NL1018670C2 - Wind turbine regulator - Google Patents

Abstract

The invention concerns a method for regulating a wind turbine, consisting of a number of rotor blades and sensors placed in the rotor blades for detecting them bending. The procedure comprises the following stages:- continuous measurement of the extent to which the rotor blades are bending;- storing measurement values corresponding to at least one full rotation;- analysis of the measurement values stored;- regulation of the wind turbine based on the analysis results.

Description

WIND TURBIN ARRANGEMENT

The invention relates to a method for controlling a wind turbine, which comprises a number of rotor blades and deflection sensors arranged in the rotor blades.

Wind turbines are already known in which deflection sensors are arranged in the rotor blades of the wind turbine. These deflection sensors are used to detect vibrations in the rotor blades. When a certain threshold value of the deflection sensors is exceeded, the wind turbine is switched off. For an ex post evaluation, measurements of the period around the time when the threshold value is exceeded are stored. In this way it is possible to evaluate afterwards why the control has switched off the wind turbine 15.

Wind turbines are designed and calculated on the basis of predetermined wind loads. After a wind turbine has been built and placed at a certain location, however, it may be that the actual wind load does not correspond to the wind load that was taken into account during the design of the wind turbine. This can lead to greater wear of the wind turbine or to inefficient use of the wind turbine.

Existing wind turbines further have the disadvantage that in many cases they are not properly oriented towards the wind. As a result, the wind turbine is skewed and the wind turbine does not work optimally.

It is an object of the invention to provide a method for controlling a wind turbine, wherein the above-mentioned disadvantages are partially or even completely avoided. This object is achieved with a method according to the invention, which comprises the steps of: 1018670 2 - continuously measuring the deflection of the rotor blades; - storing measured values corresponding to at least one revolution; 5 - analyzing the stored measurement values; - controlling the wind turbine on the basis of the analysis.

Because the measured values of a revolution are stored, it can be checked during the analysis how a rotor blade is loaded at a certain position.

The wind turbine 5 can then be regulated on the basis of this analysis.

In a preferred embodiment of the method according to the invention, the measurements of at least a part of one revolution of the rotor are stored equal to the reciprocal of the number of rotor blades 10. If, for example, a wind turbine has three rotor blades, each having a deflection sensor mounted therein, it can already be checked with a third revolution how a rotor blade is loaded at a certain position. If two rotor blades are present, then half a revolution is sufficient.

In another preferred embodiment, the rotor blades are rotatably mounted on a rotatable gondola. The method further comprises the steps of: - comparing the deflection measurement values on one side of the cross axis with the measurement values of on the other side of the cross axis when analyzing; - controlling the wind turbine, so that the gondola is seasoned in such a way that the deflection measurement values are the same on both sides of the axis of rotation.

Because the measured values of an entire revolution are available, it is possible to see how the load of a rotor blade is relative to the vertical on one side of the gondola relative to the loads on the other side. It can thus be determined whether the rotor blade is equally loaded on both sides by the wind or whether there is a difference in it, as a result of which the gondola must be seasoned to direct it straight into the wind.

In another embodiment of the method according to the invention, the pitch of the rotor blades can be adjusted separately and the method further comprises the steps of: - determining the optimum pitch of a rotor blade at a rotor blade position when analyzing the measured values; - controlling the wind turbine, so that during the rotation of the rotor blades the optimum pitch determined for each rotor blade is determined at the rotor position.

if a wind turbine is driven by a laminar wind flow, the local wind speed will depend on the distance and wind direction to the ground, the wind direction close to the ground may deviate from the direction at a greater distance from the ground. The wind speeds close to the ground will be lower than at a greater distance from the ground. The pitch position of rotor blades is set based on the prevailing wind speed and wind direction. In order to drive a wind turbine as efficiently as possible, the pitch position of the rotor blades is thus set according to the invention depending on the rotor position. If the rotor blade is at the bottom of the gondola, then the pitch position is set to the lower wind speeds and / or deviating wind direction when the rotor blade is above the gondola, the pitch position is set for higher wind speeds and associated wind direction.

In yet another embodiment, the method according to the invention comprises the step of determining the load of each rotor blade when analyzing the measured values. On the basis of this calculated load 1018870 4, it can be determined how long the technical life of the rotor blades is.

In another embodiment of the method according to the invention, the method step can be provided that when the threshold value of the load is exceeded, the wind turbine is braked. Excessive load on a rotor blade can lead to cracking, breakage or other damage to the rotor blade. To prevent this, the wind turbine can be stopped. In yet another method step according to the invention, the height of the threshold value depends on the current energy demand. When a rotor blade is heavily loaded, the technical life will quickly decrease. This can outweigh the monetary revenue that is generated as a result of the current energy demand. For example, it will be more attractive during the day for the wind turbine to function under higher loads than at night.

These and other features are further elucidated with reference to the accompanying figure.

The figure schematically shows the different steps for performing an embodiment of the method according to the invention.

The figure shows a wind turbine 1 with a rotatable gondola 2 on which three rotor blades 3 are rotatably mounted. A sensor 4 is arranged in each rotor blade 3, which sensor measures the load of the associated rotor blade by deflection. The measured values of the sensors 4 go via lines 5 to a processing unit 6. Together with the angular position a of the rotor blades 3, the signals from the sensors 4 are stored in a storage part 7.

The angular position α can be measured by means of an angle sensor, but can also be derived from the signals from the sensors 4. Since these signals are sinusoidal, since the deflection of the rotor blades is caused at least in part by its own weight, the angular position a from these signals are derived.

The signals stored in the unit 7 provide a relationship between the angular position a and the load P. This 5 can be analyzed by an analysis unit 8 and, as a result of this analysis, the wind turbine 1 can be engaged by means of a signal 9. This can be done, for example, by allowing the gondola 2 to crouch, by switching off the wind turbine or by adjusting the rotor blades 3. All this in order to allow the wind turbine 1 to function as optimally as possible in the circumstances present.

1018670

Claims (7)

A method for controlling a wind turbine comprising a number of rotor blades and deflection sensors arranged in the rotor blades, the method comprising the steps of: 5. continuously measuring the deflection of the rotor blades; - storing measured values corresponding to at least one revolution; - analyzing the stored measurement values; 10. controlling the wind turbine on the basis of the analysis. 2. Method as claimed in claim 1, wherein the measurements of at least a part of one revolution of the rotor are stored equal to the reciprocal of the number of rotor blades. 3. Method as claimed in claim 1 or 2, wherein the rotor blades are rotatably arranged on a rotatable gondola, which method further comprises the steps of: - comparing the deflection measurement values on one side of the axis of rotation with the measurement values of on the other side of the spindle axis; - controlling the wind turbine, so that the gondola is seasoned in such a way that the deflection measurement values are the same on both sides of the axis of rotation. Method according to one of the preceding claims, wherein the pitch of the rotor blades is individually adjustable, which method further comprises the steps of: <018670 * - determining the optimum pitch of a rotor blade at a rotor when analyzing the measured values -leaf; - controlling the wind turbine, so that during the rotation of the rotor blades the optimum pitch determined for each rotor blade is determined at the rotor position. Method according to one of the preceding claims, comprising the step of: 10. determining the load of each rotor blade when analyzing the measured values. 6. Method as claimed in claim 5, comprising the step of: - braking the wind turbine when exceeding a threshold value of the load. Method according to claim 6, wherein the height of the threshold value depends on the current energy demand. 1018670