NL2000821C2 - Wind turbine and rotor blade. - Google Patents

Description

Wind turbine and rotor blade

The invention relates to a wind turbine comprising a rotor with a number of rotor blades, each having a front edge and a rear edge.

5 A wind turbine produces noise during operation. The noise production can cause nuisance, especially when applied on land. The noise nuisance depends on the distance to the wind turbine - by placing the wind turbine further away, the noise level decreases. However, this reduces the surface area available for wind energy. In addition, the speed of the wind turbine can be limited in order to reduce the noise production. As a result, the efficiency of the wind turbine and the power produced are adversely affected.

A considerable part of the noise production of a wind turbine is caused by the sound of the rear edges of the rotor blades when the rotor revolves - the so-called rear edge noise. NL9301910 discloses a wind turbine 15 with a number of rotor blades, the rear edges of which have a saw-tooth shape to reduce the noise production. However, the sawtooth shape gives rise to power loss and sound increase in circumstances that deviate from the design specifications.

An object of the invention is to provide a wind turbine that reduces the trailing edge noise while substantially maintaining the power.

This object is achieved according to the invention in that at least one rotor blade is provided with a series of openings which are arranged near the rear edge, as well as fluid displacement means for forcing fluid outwardly and inwardly through these openings.

The fluid displacement means according to the invention generate so-called "synthetic jets" from the openings near the rear edge. The synthetic jets are used according to the invention to reduce the trailing edge noise. A "synthetic jet" includes a series of vortices that are formed by alternately blowing out and sucking fluid through an opening. Each opening directs such a series of swirls in the flow around the rotor blade. The swirls of the synthetic jets influence that flow in such a way that the structure of the turbulent boundary layer and the wake behind the rear edge of the rotor blade are changed. This reduces the noise production of the rear edge. Since the flow around the rotor blade hardly changes further, the power produced by the wind turbine remains substantially the same.

A further advantage is the reduced risk of damage compared to the known rotor blades with relatively vulnerable saw-toothed rear edges.

It is noted that "synthetic jets" are known per se. However, according to the invention, "synthetic jets" are used to reduce noise production.

The rotor blade has, for example, a root end connected to a hub of the rotor. The rotor blade protrudes radially outwards from the hub over a span width to a tip end. The longitudinal direction of the rotor blade runs between the root end and the tip end. The rotor blade comprises, in cross section, an aerodynamic profile shape with a cord defined by a straight line between the front edge and the rear edge of that profile shape. The profile shape may differ in the longitudinal direction of the rotor blade. In that case, the profile shape and its cord depend on the distance from the rotor hub.

The openings can be designed according to the invention in various ways. For example, the openings are each designed to force out fluid in an outflow direction that has a component parallel to the cord. The "synthetic jets" then essentially have no speed component 20 transversely of the rotor blade. The swirls of the "synthetic jets" are puffed out substantially smoothly with respect to the flow. The vortices can herein also have a speed component in the longitudinal direction of the rotor blade.

Preferably, the outflow direction in which the fluid is forced out of the openings is substantially parallel to the cord. The openings are in this case directed rearwards, i.e. the fluid puffed out of the openings flows substantially parallel to the flow around the rotor blade. This is favorable for reducing the trailing edge noise.

In one embodiment the openings in the longitudinal direction of the rotor blade are arranged at a distance from each other. For example, the openings are at substantially equal distances from each other. The distance between two adjacent openings in each case is substantially the same in this case. The openings are therefore regularly and / or homogeneously distributed in the longitudinal direction of the rotor blade.

3

According to the invention, it is possible that the distance between the openings substantially corresponds to 0.1-5% of the cord, such as 0.5-2% of the cord. The distance between the openings is such that the synthetic jets from the openings influence each other. An effective reduction of the trailing edge noise is achieved through interaction of the synthetic jets from different openings.

