EP3350438A1

EP3350438A1 - Tower for a wind turbine

Info

Publication number: EP3350438A1
Application number: EP16762821.3A
Authority: EP
Inventors: Stephan Drewes; Mark Hirt; Lothar Patberg; Adrian Paton; Patrick TLAUKA
Original assignee: ThyssenKrupp Steel Europe AG; ThyssenKrupp AG
Current assignee: ThyssenKrupp Steel Europe AG; ThyssenKrupp AG
Priority date: 2015-09-16
Filing date: 2016-09-08
Publication date: 2018-07-25
Also published as: CN108026899A; WO2017045993A1; CN108026899B; US20180266396A1; US10330085B2; CA2996021C; CA2996021A1; DE102015115634A1

Abstract

The invention relates inter alia to a tower for a wind turbine, with an upper tower portion (2) and a lower tower portion (4, 4'), wherein the upper tower portion (2) comprises a tubular tower (6), wherein the lower tower portion (4, 4') comprises a lattice tower (8, 8'). The object of allowing improved ergonomics and work safety and making it possible to obtain a structural design with optimized forces is achieved by the lower tower portion (4, 4') comprising a central tube (10, 10') arranged centrally within the lattice tower (8, 8'), and by the central tube (10,') having a smaller diameter, at least in certain portions, than at least part of the tubular tower of the upper tower portion.

Description

Tower for a wind turbine

The invention relates to a tower for a wind turbine with an upper

A tower section and having a lower tower section, wherein the upper tower section comprises a tube tower, wherein the lower tower section comprises a lattice mast. The invention also relates to a wind turbine.

The trend, especially in wind turbines or wind turbines, especially in the onshore sector, is towards ever higher hub heights (the height at which the hub of the wind rotor is above the terrain surface). In the meantime, heights beyond 100m are desirable. This should be exploited higher and more constant wind speeds and thus the efficiency of

Wind power plant can be improved, especially in low wind areas.

Higher towers with larger and more powerful generators or rotors, however, have the consequence that the wall thicknesses and the diameter of the

Tower segments must be larger in order to the resulting larger structural mechanical requirements such as stiffness, buckling and security

To meet fatigue behavior.

However, it is problematic from a logistical and transport point of view, that the transport of corresponding tower segments due to restrictions, e.g.

Bridge clearance heights, is no longer possible if the dimensions of the individual tower segments increase due to higher towers.

For this reason, mentioned in the prior art, generic towers for wind turbines are proposed. For example, describes the WO 2005/021897 AI a tower with an upper tubular tower section and a lower, designed as a lattice tower tower section.

However, it has been shown that in such constructions significant disadvantages in terms of ergonomics and safety, especially since the

Accessibility of individual parts of the tower by the grid construction in the lower

Tower section can be significantly affected. In addition, it has been shown that in such a hybrid construction, the construction of the lattice mast can be complicated, since this must withstand high forces and must be designed accordingly. This can lead to high costs and high costs.

Against this background, the invention is based on the object

generic tower for wind turbines and a wind turbine indicate which or which on the one hand allow improved ergonomics and safety and on the other hand enable a power-optimized design.

The object is achieved according to a first teaching of the present invention in a generic tower for a wind turbine, characterized in that the lower tower section comprises a centrally disposed within the lattice mast center tube, wherein the center tube at least partially has a smaller diameter than at least a portion of the tube tower of the upper tower section.

Because the lower tower section comprises a lattice mast, high hub heights beyond 100 m can initially be achieved. At the same time, however, a central tube is provided within the lattice mast, which at least

partially smaller diameter than at least part of the tubular tower of the upper tower section. This will be the benefits of a

continuous tube tower achieved that in particular easier accessibility of the wind turbine is possible through this center pipe. However, due to the smaller diameter, the disadvantages of a conventional integrated system are targeted Pipe tower avoided that the diameter of the tube tower segments in the lower area at such tower heights normally difficult transport. Rather, it was recognized that already a central tube whose diameter is at least

is smaller than at least part of the tubular tower, is sufficient to achieve the necessary ergonomics and at the same time to optimize the power flow in the tower. As a result, the invention combines the advantages of a grid construction and a tubular tower in the lower tower section, without, however, having to accept the respective disadvantages.

