CN215719235U - Wind turbine tower - Google Patents

Abstract

The utility model relates to a wind turbine tower (1) comprising a plurality of annular segments (10) axially aligned with each other, each of the annular segments (10) comprising a plurality of assembled sections (12) made of precast concrete, at least some of the segments of the tower comprising sections called sixth sections (12f) having no interlocking bosses made of concrete at the vertical interfaces (100) between the sections of the segments, the sixth sections (12f) having an elongation H/W of 1/8 to 1, where W is the width of the sixth section (12f) and H is the height of the sixth section (12 f).

Description

Wind turbine tower

Technical Field

The present invention relates to towers for holding wind turbines, and more particularly, but not exclusively, to onshore wind turbine towers.

Background

It has been proposed to manufacture wind turbine towers from precast concrete segments (sectors), also known as "shells", which are transported to a site where the tower is lifted and assembled there.

The segments may be provided with shear keys.

However, the presence of shear keys increases the complexity of the mould used to cast the segments and increases the risk of concrete spalling.

SUMMERY OF THE UTILITY MODEL

Tower comprising a section with a specific elongation without interlocking reliefs made of concrete on the lateral end faces

It was found that with sections without shear keys, the tower can also have the required mechanical resistance in case the sections are of an elongated shape.

Accordingly, the present invention relates to a wind turbine tower comprising a plurality of annular segments axially aligned with each other, the segments each comprising a plurality of assembled sections made of precast concrete, at least some of the segments of the tower having a section called the sixth section without interlocking bosses made of concrete at the vertical interfaces between the sections of the segments, the sixth section having an elongation H/W of 1/8 to 1, wherein W is the width of the sixth section and H is the height of the sixth section.

The use of segments without shear keys provides the following advantages: making the production of the sections simpler and reducing the risk of concrete spalling.

Preferably, at least some of the sixth segments have an elongation H/W of 1/6 to 3/4, more preferably 1/5 to 5/8.

At least half of the sections of the tower may have a sixth section without interlocking bosses made of concrete at the vertical interfaces between the sections of the sections. It is also possible to have all sections of the tower with a sixth section without interlocking embossments made of concrete at the interfaces between sections of the same section.

Preferably, the tower comprises post-tensioning tendons (post-tensioning tendons) for pre-stressing the segments.

The segments may have a constant height from 1m to 4m, preferably from 2m to 3 m.

Preferably the interfaces between segments of the same ring segment or the interfaces between adjacent ring segments are free of cement or grout.

Preferably, adjacent segments of the segments are assembled by a bolting system. Thus, the interface between segments of the same ring or between adjacent ring segments may be free of cement or grout, but may be in the presence of epoxy or polymer adhesives.

Preferably, each section consists of four segments.

These sixth sections on the lateral faces without interlocking reliefs made of concrete may be present:

-a lower part of the tower, which is cylindrical with a constant diameter, which part consists of a plurality of annular segments axially aligned with each other, each of these segments comprising an assembled plurality of said sixth segments,

-a middle portion, preferably frustoconical, having an enlarged base placed on top of the cylindrical portion, the middle portion being made up of a plurality of annular segments axially aligned with each other, each of these segments comprising an assembled plurality of said sixth segments,

-a cylindrical further portion placed on top of the intermediate portion, the further portion having a diameter smaller than that of the lower portion, the further portion consisting of a plurality of annular segments axially aligned with each other, each of the segments comprising an assembled plurality of said sixth segments.

The tower may or may not have a frustoconical portion at its base and may or may not have a shape in accordance with the detailed description below. Thus, the lower portion may be placed directly on the foundation (foundation) or may be placed on a first part of frustoconical shape as described below.

The tower has a resonant frequency. The design of the tower should ensure that the resonance frequency is kept at a sufficient distance from the mechanical excitation caused by the rotation of the rotor and the wind.

There is a need for a wind turbine tower that can be easily manufactured and assembled and that provides greater freedom in the design of the tower and operation of the wind turbine, while having increased stability and mechanical resistance.

