DE202011100479U1 - Floating wind power system - Google Patents

Abstract

Floating wind power system (1) comprising:
a buoyant body (4);
at least two wind turbines (2) for generating electricity from wind energy, which are arranged on the buoyant body (4); and
at least one holding device (5) mounted on the buoyant body for selectively fixing, loosening and / or releasing a position and / or orientation of the buoyant wind power system (1) such that the holding device (5) is a predetermined one defined adjustable area on the water surface (6), in which the buoyant wind power system (1) can drive and / or be attached.

Description

Technical field of the invention

The present invention relates to the technical field of wind turbines. In particular, the present invention relates to the combination of wind turbines to a wind power system, which are arranged on floatable bodies.

Description of the Prior Art

In the course of the further development of wind power plants, in particular for power generation from wind energy, more and more extensive construction measures are being made in order to construct large so-called wind farms, consisting of many individual wind power plants. As a result, the search for undeveloped suitable locations for such wind turbines is becoming increasingly difficult. In order to develop sufficient expansion areas for wind farms, areas that are difficult to access or difficult to access come to the fore, such as B. Water surfaces (seas, lakes, rivers, etc.). However, the safe construction of wind turbines on water surfaces is difficult and expensive. In addition, conventional wind turbines erected on water surfaces are fixed rigidly and inflexibly on their predetermined pedestals, so that in retrospect, neither standard changes nor alignment changes can be made.

Summary of the invention

To solve these problems in the prior art, the present invention provides a buoyant wind power system 1 according to claim 1, comprising a buoyant body 4 , at least two wind turbines 2 to generate wind energy on the buoyant body 4 are arranged and at least one holding device 5 to a position and orientation of the buoyant wind power system 1 optionally attach and / or release.

Brief description of the drawings

1 Figure 4 is a schematic illustration of the present invention using vertical axis wind turbines.

2 Figure 3 is a schematic illustration of the present invention using horizontal axis wind turbines.

Detailed description of the invention

The present invention discloses a buoyant wind power system 1 that has a buoyant body 4 (which may consist of several pontoons), at least two wind turbines 2 for obtaining wind energy, and at least one holding device 5 includes. Preferably, the wind turbines generate 2 From the wind energy electric power and therefore include corresponding devices, such as a generator or a system for transmitting the electricity generated in a power grid. The buoyant body 4 serves as a floating platform on top of the wind turbines 2 to assemble. The buoyant body 4 can be formed from one pontoon or several connected pontoons. According to the present invention, the buoyant body carries 4 of the buoyant wind power system 1 at least two wind turbines 2 , The holding device 5 serves to the buoyant body 4 in a freely chosen position or in a freely chosen orientation. This attachment does not have to be completely rigid or immobile. When as a holding device 5 For example, an anchor system is used (see 1 or 2 ) is an attachment according to the invention of the buoyant body 4 definitely with a - again freely selectable - game provided, so that the buoyant wind power system 1 in a predetermined adjustable range on the water surface 6 drift and / or can be attached. The holding system 5 allows, for example, that the buoyant wind power system 1 optionally and adjustably fastened, loosened and / or loosened, so that the holding device 5 a predetermined adjustable area on the water surface 6 for the buoyant wind power system 1 defined in which the buoyant wind power system 1 drift and / or can be attached. The lock of attachment by the holding device 5 may be, for example, an extension of an anchor chain (unwinding from a winch), whereby the predetermined adjustable range on the water surface 6 enlarged, on which the buoyant wind power system 1 can drive. In this example, of course, the anchor chain can be shortened again (winding on a winch) to reduce the predetermined adjustable range again.

It is for example possible that the buoyant wind power system 1 around 30 ° on the water surface 6 can turn. But there are also other arbitrary angles of rotation possible. The holding device 5 can also be implemented in such a way that an offset of the buoyant wind power system 1 or a drive of the buoyant wind power system 1 several meters on the water surface 6 is possible. This offset can also be freely combined with any angle of rotation according to the invention. However, it is also possible that the holding device 5 the predetermined range for offset and / or rotation less than one meter or an angular degree pretending - whereby a complete fixation of the buoyant wind power system 1 through the holding device 5 is possible.

The holding device 5 but can also be implemented, for example, via bars and / or rail systems (not shown) as needed with more or less play. The holding device 5 is able, if necessary by a user the buoyant body 4 to fix and to solve this attachment again. The holding device 5 does not necessarily have to with the reason 5 be connected. You can also connect to z. As a bridge, a quay wall or other floating buoyant bodies next to each other 4 represent, so a wind farm of several wind power systems according to the invention 1 build.