The central tube of the lower tower section preferably has a smaller diameter over substantially its entire length than at least one part of the tubular tower, for example as at least the lower part or also as the entire tubular tower.

The central tube of the lower tower section is preferably in extension of the

Pipe tower of the upper tower section arranged. The longitudinal axes of the central tube and the tubular tower are preferably on each other.

The tower is preferably designed for a hub height of more than 100m. At such heights, the properties of a tower according to the invention, that is to say an improved ergonomics and an improved force flow, are particularly advantageous.

The upper tower section having the tubular tower is preferably free of a lattice mast surrounding the tubular tower. It has been found that sufficient stability can be achieved in the upper tower section without an additional grid structure surrounding the tubular tower.

The central tube is designed in particular as a hollow profile. The center tube is preferably built in sheet metal construction. This allows optimum adaptation and a cost-effective and lightweight compared to, for example, castings. Individual parts of the central tube can in particular be welded together. According to one embodiment of the tower according to the invention, the tower further comprises a transition piece between the upper and the lower tower section and preferably the tube tower of the upper tower section and the central tube of the lower tower section are connected to each other via the transition piece. By providing a transition piece, a further optimized and

load-compatible transition between the upper tower section, in particular the tube tower of the upper tower section, and the lower tower section, in particular the central tube of the lower tower section can be achieved. The transition piece can initially serve to connect the pipe tower and center pipe. At the same time, the transition piece can also serve to connect the lattice mast to the tubular tower of the upper tower section. As a result, the transition piece can therefore also for

Connecting the center tube to the lattice mast serve. Thus, the transition piece preferably has connection areas for the tubular tower, the central tube and the lattice mast. The transition piece thus represents in particular a kind of central node.

It is conceivable to form the transition piece, or parts thereof, integrally with the tubular tower, the central tube and / or the transition piece. This is preferred

Transition piece, however, designed as a separate component, which is connected to the other elements, in particular welded and / or screwed.

Also, the transition piece is preferably built in sheet metal construction. As already

executed, this allows on the one hand a flexible production and compared to for example castings cost-effective and lightweight construction. Individual sheet metal parts can then be joined to the transition piece by welding.

According to a further embodiment of the tower according to the invention, the central tube of the lower tower section is connected at its lower end to a foundation of the tower and at its upper end to the transition piece. Here is achieved in a particularly simple manner that the center tube to an improved power flow and contribute to the relief of the lattice mast. In addition, through the central tube accessibility for personnel from the ground up to the upper tower section can be simplified.

According to a further embodiment of the tower according to the invention, the central tube of the lower tower section for receiving forces from the upper tower section, in particular for receiving torsional forces, is formed. As already stated, an optimized force flow or an optimized load distribution can be achieved hereby, since the center tube assumes a structural support component and in particular the lattice mast, in particular its corner stems, is relieved of load. Which forces can take up which height the central tube can be adjusted in particular by the wall thickness and the diameter.

According to a further embodiment of the tower according to the invention, the

Lattice mast of the lower tower section at least three, preferably exactly three corner handles. It has been found that the design of the lattice mast with, in particular, three corner stems enables a simple and scalable construction by means of standard profiles with simultaneously high stability. In the case of three corner stems, the base area or cross-sectional area of the lattice mast correspondingly forms a triangular area. However, the lattice mast can also be designed with a higher number of corner stems, for example, four or five corner stems can be provided. The base area or cross-sectional area is then a corresponding polygon. The number of corner handles can be made particularly dependent on the hub height, the power and the weight to be carried by the tower.

The corner handles consist for example of individual Eckstielsegmenten, for example, tubular hollow sections. For example, several hollow profiles can form a corner post. The individual hollow profiles can be connected to one another in their end regions, for example by means of screws. Run between the corner stems preferably transverse and / or diagonal struts, which connect adjacent corner stems with each other.