Thus, a wind turbine tower may comprise:

a first portion having an enlarged base and preferably being frustoconical, consisting of a plurality of annular segments axially aligned with one another, each comprising a plurality of assembled sections made of precast concrete,

a second portion, cylindrical with a constant diameter, consisting of a plurality of annular sections axially aligned with each other, each comprising a plurality of assembled sections made of precast concrete, the lower end of said second portion being placed on the upper end of the first portion,

a third portion, preferably frustoconical, having an enlarged base placed on top of the second portion, consisting of a plurality of annular sections axially aligned with each other, each of these sections comprising a plurality of assembled sections made of precast concrete,

-a fourth portion, cylindrical and placed on top of the third portion, the fourth portion having a diameter smaller than the diameter of the second portion, the fourth portion consisting of a plurality of annular sections axially aligned with each other, each of the sections comprising a plurality of assembled sections made of precast concrete.

The tower can be made of a relatively large number of sections which are easy to manufacture and assemble, and has the required mechanical resistance and assembly accuracy. The segments can be made to a size that is easily transportable using conventional vehicles, thereby reducing transportation costs. As the diameter of the first section increases, the resonant frequency of the tower increases, thus giving more freedom in the design of the tower and in the operation of the turbine. The tower also obtains additional stability and mechanical resistance.

The tower may comprise post-tensioning tendons for pre-stressing the segments, and deviators secured to the lower end of the second part of the tower against which the tendons abut. These deviators allow the tendons to remain close to the inner diameter of the bottom section of the first section, yet avoid the tendons bearing directly against the section of concrete, thus avoiding possible damage.

The height of the first section may be 3% to 9% of the sum of the heights of the first to fourth sections of the tower. The outer diameter of the first portion at its base may be greater than 6m, for example in the range 6m to 15 m. The height of the first portion is, for example, in the range of 6m to 14 m. For example, the thickness e of a section of the first portion may be greater than 20 cm.

The height of the second section may be 40% to 70% of the sum of the heights of the first section to the fourth section of the tower. The outer diameter of the second portion may be greater than 6m and may for example be in the range of 6m to 14 m. The height of the second portion may be, for example, in the range of 50m to 140 m. The thickness of a section of the second portion may be, for example, greater than 20 cm.

The height of the third section may be 4% to 10% of the sum of the heights of the first to fourth sections of the tower. The height of the third portion may be, for example, in the range of 10m to 15 m.

The height of the fourth section may be 25% to 40% of the sum of the heights of the first to fourth sections of the tower. The outer diameter of the fourth portion may be greater than 4m and may for example be in the range of 4m to 6 m. The height of the fourth portion may be, for example, in the range of 30m to 80 m.

The sections of the second and fourth portions are generally cylindrical, while the sections of the first and third portions are generally frusto-conical.

Preferably, the second and fourth portions each comprise at least five consecutive segments formed from the same segment.

The tower may carry a post, preferably a metal post, on top of the end element fixed to the upper end of the fourth section. The mast carries a wind turbine.

All the segments and sections may have a constant height, preferably in the range of 2m to 3 m.

The adjacent segments may be assembled by clamping means, preferably by a bolted connection system. Some segments may include shear keys cast with the segments at interfaces with adjacent segments. These shear keys help to transfer vertical forces between the segments.

The tower may comprise a plurality of subsections, each subsection having 3 to 7 sections, the bottom section comprising a section with a window for engaging therein an arm of a hoist for erecting the tower, the hoist being known per se, e.g. Freyssinet Eolift^TMA lift of the type used to hoist the subsection and/or anchor the lift.

One of these sub-portions may correspond to the third portion plus the top section of the second portion. The other subsection may correspond to the first bottom section of the fourth section.

It is desirable to allow the tower to be erected using a hoist with arms engaged in windows of sections to hoist each subsection of the tower made up of a plurality of sections and/or to anchor the hoist on the tower being constructed in order to place a new subsection below subsections previously mounted on top of each other and lifted by the hoist.

