DE10064912B4 - Rotor blade for a wind energy plant - Google Patents

Abstract

A rotor blade of a wind energy plant, wherein the rotor blade (10) has a certain area, which is exposed to the wind during operation of the wind turbine and means for changing the size of the surface of the rotor blade (10), characterized in that the means for changing the size of the surface of the rotor blade (10) in the region of the rotor blade root (12) or the rotor blade root near part are arranged.

Description

The present invention relates to a rotor blade for a wind energy plant and to a wind energy plant with at least one rotor blade according to the invention.

Rotor blades for wind turbines are well known and widely visible on each wind turbine. These rotor blades have an outer shape, which takes into account the special aerodynamic requirements. In order to save material and weight, these rotor blades generally consist of a first, inner support structure and an aerodynamically designed surface which surrounds this first support structure.

For large wind turbines take the rotor blades for reasons of aerodynamics considerable dimensions. This affects on the one hand on the production and the transport, and on the other hand on the loads, which act on the wind energy plant in the enterprise. These result, in particular, from the leaf surface which increases automatically with increasing size, as well as from the enlarged surface swept over by the rotor blades.

Wind turbines must be designed according to given guidelines for specific load cases. These are, on the one hand, the loads occurring during operation (so-called operating loads) and, on the other, the so-called extreme load cases. These extreme load cases are from certain situations or disorders such. As a power failure, a disturbance of the pitch, an extraordinary strong Windbö (50-year gusts, etc.), derived.

It is understandable that the loads transferred from the rotor blades to the system depend substantially on the rotor blade surface exposed to the wind. For the calculation of the extreme load, it is assumed that the entire rotor blade surface is exposed to a maximum wind. Accordingly, all subsequent components such as drive train, machine frame, tower, foundation, etc. must be designed.

It follows that, the smaller the wind attack surface, so in particular the rotor blade surface, the lower the load level for which the system must be designed. This also means lower material costs and thus lower costs.

In contrast, however, there is a need for aerodynamic reasons, minimum surface area to the forces required for the operation of the wind turbine - the rotation of the generator - can muster. It is disadvantageous in the known rotor blades that in particular in the leaf root near area with increasing rotor blade size also increasing rotor blade depth is needed. This depth is so great that even a road transport of such a rotor blade is no longer possible or only with disproportionately high effort.

From the DE 197 19 221 C1 a rotor blade for wind turbines is known, whose surface is made of a flexible material in the central region of the rotor blade, wherein the interior of the rotor blade is filled with a variable in pressure medium, so that an increase in the diameter of the rotor blade are made in the central region of the rotor blade can.

The object of the present invention is therefore to provide a rotor blade in which the described disadvantages are avoided and which has the aerodynamically required surface.

The object is achieved with a rotor blade with the features of claim 1. Advantageous developments are described in the further claims.

The invention is based on the finding that in normal operation of the wind turbine, a certain rotor blade surface (nominal area) is required, while these are at extreme wind and z. B. in a transport situation u. U. is too big.

According to the invention, it is therefore proposed to further develop a rotor blade of the type mentioned at the beginning in such a way that a part of the surface is actively deformable or movable.

In a preferred embodiment of the invention, a portion of the surface is formed of a deformable material which is part of a closed container. This closed container can, for. B. are filled with a gaseous medium, said gaseous medium is subjected to a predetermined pressure. This results in a partially inflatable surface of the rotor blade, which can be vented during transport or when extreme wind occurs and thus takes up less space or yields under the wind pressure. As a result, the effective surface of the rotor blade and thus the attack surface for the wind is smaller. At the same time, the load on the following components, including the tower, decreases.

In a particularly preferred embodiment of the invention, the rotor blade on a per se and / or in itself movable second support structure.

In this case, the deformable material may be fixed at predetermined locations of this second support structure. Furthermore, the deformable material may be fastened with one side to a rotatable winding core.

In normal operation of the wind turbine, the second support structure can now be extended, d. h., Folding arms can be fully extended or telescopic arms fully extended. The deformable material may be fastened with one side to a rotatable winding core. If the rotor blade surface is now to be reduced, the winding core is rotated in a manner similar to that of an awning so that it winds up the deformable material. At the same time, the folding arms are folded and reduce the size of the second supporting structure in the area of the reducible surface, so that the surface of the rotor blade is correspondingly reduced.