According to a further embodiment of the tower according to the invention, the diameter of the central tube is at least partially at least Im, preferably at least 1.5m, and / or at most 4m, preferably at most 3.5m, more preferably at most 1.8m.

If a smaller diameter of the center tube (for example 1.5m to 1.8m) is chosen, the minimum ergonomic and occupational safety requirements can be met. On the other hand, if larger diameters (for example 1.8 to 3.5 m) are selected, the middle tube can absorb forces (in particular torsional forces) in a particularly effective manner and relieve the load on the lattice mast. In addition, it is then possible that the central tube can accommodate even larger components, such as a transformer unit.

According to a further embodiment of the tower according to the invention, the lower tower section is formed free of load-bearing connections between the lattice mast and the central tube. This is especially true for connections between corner posts of the lattice mast and the center tube. That is, there are either no connections between the central tube on the one hand and the lattice tower tower (or its Eckstielen) on the other hand provided or at least no load-bearing connections. That is, in the latter case, but that, for example, non-supporting struts or webs can be provided. These can further increase the accessibility of the tower for staff

improve.

According to a further embodiment of the tower according to the invention, the lower tower section in or on the central tube comprises access means, in particular an elevator, a ladder and / or mounting platforms, and / or electrical components, in particular lines and / or electrical components. The central tube can be used in particular as a dwelling or enclosure for such facilities or Serve components. In this way, a simple and secure accessibility for personnel and / or secure housing for corresponding components is achieved practically independent of the design of the tower in the lower tower section, so in particular even if a grid structure is provided.

According to a further embodiment of the tower according to the invention, the central tube comprises one or more passages, wherein in particular at least part of the passages are connected via non-load-bearing connections to the lattice mast, in particular corner posts of the lattice mast. By providing the walkways, the ergonomics and safety of the tower is further improved, as personnel can reach about the assembly or service work through the center tube to a certain height and then can leave through the passages the center tube to reach more area of the tower. For example, a first pass near the ground is provided in the central tube. Further passages may, for example, be arranged at predetermined heights at a distance from one another. At the height of the respective passages, in any case, mounting baskets can in some cases also be provided on the central tube and / or on the lattice mast.

According to a further embodiment of the tower according to the invention, the transition of the diameter of the tube tower of the upper tower section to the central tube of the lower tower section in a transition region is continuous and / or stepped.

The transition region can be formed for example by the central tube. The transition region is then preferably at the upper end of the central tube. However, it is also conceivable that the transition region is at least partially formed by the transition piece. Preferably, however, the transition piece in

Essentially the diameter of the tube tower of the upper tower section. For example, the central tube has a substantially constant diameter at the upper end, so that the transition takes place in steps. For example, at the upper end, the central tube has a conical section with a continuously increasing diameter in the direction of the upper tower section. The diameter increases, for example, up to the diameter of the

Tube tower or transition piece.

According to a further embodiment of the tower according to the invention, the lower tower section has a height of at least 60m, preferably at least 80m, and / or a height of at most 140m. A preferred range of the height of the lower tower section is, for example, 80m to 100m. However, to achieve high hub heights of about 200 m, a preferred range of 120 m to 140 m may be provided for the height of the lower tower section. Location and

Depending on the technology, even larger heights are possible. It has been shown that in lattice towers in this height range, the described construction with a

Middle tube advantageous in terms of increased ergonomics and safety and a possible relief of the lattice tower are.

According to a further embodiment of the tower according to the invention, the

Lattice mast of the lower tower section grid elements which are at least partially connected by connecting elements, in particular screws, preferably HV screws or bolts, preferably locking ring bolts. However, it is also the use of other fasteners for producing positive

Connections conceivable. Such grid elements are, for example, corner handles,

Cross struts and / or diagonal struts. Through the use of HV screws, that is, high-strength, planned prestressable screw connections, in particular individually to be certified clamp connections (for example, lock bolt) can be avoided. This is made possible by the fact that the central tube during assembly and during subsequent inspections improved possibilities for the

Accessibility offers. According to a further embodiment of the tower according to the invention, the central tube is at least partially spirally welded and / or longitudinally welded. Spirally welded pipes can be economically produced by a quasi-continuous process. In longitudinally welded pipes especially larger wall thicknesses and diameters can be processed and high stability can be achieved.