At least some of the sections may include an area of increased thickness and a window therethrough for introducing therein an arm of a hoist used during erection of the tower.

Due to this region of increased thickness, the section provided with the window can be made as high as necessary at the same height as the other sections, with the required mechanical resistance. These sections may also hold a weight comparable to other sections and may be manipulated using the same tools as the other sections. The manufacture of the mould for casting the section is also made easier, since the shape of the section can remain the same as the other sections, except for the areas of increased thickness where the windows are provided.

The region of increased thickness may extend radially between an outwardly convex (e.g. cylindrical) outer surface and a flat inner surface. The flat surface may be used as a landing surface for a flat plate of a machine for erecting a tower. The flat surface improves the accuracy of positioning the machine relative to the tower.

Preferably, the inner surface is substantially perpendicular to the central axis of the window.

In a variant embodiment, the zone of increased thickness may extend radially between an outer surface convex towards the outside and an inner surface defined by projections on the inner surface of the segment.

The zone may have a substantially constant thickness e outside the region of increased thickness, and the region of increased thickness may have a maximum thickness e_maxWherein e is_max/e>2。

Preferably, the tower comprises sub-sections each having 3 to 7 sections, the bottom section of each sub-section comprising said section with a window.

Preferably, all sections of the section provided with windows have windows. Thus, when there are four sections per section, the section provided with the window has a total of four windows.

Preferably, the window is located in the centre of each section.

Preferably, the section comprising the section with the window comprises a jacket for a pre-stressed strip extending within the concrete of the section. In a variant embodiment, the temporary prestressed band may be external to the concrete.

Other considerations

The total height of the tower (excluding the wind turbine) may exceed 100 m.

The outer diameter of the tower may be in the range from 3m to 15 m.

The number of sections of the tower may range from 20 to 150.

The number of sections per section may range from 2 to 10, preferably 4 as described above. All sections may have the same number of sections, preferably 4.

The vertical joints at the interfaces of adjacent sections of a given section are angularly offset relative to the vertical joints of adjacent sections by approximately one-half of the angular extent of the sections.

When present, preferably the recess for receiving the shear key opens onto the intrados of the segment. This eases the assembly of the segments as the segments only need to be inserted by radial movement between the segments already in place. These recesses can be closed at the other radial end and therefore do not open onto the extrados of the segment. This helps to give the tower a smooth outer surface. The number of shear keys on the same side end face of the segment may range from 1 to 10. Preferably, the lateral end faces have three shear keys, two of which are close to the respective axial end faces of the segments and the third of which is substantially at mid-height.

Each side or axial end face of a segment may be flat, except for a corresponding shear key or recess (when present) for interlocking with an adjacent segment and/or for receiving a centering pin or component of a bolted connection system.

Preferably, the side end faces of the segments adjacent to the recess and the outer circumference are radially oriented.

In the case of a shear key, preferably, the shape of the portion of the side end face of a segment extending radially between the recess and the outer circumference (extrados) is substantially complementary to the shape of the portion of the side end face of an adjacent segment extending radially between the shear key and the outer circumference.

The side end faces of the segments may be provided with axial grooves. The groove may receive a resilient seal.

When a shear key is present, it is preferred that the shear key is oriented substantially perpendicular to a tangent of the extrados near the interface between the segments.

Each segment may include an axial rib projecting inwardly adjacent the end face of the segment, the rib preferably having a triangular cross-section. These ribs help the concrete flow and promote the expulsion of air bubbles that might otherwise remain at the lateral end faces of the segments during casting. These ribs face upward during the casting campaign. The clamping means may comprise a bolt extending through the respective rib, preferably at the bottom of the respective rib. Preferably, each bolt extends in a horizontal plane.

Preferably, the segments comprise sockets (sockets) for receiving the bolts of the clamping device, which sockets are advantageously integrated into the segments during casting of the segments.

Each segment may include at least one axial bore extending from each axial end of the segment along at least a portion of the height of the segment. Preferably, at least one of said axial holes opens into a recess formed on the inner surface of the segment. These holes are used to introduce a rod extending between two consecutive segments and help to fasten the segments to each other.

