange 30 of the tower section 10 rather than being provided in the cylindrical tower wall 12.

[0049] In the above embodiments, the tensioning devices 20 are configured to apply a tension between opposed associated attachment points 22. As the skilled person will appreciate, this may be achieved in various ways. For example, a fabric strap will inherently apply tension if it is stretched as it is connected to the attachment points. In other embodiments, however, the tensioning device 20 may be provided with a tensioning mechanism, as shown schematically in FIGS. 3a to 3c by the numeral ‘32’.

[0050] The tensioning mechanism 32 may generate some or all of the tension that is applied by the tensioning device 20 between the opposed attachment points 22. The configuration of the tensioning mechanism 32 may depend on the material from which the tensioning device 20 is made. For example, if the tensioning device 20 is a steel rod, a turnbuckle or other screw-based tensioning device may be an appropriate option to apply sufficient tension. Alternatively, other more complicated variants may be used, such as a tensioning system using hydraulic or electric actuators. If the tensioning device 20 comprises fabric straps, then the at least one tensioning mechanism 32 may take the form of a windlass-style ratchet.

[0051] It should be appreciated that it is advantageous for the tension applied to the tensioning device 20 by the tensioning mechanism 32 to be adjustable. In particular, where a hydraulic tensioning system is used as the tensioning mechanism 32 the hydraulic tensioning system may automatically adjust the tension applied by the tensioning device 20. This allows the tensioning device 20 to respond to and therefore compensate for environmental conditions to adjust the support provided to the tower section 10, and therefore the tower 4, of the wind turbine 2. As an example, if wind speeds are high in the area around the wind turbine 2, the hydraulic tensioning system may increase the tension applied to the tensioning device 20 to increase the stiffening effect on the tower section 10.

[0052] A final embodiment is shown in FIG. 4, in which parts that are common with the embodiments described above are denoted with the same reference numerals. In this embodiment, the tensioning arrangement 18 is connected to attachment points 22 provided in an additional component, here a flange component 34, that is separate to the tower section 10. The tensioning arrangement 18 is shown as comprising a pair of linear members that are arranged into an x-shaped formation so as to cross each other perpendicularly at the centre of the flange component 34. Other forms of tensioning arrangement will also be suitable, as discussed in the previous embodiments.

[0053] As is shown, the flange component 34 is separate to the tower section 10 and may be affixed thereto by appropriate methods, for example by welding. It may also be fixed to an integral flange member of the tower section 10.

[0054] It will therefore be appreciated that a benefit of this embodiment is that the flange component 34 including the tensioning arrangement 18 may be retrofitted to tower sections to improve their radial stiffness.

[0055] The embodiments of the invention may also be expressed as a method, as is illustrated by the flowchart in FIG. 5.

[0056] At step 100, a tower section is provided. For example, a tower section 10 may be manufactured and transported to the installation site before being equipped with the tensioning arrangement 18. It is also envisaged that a tower section 10 may be fabricated and then equipped with the tensioning arrangement 18 before the tower section 10 is transported.

[0057] In either scenario discussed above, at step 102 a tensioning arrangement 18 according to the embodiments discussed above is applied to the tower section 10 at the appropriate time when it is determined that an increase in the radial stiffness of the tower section 10 is required. It will be appreciated that this will be dependent on the design characteristics of the tower section 10 and whether the tower section 10 has sufficient radial stiffness to be transported without the tensioning arrangement 18 attached.

[0058] In this step, it should be noted that the application of the tensioning arrangement to the tower section 10 may be achieved by attaching one or more tensioning devices 20 directly to the tower section 10, for example to the tower wall 12 as discussed above with reference to FIGS. 2a-2c and FIGS. 3a-3c, or by attaching one or more tensioning devices 20 to a separate component, for example a tower flange as discussed above with reference to FIG. 4.

[0059] In a further step (step 104), the tensioning arrangement 18 is tensioned to a value that is determined to be sufficient to impart an improved radial stiffness to the tower. As discussed above with reference to the illustrated embodiments, the tension applied by the tensioning arrangement 18 depends on the configuration of the tensioning device which in turn may depend on the radial stiffness requirements of the tower. For example, in some embodiments, a resilient strap connected between a pair of attachment points may provide sufficient radial stiffness. In other scenarios, however, a tensioning device in the form of a steel rod may require a turnbuckle-style tensioning mechanism to apply a sufficient tension. Furthermore, as mentioned above, in embodiments featuring a steel rod as the tensioning device, that steel rod may be configured to be precisely the same length as the diameter of the tower such that attaching the rod to the attachment points imparts little tension. Tension will then be generated in response to attempted deformation of the tower section.

[0060] Optionally, the tension in the tensioning arrangement may be adjusted at step 106.

[0061] The illustrated embodiments discussed above demonstrate various technical implementations of the inventive concept. However, it will be appreciated by the skilled person that other variations may be made apart from those detailed above and yet still fall within the scope of the appended claims. It will also be appreciated by the skilled person that the invention may relate to tower structures other than those for wind turbines.