According to a further embodiment of the tower according to the invention, the tubular tower of the upper tower section is formed in a transversely oriented construction. Since the tube tower begins only in the upper tower section and does not have to extend from the ground to the total height of the tower, the tube tower can be a correspondingly small

Have diameter and the individual tube tower segments can in

transverse-oriented design can be provided without this would affect the transport. A transverse-oriented design is to be understood in particular as meaning that the tower is constructed of elements running transversely to the tower path (longitudinal direction).

According to a further teaching of the present invention, the object mentioned above is also achieved by a wind turbine with a tower according to the invention. A wind turbine includes in particular a mounted on the tower

Engine house (also called nacelle) and a rotor with rotor blades. For this purpose, the tubular tower of the upper tower section at the upper ends of an adapted

Have attachment area.

With regard to further embodiments and advantages of the wind turbine, reference is made to the description of the tower according to the invention.

In addition, the invention will be explained in more detail with reference to embodiments in conjunction with the drawings. The drawing shows in Fig. La a longitudinal section of a first embodiment

tower according to the invention;

Fig. Lb is a cross-section of the embodiment of Fig. La;

2a-c different embodiments of the transition region;

Fig. 3a is a perspective view of part of another

Embodiment of a tower according to the invention; and

Fig. 3b, c enlarged partial sections of Fig. 3a.

Fig. La shows a longitudinal section of a first embodiment of a

Tower according to the invention, while Fig. lb is a cross section of the

Embodiment of Fig. La shows.

The tower 1 is part of a wind turbine with gondola and rotor (not shown). The tower 1 has an upper tower section 2 and a lower tower section 4. The upper tower section 2 comprises a tubular tower 6. The lower tower section 4 comprises a lattice mast 8 and a central tube 10, which is centrally located within the

Grid mast 8 is arranged. The central tube 10 has a smaller diameter throughout than the tube tower 6 of the upper tower section 2. The tower 1 further comprises a transition piece 12, via which the lattice mast 8, the central tube 10 and the tube tower 6 are interconnected. The central tube 10 is connected at its lower end to a foundation (not shown) of the tower 1 and at its upper end to the transition piece 12.

The central tube 10 of the lower tower section 4 is formed due to the wall thickness and the diameter for receiving forces from the upper tower section 2. As a result, the central tube 10 relieves the lattice mast 8. In addition, the central tube 8 in this case represents a dwelling for a ladder.

The lattice mast 8 of the lower tower section 4 here has three corner posts, two of which corner posts 14 can be seen in Fig. La. The lattice mast also has transverse struts and / or diagonal struts 16, which are arranged between the corner posts 14. The lower tower section 4 is formed free of load-bearing connections between the lattice mast 8 and the central tube 10.

Fig. 2a-c shows various variants of the transition region from the central tube 10 to the transition piece 12. Fig. 2a shows as already shown in Fig. La a

exclusively stepped transition, Fig. 2b shows a combined

Stepped and continuous transition and Fig. 2c finally shows a continuous transition without step. For the (partially) continuous transition (Figure 2b, c), the central tube 10 has an increasing diameter at its upper end.

Fig. 3a shows a perspective view of part of another

Embodiment of a tower according to the invention. The structure essentially corresponds to that already described in connection with FIG. In contrast to this, the central tube 10 'of the tower shown in detail in FIG. 3a has a plurality of passages 18', the passages being connected in part via non-load-bearing connecting webs 20 'to the lattice mast 8' and here in particular to the corner pillars 14 'of the lattice mast 8' , In addition, mounting platforms 22 'are provided both on the central tube 10' and on the corner posts 14 '.