Preferably, the centering pin is engaged between the segments of two adjacent segments. Preferably, the centering pins are biconical. These centering pins help to accurately position the segments on top of each other and also help to transfer horizontal shear forces between the segments.

Drawings

Other features and advantages of the utility model will become apparent upon reading the following detailed description and upon reference to the drawings in which:

FIG. 1 shows an elevation of an example of a tower,

FIG. 2 is a partial enlarged view of the tower of FIG. 1,

figure 3 shows a section in perspective view,

figure 4 shows two adjacent sections before bolting,

figure 5A shows in perspective a section of the base section of the first part of frustoconical shape,

figure 5B shows the section of figure 5A in an axial view,

figure 5C shows the section of figure 5A in a side view,

figure 6A shows in perspective a section of the top section of the first part of frustoconical shape,

figure 6B shows the section of figure 6A in an axial view,

figure 6C shows the section of figure 6A in a side view,

figure 7A shows in perspective a section of a segment of a fourth portion of cylindrical shape,

figure 7B shows the section of figure 7A in a top view,

figure 7C shows the section of figure 7A in a side view,

figure 8A shows in perspective a section of a segment of the cylindrical second part,

figure 8B shows the section of figure 8A in an axial view,

figure 8C shows the section of figure 8A in a side view,

figure 9A shows in perspective a section with a window and an area of increased thickness,

FIG. 9B is an axial view of the segment of FIG. 9A,

FIG. 9C is a side view of the section of FIG. 9A,

figure 9D is a perspective view of the section of figure 9A in a different viewing direction,

FIG. 9E is a perspective view of the section of FIG. 9A in a different viewing direction,

figure 10A shows in perspective a variant embodiment of a section with windows and zones of increased thickness,

FIG. 10B is a top view of the section of FIG. 10A,

FIG. 10C is a side view of the section of FIG. 10A,

fig. 11A is an elevation of the tower showing the post-tensioning tendons in transparent form,

FIG. 11B shows the tower of FIG. 11A in a side view,

fig. 12 is a partial schematic view of the inside of the tower, showing the tensioning tendons,

fig. 13 is an enlarged view of fig. 12, showing the deviator,

figure 14A is a perspective view of a segment according to a variant embodiment,

figure 14B is an axial view of the section of figure 14A,

fig. 14C is a side view of the section of fig. 14A.

Detailed Description

Fig. 1 shows a wind turbine tower 1 manufactured according to the present invention.

The tower 1 comprises a plurality of sections 10 assembled vertically along the longitudinal axis Z of the tower.

The wind turbine T is fixed on top of the tower 1 by means of the annular end element 11.

Each segment 10 is annular and consists of a section 12, the section 12 preferably being arcuate (as shown in the figures) and made of precast concrete.

The number of sections 12 per section 10 may vary depending on the position of the section along the tower 1, in the embodiment described always four.

The tower 1 includes:

a first frustoconical portion 2 of base having an enlarged outer diameter D, consisting of a plurality of annular segments axially aligned with each other along the longitudinal axis Z of the tower,

a cylindrical second portion 3 of constant diameter C, consisting of a plurality of annular sectors axially aligned with each other, the lower end of which rests on the upper end of the first frustoconical portion 2,

a third frustoconical portion 4 having an enlarged base placed on top of the second portion 3, the third portion being composed of a plurality of annular segments axially aligned with one another,

a fourth portion 5 of cylindrical shape, placed on top of the third portion 4, the diameter B of which is smaller than the diameter C of the second portion 3, the fourth portion 5 being made up of a plurality of annular segments axially aligned with each other.

As shown more particularly in FIG. 2, the tower may be made up of subsections S1-S12, each of which is assembled on the ground and then passed through a tower such as Eolift from Fresysinet^TMIs placed below the previously installed sub-section.

Each subsection S1-S12 is formed from the same number of annular segments 10, for example, 6 segments as shown.

