DE102016014799B4 - Tower construction for a wind turbine - Google Patents

Abstract

Tower construction for a wind turbine inland (onshore) with horizontal rotor axis for use of the lower part of the tropospheric wind up to 400 m height with large rotors and drive power, where the tower construction consists of at least three columns (3, 4) whose center lines are at hub height wherein one of the columns (3) of the tower construction (1) for receiving the rotor is arranged vertically and this vertical column (3) by at least two spread columns (4) against the rotor force (5) is supported and these pressure columns (4) including the stabilizers and struts (8) with the vertical column (3) as a unitary tower construction (1) are rotatable on a circular path (11), characterized in that the vertical column (3) in the center of the circular path (11), via a support bearing (13) on the foundation (14) at the same time receives tensile or compressive loads and the pressure columns (4) with their support and chassis (12 ) on the circular path (11) and thus rotatable about the vertical column (3) are rotatable, or that both the vertical column (3) and the pressure columns (4) are equipped with support and chassis (12), together on the circular path (11) move and the occurring tensile or compressive loads of the unitary tower construction (1) in the center of the circular path (11) in a support bearing (13) are transmitted.

Description

The invention relates to the tower construction for a wind turbine to use the lower part of the tropospheric wind to 400 m inland (onshore) with the associated possibilities of construction, equipping and operation, which thus leads to a much higher range of energy yield and cheaper production costs.

State of the art

The current status of modern wind turbines (WEA) has been a leader in Germany after 35 years of development and will be extensively analyzed and necessary conclusions for the future in the "WHITEPAPER" published by the German Wind Energy Association in Germany under the heading "The limits of growth are not yet reached "questioned in issue no. 06/2015. With regard to the size of the wind turbine, it states that the average hub height of the installations installed inland today is already 135 meters and will continue to grow in the future (pages 5 and 6).

The Scandinavian wind industry (www.elforsk.se, Stockholm) clearly stated in the "Elforsk rapport 10:48" that larger hub heights are not economically justifiable with the previous tower design (page 45). In issue 11/2013 of the magazine "RENEWABLE ENERGIES", Prof. Dr. Ing. Stefan Emeis, Institute for Meteorology and Climate Research in Garmisch-Partenkirchen (KIT) called on German engineers to use the wind at higher altitudes.

In the column "Conclusions" of the journal "RENEWABLE ENERGIES", issue February 2015, Prof. Dr. med. Horst Bendix on page 74 entitled "Wind harvest at 300 meters altitude" - "High altitude wind - an opportunity for inland wind energy" emphasizes that wind turbines contribute faster and more effectively to master the energy transition, if not only the lower areas, the Prandtl layer and the Ekman layer, but the lower tropospheric layers, so the heights starting from 200 m are used for the energy conversion.

With the evaluation of the development of the WEA on the market and the study of the existing protective rights, it becomes clear that larger hub heights of 150 and 160 m were achieved, in which higher material qualities, larger dimensions and extension of the base areas or modified designs of the first tower parts over the stand area are realized , but not the previously typical bending stress of the tower on the full circle of the wind was changed to the clamping point on the foundation.

It can be seen that an increase in the hub height up to and over 200 m with further increase in the rotor diameter and the drive power without innovation of a fundamental nature will not be achieved because missing logistical details, technically and economically suitable lifting equipment for the construction, equipment and the Service life required and later dismantling prevent this.

Also in the publication DE 20 2015 005 040 U1 is a tower construction with several evenly distributed and inclined to each other tower columns known, the total compared to solid towers by the fundamentally changed tower load of at least three splayed columns allows a significant reduction in the use of materials, which brought despite the benefits of no step to Höhenwindnutzung.

The spreading of the columns leads during the gondola rotation with very long and elastic rotor blades to an unwanted approach or in extreme cases to a collision between the rotor blade tip and tower column. To avoid such collisions, plant operation in the lee forces itself: 'Wind from behind'. Although this mode of operation has been reused in modern offshore installations, it is not popular for onshore installations because of the tower backlog. Other proportions between spreading and sheet deformation could lead to improved sheet freedom.

From the publication EP 2 065 593 A1 Furthermore, a tower construction is known whose tower is supported at a certain height above its footprint around by a comprehensive ring with multiple pairs of rollers and out to reduce the bending stress in the tower and to make the tower to a possible rotation about its base. The type and possible height of the tower support is not well suited to reach large hub heights and to create tall plant towers with favorable intrinsic mass ratios.

The publication DE 20 2009 009 517 U1 has a hollow cylinder as a wind turbine tower, which is inserted deep in the base and rotatably designed the tower incl. The nacelle to rotate the rotor in the wind can. This design is structurally not designed so that the bending stress of the tower can be reduced and so the tower can be performed with less material.

Object of the invention

It is an object of the invention to liberate the tower construction by applying at least three splayed columns, the centerlines intersect at hub height, bending stress from the rotor force and from the outer edge of the wind-facing column to the largest occurring rotor blade deformation during the Vorbeidrehens of the sheet a column with certainty to avoid a collision.

This object is achieved in that the windward front pillar of the plant to ensure freedom from the sheet is placed vertically.

The vertical column of the rotatable tower is supported at hub height against the summary rotor force by at least two splayed columns. These two columns thus predominantly absorb pressure forces.

So that the vertical column remains the front in each wind direction, the entire tower construction is rotated with the change of wind direction on a circular path in the wind. The center of this circular path is located in the invention according to variant 1 in the axis of rotation of the vertical column and according to variant 2 at the intersection of the medians of the base of all columns.