In an alternative embodiment of the invention, a part of the surface of the rotor blade of lamellar strips, which are each arranged on a pivotable about its own longitudinal support rail. These blades are aligned in normal operation so that they increase the aerodynamically effective surface of the rotor blade. For transport and / or extreme loads, the mounting rails can be pivoted so that these slats z. B. get into the lee of the remaining rotor blade and thereby the surface of the rotor blade is reduced.

In a particularly preferred embodiment of the invention, a movable part of the aerodynamically effective surface of the rotor blade consists of a single surface element, which is displaceable in the direction of the depth of the rotor blade. During normal operation, this surface element extends the surface of the rotor blade, preferably on the suction side, in order to create a large, aerodynamically effective surface.

To reduce the surface of this surface element, similar to the flap system of an aircraft wing can be moved so that it is either moved into the rotor blade and thus covered by the remaining surface of the rotor blade, or is moved to the surface of the rotor blade and in turn the surface covering the rotor blade. In any case, this results in a reduction of the surface of the rotor blade.

In an alternative embodiment of the invention, this surface element can be pivoted on one side to the first support structure or of the rear edge of the rotor blade. To change the size of the rotor blade surface of this element can be pivoted about this pivot axis either to the suction side or to the pressure side of the rotor blade.

A pivoting of this surface element by about 90 ° causes this element is substantially perpendicular to the direction of air flow on the rotor blade and unfolds a corresponding braking effect, since it forms an obstacle for the air flowing along the surface of the rotor blade along.

In the following, several embodiments of the invention will be explained in more detail with reference to the accompanying drawings. Showing:

1 a plan view of an inventive complete rotor blade;

2 a plan view of the front part of a rotor blade according to the invention;

3 a simplified cross-sectional view of a first embodiment of a rotor blade according to the invention;

4 a simplified cross-sectional view of a second embodiment of a rotor blade according to the invention;

5a . 5b a simplified cross-sectional view of a third embodiment of a rotor blade according to the invention;

6 a simplified cross-sectional view of a fourth embodiment of a rotor blade according to the invention;

7 a simplified cross-sectional view of a fifth embodiment of a rotor blade according to the invention;

8a . 8b simplified cross-sectional views of a sixth embodiment of a rotor blade according to the invention;

In 1 is a simplified plan view of a complete rotor blade according to the invention. The rotor blade 10 is divided into two areas. Here is the rotor blade 10 in conventional parts conventionally constructed. In one of the rotor blades root 12 adjacent area, namely the area with the largest blade depth, however, a pitch of the rotor blade can be seen. This division marks the area of the rotor blade 10 whose surface can be reduced if necessary and thus be removed from the action of the wind.

The fixed part of the rotor blade 10 , whose surface remains unchanged, is in 2 shown. As can be clearly seen in this figure, the aerodynamically effective surface of the rotor blade 10 significantly reduced, and thus the load, especially in extreme wind situations, significantly lower than in a conventionally constructed rotor blade.

3 shows a simplified cross-sectional view of a first embodiment of the invention. Here is the rotor blade 10 in a front area 11 and a backbox 14 divided up. This back box 14 consists of two sheets of deformable material 18 , which together with the rear wall of the front area 11 a closed container 16 form. Now this closed container 16 filled under pressure with a gaseous medium, forming the deformable material 18 a part (in 1 with the reference number 14 indicated) of the aerodynamically effective surface of the rotor blade according to the invention in normal operation 10 ,

By a suitable choice of the filling pressure results in such a stability of this part of the rotor blade 10 in that it develops its normal effect in normal wind conditions. In an extreme wind situation, the wind pressure on this part of the rotor blade 10 but larger, so that then the external pressure is greater than the internal pressure, and thus there is a deformation of the rotor blade in the region of the rear box 14 and the rotor blade gives way to the external wind pressure. As a result, the attack surface for this extreme wind is lower and thus the loads on the subsequent construction smaller.

To damage in particular the container 16 can be avoided, for. B. a (not shown) pressure relief valve may be provided through which a in the container 16 can escape forming overpressure.

By using a compressor 17 the pressure required for normal operation can be restored. If further controllable valves (also not shown) and / or pressure sensors are provided, the filling pressure in the container 16 be tracked even with fluctuations in wind pressure, so as to always maintain optimal operating conditions.

4 shows a second embodiment of the present invention, in which instead of a complete Hinterkastens 14 the surface of the suction side of the rotor blade 10 is extended. This extension is a surface element 24 , which adhere to the surface of the front area 11 followed.