3b shows an enlarged (semi-transparent) view of the access passage 18 'in the lower region of the central tube 10'. It will be appreciated that a conductor 24 'and an electrical component, eg, a service lift 26' can be accommodated in the central tube 10 '. Fig. 3c also shows an enlarged view of the mounting platform 22 'at the corner post 14'. It will be appreciated that HV screw connections can be used to connect the individual struts 16 'of the lattice mast 8' to the corner stalk 14 '. Due to the central tube 10 'and the connecting webs 20', these connection areas can be achieved with high ergonomics and occupational safety.

Claims

P a n t a n s p r e c h e

Tower for a wind turbine,

with an upper tower section (2) and

with a lower tower section (4, 4 '),

the upper tower section (2) comprising a tubular tower (6),

wherein the lower tower section (4, 4 ') comprises a lattice mast (8, 8'), wherein the lower tower section (4, 4 ') comprises a central tube (10, 10') arranged centrally within the lattice mast (8, 8 ') , and

wherein the central tube (10, 10 ') at least partially has a smaller diameter than at least part of the tubular tower of the upper

Tower section.

Tower according to claim 1,

wherein the tower (1, 1 ') further comprises a transition piece (12) between the upper and the lower tower section (2, 4, 4') and preferably the tubular tower (6) of the upper tower section (2) and the central tube (10, 10 ') of the lower tower section (4, 4') via the transition piece (12) are interconnected.

Tower according to claim 2,

wherein the central tube (10, 10 ') of the lower tower section (4, 4') is connected at its lower end to a foundation of the tower (1, 1 ') and at its upper end to the transition piece (12).

Tower according to one of claims 1 to 3,

wherein the central tube (10, 10 ') of the lower tower section (4, 4') for receiving forces from the upper tower section (2) is formed.

5. Tower according to one of claims 1 to 4,

wherein the lattice mast (8, 8 ') of the lower tower section (4, 4') has at least three, preferably exactly three corner stems (14, 14 ').

6. Tower according to one of claims 1 to 5,

wherein the diameter of the central tube (10, 10 ') at least in sections at least Im, preferably at least 1.5m, and / or at most 4m, preferably at most 3.5m, more preferably at most 1.8m.

7. Tower according to one of claims 1 to 6,

wherein the lower tower section (4, 4 ') is formed free of load-bearing connections between the lattice mast (8, 8') and the central tube (10, 10 ').

8. Tower according to one of claims 1 to 7,

wherein the lower tower section (4, 4 ') in or on the central tube (10, 10') access means, in particular an elevator, a ladder (24 ') and / or mounting platforms (18'), and / or electrical components (26 '; )

in particular lines and / or electrical components.

9. Tower according to one of claims 1 to 8,

wherein the central tube (10, 10 ') comprises one or more passageways (18'), wherein in particular at least a portion of the passageways (18 ') via non-load-bearing connections (20') with the lattice mast (8, 8 '), in particular corner stems ( 14, 14 ') of the lattice mast (8, 8') are connected.

10. Tower according to one of claims 1 to 9,

wherein the transition of the diameter of the tube tower (6) of the upper tower section (2) to the central tube (10, 10 ') of the lower tower section (4, 4') in a transition region is continuous and / or stepped.

11. Tower according to one of claims 1 to 10,

wherein the lower tower section (4, 4 ') has a height of at least 60m, preferably at least 80m and / or a height of at most 140m.

12. Tower according to one of claims 1 to 11,

wherein the lattice mast (8, 8 ') of the lower tower section (4, 4') has grating elements (14, 14 ', 16, 16') which at least partially through

Connecting elements, in particular screws, preferably HV screws, or bolts, preferably lockbolts, are interconnected.

13. Tower according to one of claims 1 to 12,

wherein the central tube (10, 10 ') is at least partially spirally welded and / or longitudinally welded.

14. Tower according to one of claims 1 to 13,

wherein the tube tower (6) of the upper tower section (2) is formed in a transversely oriented construction.

15. Wind power plant with a tower according to one of claims 1 to 1