All sub-sections S1-S11, except S12, are provided with a bottom section 10a, each section of the bottom section 10a including a window 50. These windows 50 can be used for inserting the gripping arms of a machine for erecting the tower.

The varying thickness e of the sections may be selected within the range according to table 1 below for each sub-section S1 to S12, but preferably the thickness e of all sections of a given sub-section is the same.

TABLE 1

Outer diameters A, B, C and D may be selected within ranges according to Table 2 below. These values are given for a tower with a height of 120m to 200 m.

TABLE 2

As shown in fig. 3, each segment 12 is made of reinforced concrete and has a lateral end face 13 provided with a shear key 15 and a lateral end face 14 provided with a corresponding recess 16, respectively. These side faces are oriented vertically in the tower.

Each segment 12 comprises a projection 17 projecting inwardly in the vicinity of the side end face 14 and a projection 18 projecting inwardly in the vicinity of the side end face 13, respectively.

The recesses 16 open onto the intrados of the segments and extend along a portion of the adjacent protrusion 17.

Preferably, each segment 12 has three shear keys 15.

The base 20 of each recess 16 may have a shape substantially complementary to the shape of the most radially outward end 21 of the shear key 15.

Preferably, the segments 12 are assembled by means of a clamping device, such as a bolted connection system, comprising a bolt 30 as shown in fig. 4 and an associated socket 31 which is internally threaded and into which the bolt can be screwed.

The bolts 30 extend through holes 32 of the segment 12, while the sockets 31 are integrated into the segment 12 during casting of the segment.

The aperture 32 opens onto the rear side 34 of the projection 18 as shown in fig. 4.

As shown in fig. 3, there may be two bolting systems 30, 31 per interface between two adjacent sections 12 of the same section 10. The bolts 30 are oriented substantially horizontally in the tower 1.

As shown in fig. 4, the shear key 15 and the recess 16 help position one segment relative to the other to complete the joint.

At least some of the segments 12 may include axial bores 40 that open onto the axial end faces 35 of the segments 12. These axial end faces are oriented horizontally in the tower. Some recesses 41 may be formed on the intrados of the segments 12 to provide access to the ends of at least some of the holes 40 for fastening rods.

These holes 40 are used to receive rods for assembling adjacent sections.

The end face of the section 12 may be provided with a recess 45 for receiving a double conical centring pin. These recesses 45 may be present on the lateral end faces as well as on the axial end faces.

The segments 12 are of relatively small size and are preferably manufactured in a factory in moulds which are moved between different work stations.

Preferably, each mould for casting the segment is machined with a relatively high degree of precision, so that the manufacturing tolerances on at least some of the surfaces of the segment are within a relatively low value, which is less than 5mm, better less than 2mm, even better less than 1mm or less than 0.5 mm.

In particular, the manufacturing tolerances of the side end faces 13 and 14 and the axial end face 35 are better than this value.

All segments 12 may have a constant height H, for example 2.45m, i.e. about 2.5 m.

The section of the segment 10 at the base of the first part 2 may have the geometry shown in fig. 5A to 5C. In these figures, these sections are labeled 12a, and are referred to hereinafter as first sections 12 a.

The width W of the first section 12a may be equal to about 9.5m, giving an elongation H/W of about 0.26.

The maximum outer radius may be about 6.75 m. The first section 12a has a conical surface on the extrados and parallel top and bottom surfaces 35.

The section of the segment 10 at the top of the first part 2 may have the geometry shown in fig. 6A to 6C. In these figures, these sections are labeled 12b, and are referred to hereinafter as second sections 12 b.

The width W of these second sections may be equal to about 7.8m, giving an elongation H/W of about 0.32. The maximum outer radius may be about 5.5 m.

The segments of the segments 10 of the fourth portion 5 may have the geometry shown in fig. 7A to 7C. In these figures, these sections are labeled 12c, and are referred to hereinafter as third sections 12 c.

The width W of these third sections may be equal to about 4.6m, giving an elongation H/W of about 0.54. The outer radius R may be about 3.25 m.