In one embodiment of the invention, the fluid displacement means are adapted to force fluid outwardly and inwardly through the openings at a frequency of 50-5000 Hz, such as 50-500 Hz. The synthetic jets at these frequencies are particularly effective at reducing trailing edge noise. According to the invention, it is possible for the fluid displacement means to be controllable depending on a signal detected by a sensor. The fluid displacement means are controllable by a control unit. The sensor and / or the control unit can be located inside the rotor blade, but can also be arranged outside of it.

In a special embodiment, each rotor blade is provided with a sensor, and the fluid displacement means of each rotor blade are controllable depending on the signal detected by the sensor of that rotor blade. The rotor blades each have a local sensor. The fluid displacement means of the respective rotor blades are operated on the basis of locally observed quantities.

The control unit can control the fluid displacement means in various ways. For example, the fluid displacement means are switchable and switchable. The frequency of the fluid displacement means can also be controlled.

The sensor can be designed for detecting wind speed and / or wind direction. At high wind speeds, the trailing edge noise does not exceed the ambient noise of the wind. The synthetic jets can then be switched off. Also, the trailing edge noise is sometimes only annoying in certain wind directions, for example if there are only buildings in a limited area around the wind turbine. In those wind directions, the use of synthetic jets is then particularly suitable.

In one embodiment, each rotor blade has an azimuth angle determined by the angle from the upwardly directed vertical to that rotor blade viewed in the direction of rotation, and the sensor is designed for detecting the azimuth angle, and the control unit is designed for switching on the fluid displacement means at an azimuth angle between 0-180 ° and switching off the fluid displacement means at an azimuth angle outside it. The rotor blades produce the most sound in the first and second quadrant, i.e. when the rotor blades move downwards. In that area, the control unit can turn on the fluid displacement means to generate "synthetic jets," while no "synthetic jets" are puffed out as the rotor blades rotate.

In one embodiment the control unit is designed for determining the frequency of the fluid displacement means. For example, the control unit 10 comprises an electrical control. The control unit can be designed to impose a fixed frequency. Alternatively, the frequency is variable and / or adjustable by the control unit, for example based on a signal from the sensor as indicated above.

In one embodiment, the fluid displacement means are arranged for forcing fluid out through a first group of the openings and simultaneously forcing fluid through a second group of the openings during a first period of time, and forcing fluid in through the first group of the openings and simultaneously forcing out fluid through the second group of the openings during a second period of time after the first period of time. This allows the influence of the synthetic jets on the flow around the rotor blade to be accurately adjusted.

The fluid displacement means can be designed in various ways. For example, the fluid displacement means are provided with at least one fluid chamber, which is arranged inside the rotor blade and connected to at least one opening, the fluid chamber being provided with means for changing the volume of the fluid chamber for forcing it in and out of fluid through the associated opening. It is thereby possible for several fluid chambers to be provided, each of which is connected to one or more openings.

For example, the means for changing the volume of the fluid chamber comprises a flexible membrane. Each fluid chamber is formed by an internal cavity in the rotor blade. Each fluid chamber has a volume that is, for example, limited by the opening and the flexible membrane. The flexible membrane is energizable. By distorting the flexible membrane towards the opening, i.e. outwards, the volume is reduced. Hereby an amount of fluid is pushed out of the fluid chamber to form a vortex. The fluid flows "straight" out of the opening during extraction. The flexible membrane is subsequently deformed, so that the volume of the fluid chamber increases. This creates an underpressure in the fluid chamber, so that fluid is sucked in from outside the opening. This leads to a mass flow into the fluid chamber. The fluid then flows along the surface of the rotor blade to the opening and deflects inwards. The net mass flow flux through the opening is zero. The flexible membrane can then move outwards again to generate a further swirl. The concatenation of swirls forms a "synthetic jet".

Instead of the flexible membrane, the fluid displacement means may comprise a piston which is reciprocally movable in the fluid chamber for generating vortices. Other embodiments for generating synthetic jets are also possible according to the invention.

According to the invention, it is possible that a fluid chamber or a plurality of fluid chambers are provided. For example, a plurality of openings are connected to a common elongate fluid chamber.