Every wind turbine 2 the wind power system according to the invention 1 each includes at least one wind turbine 3 , If the wind turbine 3 a vertical axis of rotation is called a vertical axis wind turbine (see 1 ) while when the wind turbine 3 has a horizontal axis of rotation is called a horizontal axis wind turbine (see 2 ). The direction of rotation (A, B) of the wind turbines 3 must be chosen so that a direction of rotation A at least one of the wind turbines 3 opposite or opposite to a direction of rotation B of a respective other wind turbine 3 of the buoyant wind power system 1 is. If more than two wind turbines 2 or at least more than two wind turbines 3 on the buoyant body 4 must be mounted, at least one of the wind turbines 3 have a different rotational direction A and B than the others. In the in 1 or 2 shown example, are each two wind turbines 2 each with a wind turbine 3 on a buoyant body 4 to a buoyant wind power system according to the invention 1 combined. However, it is also possible to combine three or four wind power plants according to the present invention, for example 3 wind turbines having a direction of rotation A and only one wind turbine having the direction of rotation B. Especially for horizontal axis wind turbines, it is also possible that by special design of the wind turbine 3 the direction of rotation of the wind turbine can be changed. According to the present invention, horizontal axis wind turbines and vertical axis wind turbines are also possible together on the buoyant body 4 to a buoyant wind power system according to the invention 1 to arrange. In the 1 and 2 In each case, for example, the directions of rotation A and B are illustrated by arrows. The directions of rotation A and B can, according to the invention, also be opposite to the directions indicated in FIG 1 and 2 be implemented.

Each of the at least two wind turbines 2 has a braking system (not shown) for braking the respective wind turbine 3 , This braking system can, for. As an eddy current brake, an aerodynamic brake or another known braking system. When the wind power system according to the invention 1 is in operation and the wind turbines 3 rotate at the same rotational speed A and B, the torques resulting from this rotation compensate for the buoyant wind power system 1 or the buoyant body 4 , Thus, must by the holding device 5 no reverse torque can be intercepted to a rotary or pivoting movement of the buoyant wind power system 1 on the water surface 6 to prevent. Now if the position or orientation of the buoyant wind power system 1 should be changed, the holding device 5 the attachment of the buoyant wind power system 1 completely solve or at least increase the game of attachment to allow a pivoting or pivoting movement to the extent desired. The speeds of the wind turbines 3 are through selective braking of individual wind turbines 3 variable to any torque difference between the resulting reverse torques on the buoyant wind power system 1 through the wind turbines 3 to create. If - as previously mentioned - the wind turbines 3 rotate with different directions of rotation, with the same rotational speed, then compensate both Rückdrehmomente. However, if the selective braking is chosen such that the wind turbines 3 have different rotational speeds, the overall result is an effective return torque to the buoyant wind power system 1 , which now begins, according to the return torque on the water surface 6 to move. Through targeted selective braking of the wind turbines 3 Is it possible for an operator to use the buoyant wind power system? 1 to any position or to a desired orientation on the water surface 6 bring to. Once the desired position or orientation is reached, the holding device 5 again an attachment of the buoyant wind power system 1 make. In particular, with regard to horizontal-axis wind turbines, according to the present invention, there is thus no need for their complex and fault-prone azimuth control, which is otherwise indispensable in the prior art.

1 shows a schematic representation of the present invention according to a preferred embodiment when using vertical axis wind turbines. The buoyant wind power system 1 Floats on the water surface 6 and is about a holding device 5 at the bottom 7 attached. In this example, the fixture is 5 an anchor device, which in principle also other holding devices 5 can be used. 2 shows a schematic representation of the present invention according to another preferred embodiment when using horizontal axis wind turbines. An additional advantage of the buoyant wind power system according to the invention 1 is also that the gyroscopic moments of the rotating wind turbines 2 the buoyant wind power system 1 stabilize in its position, reducing the wind turbines 2 by the inventive interconnection on the buoyant wind power system 1 have a higher stability and longer durability than when they are - as customary in the art - individually positioned. In addition, one can inventively a buoyant wind power system 1 Use wherever the foundation of pile foundations for conventional wind turbines is not feasible for reasons of water depth (eg too deep) or the condition of the substrate (eg silt) or for cost reasons. The present invention is also suitable for wind power use in wetlands or permafrost zones.

LIST OF REFERENCE NUMBERS

1

Wind Power System

2

Wind turbine

3

wind turbine

4

buoyant body

5

holder

6

water surface

7

reason

A and B, respectively

exemplary directions of rotation

Claims (6)

Floating wind power system ( 1 ), comprising: a buoyant body ( 4 ); at least two wind turbines ( 2 ) for generating electricity from wind energy stored on the buoyant body ( 4 ) are arranged; and at least one holding device ( 5 ) mounted on the buoyant body to determine a position and / or orientation of the buoyant windmill system ( 1 ) optionally to fix, loosen and / or release, so that the holding device ( 5 ) a predetermined adjustable area on the water surface ( 6 ), in which the buoyant wind power system ( 1 ) and / or can be attached. Floating wind power system ( 1 ) according to claim 1, wherein the wind turbines ( 2 ) at least one wind turbine ( 3 ) and wherein a direction of rotation of at least one of the wind turbines ( 3 ) opposite to a direction of rotation of a respective other wind turbine ( 3 ) on the buoyant wind power system ( 1 ). Floating wind power system ( 1 ) according to claims 1 to 2, wherein the speeds of the wind turbines ( 3 ) by selective braking of individual wind turbines ( 3 ) are variable to an optional torque difference between the wind turbines ( 3 ) to create. Floating wind power system ( 1 ) according to claim 3, wherein the optional torque difference comprises a rotation of the buoyant wind power system ( 1 ) for an optional repositioning of the buoyant wind power system ( 1 ) caused. Floating wind power system ( 1 ) according to claims 1 to 4, wherein the wind turbines ( 2 ) each comprise at least one vertical axis wind turbine. Floating wind power system ( 1 ) according to claims 1 to 4, wherein the wind turbines ( 2 ) each comprise at least one horizontal axis wind turbine.

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