The segments of the segments 10 of the second part 3 may have the geometry shown in fig. 8A to 8C. In these figures, these sections are labeled 12d, and are referred to hereinafter as fourth sections 12 d.

The width W of these fourth segments may be equal to about 7.8m, giving an elongation H/W of about 0.32. The outer radius may be about 5.5 m.

Fig. 9A to 9E show a section, designated 12E, hereinafter referred to as a fifth section 12E, which is provided with a window 50 in a central region 80, the thickness of the central region 80 being greater than the thickness E of regions 81 located to the left and right of the central region 80. In these figures, the region 81 extends between the two concentric cylindrical surfaces of the fifth segment (corresponding to the intrados and extrados of the segment). The region 80 is defined between an outer cylindrical surface of the extrados and a plane 82 extending substantially perpendicular to the central axis of the window 50. This plane 82 may be used as a landing surface for the flat plate of the hoist used to erect the tower.

Maximum thickness e of region 80_maxFor example about 360mm, and the thickness e of the region 81, for example about 210mm, so that the ratio e_maxThe value of/e is about 1.7.

The area 80 extends over the entire height of the fifth section 12e and the area 80 presents additional resistance to load when the respective sub-section is lifted to build the tower and/or when the machine is anchored in the window as described above.

The fifth section 12e may include an inner jacket 85 extending between the two sides of the section for introducing therein a pre-stressed (post-tensioned) belt spiraling within the section, which also helps to carry weight loads during lifting. The band extends below the window. A recess may be provided in one section, the recess having two openings for passing the steel tendons (wires), the anchoring means being mounted and the recess being stressed by means of a hydraulic jack. When the prestressed steel tendons are installed outside the concrete, the tendons can be anchored with Freyssinet (so-called X-anchor) on the outer surface of the sections.

Fig. 10A to 10C show a modified embodiment of the fifth section 12 e. In this embodiment, the areas 80 with increased thickness have different shapes. Region 80 is formed by a central projection that projects from the intrados of the segment and extends around window 50.

The projection 80 may have a flat surface 86 with the window 50 opened thereon, the flat surface 86 being connected to the cylindrical surface of the intrados surface by a bevel 87, so that the projection has a tapered frustoconical shape.

In this embodiment, the maximum thickness e of the region 80_maxFor example about 500mm, so that the ratio e_maxThe value of/e is about 2.4.

The tower 1 comprises axial post-tensioning tendons 90, some of which are transparently visible in fig. 11A and 11B.

These tendons 90 are anchored at one end to the annular top element 11 by means of an anchor and at the other end to the foundation of the tower. These tendons are only tensioned after erection of the tower is complete and extend outside the concrete wall of the section 12 in the inner space of the tower 1.

In order to keep the tendons 90 as close as possible to the inner surface of the wall, deviators 93 as shown in fig. 12 and 13 can be used to avoid the tendons 90 directly abutting the concrete surface of the segment.

Each deviator 90 may include a socket 94 secured to the inner surface of the respective segment 12 by a bolt 95 and a bracket 96 having a semi-circular cross-section into which the tendon 90 is engaged.

As shown, the deviator 90 may be fixed near the bottom edge of the bottom section of the second portion 3.

The tower 1 may be constructed as follows.

At the tower assembly site, sections 12 are assembled to form sections 10. May be performed using a rotatable platform comprising a fixed base and a rotatable table. The rotatable table may comprise a circular track and at least one radially extending arm for positioning one segment prior to assembling it to other segments which are subsequently placed on the rotatable table. The rotatable table may comprise parallel beams forming tracks for unloading the assembled segments from the rotatable table. The track may be aligned with an external track for transporting the sections to a lifting device or other apparatus for assembling the sections by rotating the platform.

A coating of polymer adhesive may be applied over the shear keys prior to assembly of the segments 12 to lubricate the interfaces and improve force transfer. No cement slurry is introduced at the interface between the sections.