To reduce the aerodynamically effective surface of this surface element 24 be moved in the direction of the arrow. This move can z. B. hydraulically, namely with appropriate hydraulic cylinders, pneumatically, with pneumatic cylinders, by electric drives or in any other suitable manner. For this purpose, of course, appropriate (but not shown for reasons of clarity in the figure) pumps, compressors or actuators (actuators) must be provided.

This displacement can take place in the front area, so that the surface of the front area 11 the surface element 24 covered. Alternatively, the displacement may also be on the surface of the front area 11 done so that the surface element 24 in turn, the corresponding part of the surface of the front area 11 covered. In both cases, there is a reduction in the aerodynamically effective surface of the rotor blade 10 ,

A third embodiment of the present invention is disclosed in FIGS 5a and 5b shown. 5a shows a wrap 20 a deformable material and the reference numeral 30 refers to folding arms which are in the folded state. The mechanism here can be comparable to that of an awning.

In 5b This embodiment is shown in the state of normal operation. The folding arms 30 are stretched, and there the deformable material 18 attached to it, this was when extending the folding arms 30 from the wrap 20 unwound so that the winding core 21 now no longer carries the entire material wrap.

In this developed situation, the deformable material 18 on the one hand on the winding core 21 and on the other hand, to the right in the figure pointing ends of the folding arms 30 attached. These ends of the folding arms 30 may in turn be connected by a web, not shown, on the one hand to achieve a higher strength of the construction and on the other hand to fix the deformable material.

To give in the deformable material 18 between the winding core 21 and the outer ends of the folding arms 30 can prevent underneath the deformable material 18 a (not shown) scissors-like device may be provided which synchronously with the folding arms 30 is actuated and the deformable material 18 in the extended state.

Reducing the effective surface is the reverse; the folding arms 30 and the scissors grid (not shown) are retracted (folded) and at the same time the deformable material 18 on the winding core 21 wound so that eventually the in 5a illustrated winding 20 gives and the effective surface of the rotor blade 10 is reduced.

In an in 6 shown fourth embodiment of the invention is the surface element 24 at the back of the front area 11 hinged pivotally and thus extends the suction side of this front area 11 , In doing so, the surface element becomes 24 supported by a compression spring between the surface element 24 and the supporting structure of the front area 11 is arranged.

In normal operation, this compression spring supports the surface element 24 so that it retains the desired position. Now, beyond the normal operating conditions, a wind pressure on the upper side of the rotor blade results 10 , the pressure on the surface of the surface element increases 24 and overcomes the force of the spring, leaving the surface element 24 in the 6 is pressed down, so the wind pressure gives way, and thus reduces the aerodynamically effective surface accordingly.

As an alternative to the spring of course, corresponding telescopic elements such as hydraulic or pneumatic devices or mechanical devices for active adjustment of the surface element may be formed, for. B. threaded rods and worm drive o. Ä. Be used to the surface element 24 to hold in a first predetermined position or to move to a second predetermined position. Of course, corresponding pumps, compressors or drives must be provided for the operation of these actuators, which in turn are not shown in this figure for the sake of clarity.

Likewise, in turn, the wind load can be detected on the surface element 24 acts and depending on this detected wind load, the surface element 24 be pivoted about the pivot axis to make an optimal for the current operating conditions setting.

7 shows a fifth embodiment of the invention. In this fifth embodiment, the surface element is 24 instead of a hinged linkage at the back of the front section 11 on a pivotable axis about its own longitudinal axis 22 arranged. In the in 7 position shown extends the surface element 24 again the aerodynamically effective surface of the rotor blade 10 ,

To reduce this surface is now the pivot axis 22 with the surface element attached thereto 24 rotated about its longitudinal axis such that the outer end of the surface element 24 moved in one of the two directions shown by the double arrow. This in turn leads to a reduction of the aerodynamically effective surface of the rotor blade 10 and concomitantly to a change in the wind load on the rotor blade 10 and all subsequent components of the wind turbine.

A variant of in 7 shown embodiment is in the 8a and 8b shown. It is in 7 With 24 designated surface element in 8a in three lamellar elements 26 divided up. These are in 8a intentionally shown at a distance to illustrate this division. In an actual embodiment, these three elements are of course arranged so that they form a closed surface as possible, which in turn as smooth as possible to the front area 11 of the rotor blade 10 followed.