In one embodiment, the means for changing the volume of the fluid chamber, such as the flexible membrane or other driver, divides the fluid chamber into two sub-chambers, the first sub-chamber being connected to a first opening and the second sub-chamber being connected to a second opening. During the deformation of the flexible membrane in one direction, the volume of the first sub-chamber decreases and the volume of the second sub-chamber increases. The first opening, which is connected to the first sub-chamber, thereby ejects a quantity of fluid. At the same time, the second sub-chamber draws fluid in through the second opening. When the flexible membrane is subsequently moved in an opposite direction, fluid flows through the first opening into the first sub-chamber, while a vortex leaves the second opening.

The invention also relates to a rotor with a number of rotor blades, each having a front edge and a rear edge. The invention further relates to a rotor blade with a front edge and a rear edge. According to the invention, a series of openings is provided, which are arranged near the rear edge, as well as 6 fluid displacement means for forcing fluid outwardly and inwardly through said openings.

The invention will now be further explained by way of example only with reference to the accompanying drawing.

Figure 1 shows a perspective view of a wind turbine comprising a rotor with a number of rotor blades according to the invention.

Figure 2 shows a perspective view, partially in cross-section, of a rotor blade of the wind turbine shown in Figure 1.

Figure 3 shows a partially cut-away top view of a second embodiment of a rotor blade according to the invention.

The wind turbine shown in Figure 1 is indicated in its entirety by 1. In this exemplary embodiment, the wind turbine 1 is mounted on land. The wind turbine 1 comprises a mast 8 and a rotor 2, which is rotatably connected to the mast 8 about a rotation axis.

The rotor 2 comprises a hub 9 and a number of rotor blades 3,4,5. Although the rotor 2 in this exemplary embodiment has three rotor blades, more or fewer rotor blades can be provided. Each rotor blade 3, 4, 5 has a root end and a tip end. The root end is attached to the hub 9, while the tip end opposite is free. Each rotor blade 3,4,5 has a longitudinal direction that extends from the root end to the tip end.

Each rotor blade 3, 4, 5 comprises a front edge 7 and a rear edge 6, viewed in the direction of rotation of the rotor 2. During the rotation of the rotor 2, the rear edges 6 of the rotor blades produce noise. The trailing edge noise is caused by reflection of turbulence in the boundary layer on the trailing edge 6 of each rotor blade. The noise production increases the thicker the turbulent boundary layer. To reduce the trailing edge noise, each rotor blade 3, 4, 5 has a series of openings 12, which in this exemplary embodiment are arranged in the trailing edge 6. However, the openings can be arranged near the trailing edge 6 in the rotor blade surface on the low pressure side and / or high pressure side (not shown). A combination with openings in the rear edge 6, as shown in Figure 2, is also possible.

30 Synthetic jets flow out of openings 12, i.e. a series of swirls. The vortices influence the flow around the rotor blade such that the thickness of the turbulent boundary layer on the rear edge 6 of each rotor blade 3, 4, 5 decreases. As a result, the noise production of the trailing edge 6 during the rotation of 7 reduces the rotor 2. Since the flow around the rotor blade hardly changes further, the power produced by the wind turbine remains substantially the same.

The synthetic jets at the trailing edge 6 therefore form sound reducing means for reducing the noise caused by the rotor blade during the rotation of the rotor 2. For generating the synthetic jets, the rotor blades 3, 4, 5 comprise fluid displacement means for forcing fluid in and out through the openings 12 alternately.

In this exemplary embodiment, the fluid displacement means comprise a plurality of fluid chambers 15, which are each connected via a channel 14 to the openings 12. Each fluid chamber 15 is provided with a flexible membrane 16, which can be deformed by a control unit 17 (see the dotted line and the dashed line in 2 and 3). The control unit 17 vibrates the flexible membrane 16. The vibration frequency is, for example, between 50-300 Hz. As the flexible membrane 16 moves from a fluid chamber 15 to the opening 12 connected thereto, the volume 15 of the fluid chamber 15 decreases. A quantity of fluid is hereby driven out of said opening 12. This results in a slight swirl at the opening 12, which opens at the rear edge 6.

