TECHNICAL FIELD

The invention relates to a method of controlling a wind turbine comprising a tower, a nacelle located on the tower, and a rotor mounted on the nacelle and comprising a hub and at least one blade, the wind turbine further comprising a yaw drive system for rotating the nacelle in relation to the tower about a substantially vertical axis, and/or a pitch drive system for rotating the blade around a longitudinal axis thereof.

BACKGROUND

In very high wind speed conditions, wind turbines are shut-down and parked or allowed to idle. During such conditions, a primary concern is to avoid failure of turbine components, such as blades, due to extreme wind speeds. Edgewise vibrations in particular during stand still have been studied, see for example Christian Bak, Research in Aeroelasticity EFP-2006, Wind Energy Department, Riso National Laboratory, Technical University of Denmark, Roskilde, Denmark, July 2007. A number of suggestions have been put forward for strategies at extreme wind situations, such suggestions usually involving feathering the blades and/or yawing upwind turbines into a downwind position, see e.g. U.S. Pat. Nos. 7,204,673B2 and 7,436,083B2. It has also been suggested to monitor edgewise vibrations on turbines, and adjust blade pitch or yaw angle if edgewise vibrations are detected, see WO2009068035A2 and WO2009068036A2. However, it would be advantageous to further improve strategies at extreme wind conditions in order to safeguard turbines against damage.

SUMMARY

An object of the invention is to improve strategies for protecting wind turbines at extreme wind speeds in stand still or idling conditions.

It is also an object of the invention to make it possible to make wind turbine components lighter and/or cheaper while still being able to withstand extreme wind speeds in stand still or idling conditions, and by doing so decrease the cost of energy.

The objects are reached with a method of controlling a wind turbine comprising a tower, a nacelle located on the tower, and a rotor mounted on the nacelle and comprising a hub and at least one blade, the wind turbine further comprising a yaw drive system for rotating the nacelle in relation to the tower about a substantially vertical axis, and/or a pitch drive system for rotating the blade around a longitudinal axis thereof, the method comprising, during a stand-still, non-power-producing situation of the wind turbine due to high wind speeds, continuously or periodically rotating, by means of the yaw drive system, the nacelle so as to vary the direction of the wind in relation to the rotor, and/or continuously or periodically rotating, by means of the pitch drive system, the blade so as to vary the direction of the wind in relation to the blade.

The method is simple to put into practice, since it does not require any load or vibration monitoring during standstill. Also, by reducing the risk of critical loads, components can be made lighter and cheaper.

Preferably, the blade is rotated between two extreme angular positions. Preferably, the extreme positions are separated by no more than 45 degrees. It is preferred that the extreme positions are separated by no less than 5 degrees.

The objects are also reached with a method of controlling a wind turbine comprising a tower, a nacelle located on the tower, and a rotor mounted on the nacelle and comprising a hub and at least one blade, the wind turbine further comprising a yaw drive system for rotating the nacelle in relation to the tower about a substantially vertical axis, the method comprising determining at least one angular interval of the wind direction in relation to the nacelle as a non-critical load interval, and during a stand-still, non-power-producing situation of the wind turbine due to high wind speeds, continuously or periodically monitoring the wind direction, and rotating the nacelle so that the wind direction in relation to the nacelle is in the non-critical load interval.

Preferably, the method comprises repeating, for a plurality of yaw angles in relation to the wind direction, keeping the nacelle at the respective yaw angle, and monitoring the wind speed and edgewise oscillations of the blade, storing data on wind speed and edgewise oscillations obtained by said monitoring, and determining the at least one angular interval based on said stored data.

Preferably, the method comprises determining at least two angular intervals of the wind direction in relation to the nacelle as non-critical load intervals, and during a stand-still, non-power-producing situation of the wind turbine due to high wind speeds, continuously or periodically monitoring the wind direction, and rotating the nacelle so that the wind direction in relation to the nacelle is in one of the non-critical load intervals.

DESCRIPTION OF THE FIGURES

Below, embodiments of the invention will be described with reference to the drawings, in which FIG. 1 shows a front view of a wind turbine, FIG. 2 shows a schematic vertical cross-section of a part of the wind turbine in FIG. 1, and FIG. 3 shows a top view of a part of the wind turbine in FIG. 1.

DETAILED DESCRIPTION

FIG. 1 shows a wind turbine 1 comprising a tower 2, a nacelle 3 located on the tower 2, and a rotor 4 mounted on the nacelle 3 and comprising a hub 5 and three blades 6.

Reference is made to FIG. 2. The nacelle 3 comprises a gearbox 31 and a generator 32, to which the rotor 4 is connected, which generator 32 is connected to a grid GD. The wind turbine further comprises a yaw drive system 7 for rotating the nacelle 3 in relation to the tower 2 about a substantially vertical axis VA, (indicated in FIG. 2 with a broken line). The wind turbine also comprises a pitch drive system 8 (electrical or hydraulic) for rotating the blades around their respective longitudinal axis, (indicated in FIG. 2 with broken lines LA). The yaw and pitch drive systems 7, 8 are adapted to be powered, during normal power-producing operation of the turbine, by power from the grid to which the turbine produces power. The yaw and pitch drive systems 7, 8 are also adapted to be powered by an alternative auxiliary power system, or backup system 9, which can supply power the grid power is not available. The backup system 9 could include for example batteries and an electrical power conversion unit, or an internal combustion engine (e.g. diesel engine) with a separate generator. The backup system 9 could be located in the turbine or outside the turbine. It could be turbine based (one backup system per turbine) or park based (one backup system common to a number of wind turbines).