Variant 2 leads compared to variant 1 to the advantage that the circular path length and the required footprint of the system can be significantly reduced.

The introduction of the rotary movement of the tower with the front vertical column also creates the possibility that this axis - with the two backward spread columns - forms the main axis of the tower and serves to optimize the tower dimensions. Thus, minimum material use for the tower and very large hub heights with high performance parameters are economically possible.

embodiment

Further details and advantages of the invention will be explained below with reference to an embodiment and with reference to the drawings. Show it

1 the inland wind turbine with a tower construction according to variant 1, referred to as "TURNING-TOWER", in a side view,

2 the wind turbine after 1 in a side view offset by 90 °,

3 the wind turbine in the position after 2 in the plan view,

4 the wind energy plant with a tower construction according to variant 2 in a side view,

5 the wind turbine after 4 in the plan view,

6 the comparison of wind turbines according to variant 1 ( 6a ) to variant 2 ( 6b ) in schematic perspective views.

After the 1 to 6 exists the tower construction called TURNING-TOWER 1 for a wind energy plant consisting of three towers; the front vertical pillar 3 and the example two, to the front pillar 3 spread and horizontally spread rear columns 4 holding the front vertical pillar 3 support. All three columns 3 . 4 consist of finished rolled large pipes in manufacturing lengths of about 12-16 meters or designed as a framework, rolled large or hollow sections and are after each section length by stabilization and stiffening 8th against bending forces, horizontal additional forces and wind supported and strengthened. The upper end of the three connected columns 3 . 4 happens in a carrier system, which at the same time the receiving conditions for the nacelle as engine house with generator 9 including a hoisting gear not shown in the drawings for hub height equipment 7 and the service and for electrical lines as well as control and measuring equipment.

The rotor blade 6 With increasing megawatt outputs, modern wind turbines are getting ever longer lengths, so that the associated large elastic deformation by the wind risks collision with components of the tower construction 1 brings with it, especially if all columns 3 . 4 the tower construction 1 are spread to each other. To avoid such collisions, the front pillar according to the invention 3 vertically arranged vertically and the backwards spread columns 4 take over the support of the vertical column 3 , In contrast to the previous version of the wind turbines with fixed, non-rotatable tower on which the nacelle with rotor 5 always adjusts to the wind and in all directions with increasing size of the tower construction 1 required TURNING TOWER has as a rotatable tower construction 1 with the rotation axis 2 and the main axis 10 the outstanding advantage that he has for designing and sizing at full hub height 7 can be optimally designed. The TURNING TOWER has several heights with hub heights 7 of over 100 meters and with power outputs greater than 3 megawatts material advantages in the order of 25 to 50% shown. The vertical column 3 owns in the foundation 14 if you look for variant 1 as the center of the circular path 11 is used, a support camp 13 , It is designed so that it also takes on tensile forces to ensure stability. In the drawings after the 1 . 2 and 4 is the design of the support bearing 13 shown with a support ball, instead of a support ball and a rotary joint can be used.

The example of the variant 2 after the 4 . 5 and 6b with all three rotating columns 3 . 4 on the circular path 11 the center of the rotational movement is at the intersection of the bisectors 16 the bases of all columns 3 . 4 , The foundation 15 and the circular path arranged thereon 11 , with the design matched to the diameter with respect to the axis of rotation 2 the tower construction 1 is according to the pressure forces to be accepted for variant 1 from the two spread pressure columns 4 with proven support and chassis 12 such as B. executed on heavy handling and shipyard systems, for variant 2 from all three pillars 3 . 4 accepted.

LIST OF REFERENCE NUMBERS

1

Tower construction (TURNING-TOWER)

2

Rotary axis of the tower construction including gondola

3

Vertical column, front pillar

4

spread rear pillars, pressure columns

5

rotor

6

rotor blade

7

hub height

8th

Stabilizations and stiffeners

9

Gondola as engine house with generator

10

Main axis of the tower

11

Circular path around the axis of rotation 2

12

Support and chassis

13

Support bearing (support ball / slewing connection)

14

Foundation for support camp 13

15

Foundation to the circular path 11

16

Seitenhalbierende

Claims (1)

Tower construction for a wind turbine inland (onshore) with a horizontal rotor axis for use of the lower part of the tropospheric wind up to 400 m height with large rotors and drive power, in which the tower construction consists of at least three columns ( 3 . 4 ) whose center lines intersect at hub height, one of the columns ( 3 ) of the tower construction ( 1 ) is arranged vertically for receiving the rotor and this vertical column ( 3 ) by at least two spread columns ( 4 ) against the rotor force ( 5 ) and these pressure columns ( 4 ) including the stabilizations and struts ( 8th ) with the vertical column ( 3 ) as a unified tower construction ( 1 ) on a circular path ( 11 ) are rotatable, characterized in that the vertical column ( 3 ) in the center of the circular path ( 11 ), via a support bearing ( 13 ) on the foundation ( 14 ) simultaneously absorbs tensile or compressive loads and the pressure columns ( 4 ) with their supporting and landing gear ( 12 ) on the circular path ( 11 ) mobile and thus around the vertical column ( 3 ) are rotatable, or that both the vertical column ( 3 ) as well as the pressure columns ( 4 ) with support and chassis ( 12 ) on the circular path ( 11 ) and the occurring tensile or compressive loads of the unitary tower construction ( 1 ) in the center of the circular path ( 11 ) in a support bearing ( 13 ) be transmitted.

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