Preferably, as shown in fig. 1 and 2, the sections 10 are angularly offset such that the vertical joint 100 between sections of one section is substantially midway between sections of an adjacent section 10 and is not aligned with the vertical joint of an adjacent section.

Due to the precision of manufacturing the segments 12, the axial end faces 35 of the segments 12 of the same segment 10 (i.e., the horizontal joint of the segment) are not significantly misaligned.

Some tendons can be used during erection of the tower and anchored in the intermediate joints.

As shown in fig. 14A-14C, at least some of the segments are not provided with shear keys 15 and corresponding recesses 16 on their side faces 114. Although the shear key 15 provides additional mechanical resistance to the tower 1, it makes the sections 12 more difficult to mould as care should be taken to avoid concrete spalling.

The section according to fig. 14A to 14C, referred to as sixth section 12f, is easier to mould and due to its elongation the tower 1 may still have the required mechanical resistance.

The sixth segment 12f may have all of the features described above except for the presence of the shear key 15 and corresponding recess 16 on its side faces 13 and 14 (now labeled 114).

The side end faces 114 may be flat, except for recesses for receiving double-tapered centering pins or elements of the clamping system.

The present invention is not limited to the embodiments disclosed, and various modifications may be made to the embodiments without departing from the scope of the present invention.

The segments may be ring-shaped other than circular, for example polygonal, in particular hexagonal.

Claims (10)

1. A wind turbine tower (1), characterized in that said tower comprises a plurality of annular segments (10) axially aligned with each other, each of these annular segments (10) comprising a plurality of assembled segments (12) made of precast concrete, at least some of the annular segments of said tower comprising segments called sixth segments (12f) having no interlocking reliefs made of concrete at the vertical interfaces (100) between the segments of these annular segments, the elongation H/W of these sixth segments (12f) being 1/8 to 1, where W is the width of said sixth segments (12f) and H is the height of said sixth segments (12 f).

2. The tower of claim 1, in which at least some of the sixth sections (12f) have an elongation H/W of 1/6 to 3/4.

3. The tower of claim 1, in which at least some of the sixth sections (12f) have an elongation H/W of 1/5 to 5/8.

4. Tower in accordance with claim 1, characterized in that at least half of the annular segments of the tower comprise the sixth segments (12f) without interlocking bosses made of concrete at the interfaces (100) between the segments of annular segments (10).

5. A tower according to claim 1, characterized in that the tower comprises post-tensioning tendons (90) for pre-stressing the annular segments.

6. A tower as claimed in claim 1, characterised in that said sections (12) have a constant height in the range of 2 to 3 m.

7. A tower according to claim 1, characterised in that adjacent segments (12) of one and the same annular segment are assembled by a bolting system, each segment comprising an axial rib (17, 18) protruding inwards near an end face of the segment, the axial ribs having a triangular cross-section, the bolting system having bolts extending through the respective axial rib, the segments comprising sockets for receiving the bolts.

8. Tower in accordance with claim 1, characterized in that each ring segment (10) consists of four segments (12).

9. Tower in accordance with claim 1, characterized in that the interface between sections (12) of one and the same ring segment (10) or the interface between adjacent ring segments (10) is free of cement or grout.

10. The tower according to claim 1, wherein the sixth section (12f) without interlocking bosses made of concrete is present:

-a lower portion (3) of said tower, said lower portion (3) being cylindrical with a constant diameter (C), the lower portion (3) being composed of a plurality of annular segments axially aligned with each other, each comprising a plurality of assembled said sixth segments (12f),

-an intermediate portion (4), said intermediate portion (4) having an enlarged base placed on top of the cylindrical lower portion (3), the intermediate portion (4) consisting of a plurality of annular segments axially aligned with each other, each comprising a plurality of assembled said sixth segments (12f),

-a cylindrical further portion (5), said further portion (5) being placed on top of said intermediate portion (4), said further portion (5) having a diameter (B) smaller than the diameter (C) of said lower portion, and being composed of a plurality of annular segments axially aligned with each other, each comprising a plurality of assembled said sixth segments (12 f).

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