The wind turbine also comprises a control unit 10 which is adapted to determine whether the yaw and pitch drive systems 7, 8 to be powered by the grid or the backup system 9, and to control the supply from these alternative power sources. The control unit 10 is also adapted to control the yaw and pitch drive systems 7, 8 based on signals from a wind measurement arrangement 11 providing data on wind speed and wind direction.

When the wind speed increases above a threshold value (e.g. 25 m/s), the rotor is stopped and parked, so as to provide a stand-still or idling, non-power-producing situation of the wind turbine. It is worth noting that the invention can be used regardless whether the rotor is locked with a brake or adapted to idle during extreme wind shutdown. During this non-power-producing situation, the yaw drive system 7 is controlled so that the nacelle 3 is continuously rotated so as to vary the direction of the wind in relation to the rotor 4. The nacelle could perform a reciprocating angular movement so that it is rotated a certain angular distance in one direction, and then rotated back in the other direction the same angular distance. This certain angular distance over which the nacelle is rotated back and forth is preferably at least 360 degrees, e.g. 360-1440 degrees. When the direction is changed, this could either be done without pausing, or, after the yawing movement in one direction has been stopped, there could be a pause of a predetermined time interval before the yawing movement in the other direction commences. Alternatively, the nacelle can rotate back and forth over an angular distance that is equal or less than 360 degrees, e.g. 30-360 degrees. In a further alternative, instead of being continuously moved, the nacelle 3 can be periodically rotated, so that it stays in a fixed position in relation to the wind direction for only a predetermined limited time, e.g. less than 30, 10 or 5 seconds, before it is moved in the same angular direction as the direction of the preceding movement to a new angular position.

Vibrations on wind turbine components during extreme wind speeds will vary significantly depending on the relative wind direction and the magnitude of the wind speed, (i.e. an increase in wind speed from 40 m/s to 50 m/s may provoke critical vibrations), and in some angular sectors, the loads will be more critical than in others. Rotating the nacelle in the described manner will avoid the turbine being in load critical areas of the relative wind direction for more than short durations. This will reduce extreme stand still loads, thus enabling lower component design loads and improved cost of energy.

In addition, or as an alternative, during a non-power-producing situation, the pitch drive system 8 is controlled so that the blades 6 are continuously rotated so as to vary the direction of the wind in relation to the blades 6. The blades can be rotated between two extreme angular positions, which for example could be separated by anywhere between 5 and 45 degrees. Preferably, one of the extreme angular positions is a fully feathered position, so as for the blades not moving past the fully feathered position. Such a blade pitching strategy could be carried out simultaneously as the yawing motion described above. Alternatively, the wind turbine could be adapted to perform said blade pitching strategy without performing the yaw pitch strategy, or vice versa.

Instead of being continuously moved, the blades 6 can be periodically rotated, so that they stay in a fixed position in relation to the wind direction for only a limited time, e.g. less than 30, 10 or 5 seconds, before they are moved in the same angular direction as the direction of the preceding movement to a new angular position. Rotating the blades in any of said manners will avoid them being in load critical areas of the relative wind direction for more than short durations.

Is understood that for the yaw and/or pitch movements during the non-power-producing situation, where grid power is not available, which could be the case during hurricanes, typhoons etc, the yaw and/or pitch drive systems 7, 8 are powered by the backup system 9.

Reference is made to FIG. 3. In another embodiment, for a specific wind turbine model, one or more angular intervals of the wind direction in relation to the nacelle 3 are determined as non-critical load intervals I1, I2, I3. Such non-critical load intervals I1, I2, I3 would differ between turbine models, as they would be dependent on model specific features of construction, materials, dimensions, eigenfrequencies, etc. In this example there are three such intervals of varying orientation and extension but more intervals could be established. The non-critical load intervals I1, I2, I3 could be established by numerical methods, and/or by testing on a wind turbine, for example on a prototype turbine. When the wind speed is high enough, e.g. above a predetermined level, the prototype turbine could be kept at a constant yaw angle in relation to the wind direction for a period of time and at which edgewise oscillations would be monitored. Then the turbine could be yawed a predetermined angular distance, e.g. 10 degrees, and the same monitoring operation could be performed again. This could be continued for all wind relative yaw positions separated by said predetermined angular distance, (e.g. 10 degrees), and for several critical wind speeds until enough data is collected for a representative analysis. Then the data could be analysed, in order to define critical threshold wind speeds and critical wind relative yaw positions. The non-critical load intervals I1, I2, I3 could then be set based on the critical yaw positions.

It should be mentioned that the non-critical load intervals can be site-calibrated. This would allow adjustment for local phenomena. For example, it could be that certain intervals, normally critical, are less critical at a certain site due to wake effects, but it could also be that certain intervals, normally non-critical, show to be more critical because of speed-up effects related to the local topography.

When the turbine is shutdown due to high winds, the wind direction is continuously or periodically monitored, and the nacelle is rotated so that the wind direction in relation to the nacelle and rotor is in one of the non-critical load intervals. It should be noted that at least a part of at least one of the intervals covers relative wind directions different from the direction of the rotor rotational axis, which is the direction usually chosen in prior art. The main parameters to establish the non-critical load intervals are the blade design, i.e. stiffness and strength, the extreme wind speed, inflow angles which result in blade stall induced vibrations due to low aerodynamic damping.

All embodiments above provide simple stand-still load mitigation strategies, which will make it possible to make turbine components lighter and cheaper, since they do not have to be equipped with special vibration dampening devices, or obtain dimensions otherwise required to withstand extreme wind speeds.