Each of the slats 26 is arranged on a separate pivot axis. Each of these swivel axes 28 is rotatable about its own longitudinal axis and thus allows by rotating the pivot axis 28 around the longitudinal axis, a pivoting of the slats 26 ,

8b shows the device according to the invention in the situation in which these lamellae are pivoted so that the aerodynamically effective surface of the rotor blade 10 is reduced. Here are the slats 26 in the flow shadows of the front area 11 pivoted. As a result, on the one hand they no longer act as a rotor blade surface, but on the other hand are also deprived of the wind and thus not exposed to increased loads.

Such an arrangement is achieved by, in addition to a rotation of the pivot axes 28 about their longitudinal axes also the distance between the left in the figure pivot axis 28 and the front area 11 of the rotor blade 10 on the one hand and between the swivel axes 28 on the other hand is reduced.

If only an extension of the suction side of the surface is shown in the figures, the surface of the pressure side can, of course, alternatively or additionally be changed accordingly.

If a wind turbine equipped with the above rotor blades, so it is possible that when extreme wind situation occurs not only the large wind speed is determined, which can be done by means of wind speed gauges, but that by an appropriate control the size of the surface of the rotor blade then clear is reduced. As in 1 and 2 to recognize, for example, the surface of the rotor blade after 1 by more than 10% larger than the surface of the rotor blade after 2 , While the normal size of the rotor blade is set in the nominal operation of the wind turbine, for example at a wind speed in the range of 2-20 m / s wind speed, the surface size at a wind speed of above 20 m / s can be reduced, so that the surface size significantly - in 2 shown - decreases.

The control is preferably computer-aided and, if necessary, ensures the respectively optimally set surface size of the rotor blade.

Claims (14)

Rotor blade of a wind turbine, wherein the rotor blade ( 10 ) a certain area which is exposed to the wind during operation of the wind turbine and means for changing the size of the surface of the rotor blade ( 10 ), characterized in that the means for changing the size of the surface of the rotor blade ( 10 ) in the area of the rotor blade root ( 12 ) or the rotor blade root near part are arranged. Rotor blade according to claim 1, characterized in that the rotor blade has a first support structure and a first supporting structure enveloping aerodynamically designed surface, wherein the size of the surface of the rotor blade in extreme wind situations and / or during transport in certain sections of the rotor blade significantly lower is than in the normal operation of the rotor blade and wherein the means for changing the size of the surface of the rotor blade are formed so that with them the cross section of the rotor blade is changeable, deformable and / or movable. Rotor blade according to one of claims 1 or 2, characterized in that the means for varying the size of the surface are constituted by a deformable part of the surface forming part of a closed container ( 16 ). Rotor blade according to one of claims 1, 2 or 3, characterized in that the means for changing the size of the surface are formed by a per se and / or in itself movable second support structure in a predetermined region of the rotor blade. Rotor blade according to Claim 4, characterized by at least point-wise attachment of a deformable material ( 18 ) at predetermined locations of the second support structure ( 30 ). Rotor blade according to claim 4, characterized in that a deformable material ( 18 ) with one side on a rotatable winding core ( 21 ) is attached. Rotor blade according to claim 4, characterized by at least one support rail which can be pivoted about its own longitudinal axis, wherein a planar element (11) is mounted on each support rail. 24 ) is arranged. Rotor blade according to claim 7, characterized by a plurality of support rails pivotable about its own longitudinal axis and planar elements arranged on the support rails, wherein the distance between the support rails can be changed in the radial direction. Rotor blade according to claim 4, characterized by a surface element ( 24 ), which is articulated on one side pivotally on the first support structure. Rotor blade according to one of claims 1 or 2, characterized by a in the direction of the depth of the rotor blade ( 10 ) movable part of the surface. Rotor blade according to one of the preceding claims, characterized in that in particular the part of the surface of the rotor blade can be changed by the means for changing the size of the surface, which is in the region of the rotor blade root or the rotor blade near part. Wind energy plant with at least one rotor blade according to one of the preceding claims. Wind energy plant according to claim 12, characterized in that a control is provided by which the means for changing the size of the surface are adjusted. Wind energy plant according to claim 13, characterized in that means are formed by means of which an extreme wind situation can be detected and that these means of controlling the means for changing the size of the surface are coupled and that in an extreme wind situation, for. B. at a wind force of more than 20 m / s, the size of the surface of the rotor blade or the rotor blades is lower than at a wind speed below 20 m / s.

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