After the vortex has been extracted, the flexible membrane 16 moves away from the opening 12. After all, the flexible membrane 16 performs a vibration. This means that the volume of the fluid chamber 15 increases, and fluid is sucked in from outside the rotor blade through the opening 12. As a result, the fluid in the fluid chamber 15 is supplemented, so that the mass flow flux through the opening 12 is substantially equal to zero.

The control unit 17 then returns the flexible membrane 16 in the direction of the opening 12 to form a further swirl. Vibrating the flexible membrane 16 creates a succession of swirls from the openings 12. The fluid displacement means determine the frequency with which the swirls are puffed out of the opening 12. Through interaction of the swirls, each concatenation forms a "synthetic jet". The fluid driven out of the aperture 12 comprises the fluid surrounding the rotor blades 3,4,5, such as air.

As shown in Figure 2, the openings 12 are at equal distances a from each other. The distance a between the openings is, for example, about 1% or 1.5% of the cord c, which is defined by the distance from the front edge 7 to the rear edge 8. The synthetic jets from adjacent openings 12 influence each other, so that the trailing edge noise is effectively counteracted.

The apertures 12 are oriented such that during the extraction fluid flows out of the fluid chamber 15 substantially parallel to the cord c in the flow around the rotor blade. This is favorable for maintaining the produced power of the wind turbine 1. However, the fluid flowing out of the openings 12 can have a speed component in the longitudinal direction of the rotor blade. It is even possible that the fluid from the openings 12 flows slightly up or down (not shown).

Figure 3 shows an embodiment in which the fluid chambers 15 each comprise two sub-chambers 19,20, which are mutually separated by the flexible membrane 16. During the execution of the vibration through the membranes 16, which is controlled by the control unit 17, fluid is discharged from the sub-chambers 19 are pushed out of a first group of openings 12 and, at the same time, fluid is sucked into the sub-chambers 20 from outside the rotor blade via a second group of openings 12. This causes the frequency of the swirls from adjacent openings 12 to shift relative to each other.

The invention is not limited to the exemplary embodiments shown in the figures. For example, each rotor blade comprises one or more fluid chambers that are connected to one or more openings. The flexible membrane can also be replaced by any driver for expelling fluid or means for changing the volume of the fluid chamber, such as a piston movable in the fluid chamber. In addition, the invention relates to any aerodynamic object that rotates in a fluid and thereby produces sound, such as a rotor blade of a propeller, helicopter or jet engine.

Claims (22)

Wind turbine (1) comprising a rotor (2) with a number of rotor blades (3, 4, 5), each having a front edge (7) and a rear edge (6), characterized in that at least 5 a rotor blade ( 3, 4, 5) is provided with a series of openings (12) which are arranged near the rear edge (6), as well as fluid displacement means for forcing fluid outwardly and inwardly through said openings (12). 2. Wind turbine according to claim 1, wherein the rotor blade (3,4,5) has a cord in cross-section that extends between the front edge (7) and the rear edge (6). 3. Wind turbine according to claim 1 or 2, wherein each opening (12) is arranged in the rear edge (6) or at a distance from the rear edge (6) that is less than 10% of the chord. Wind turbine according to claim 2 or 3, wherein each opening (12) is designed for forcing out fluid in an outflow direction that has a component parallel to the cord. 20 5. Wind turbine according to claim 4, wherein the outflow direction extends substantially parallel to the cord. 6. Wind turbine as claimed in any of the foregoing claims, wherein the rotor blade (3, 4, 5) has a longitudinal direction, and wherein the openings (12) are arranged at a distance from each other in the longitudinal direction. The wind turbine according to claim 6, wherein the openings (12) are at substantially equal distances from each other. 30 A wind turbine according to claim 6 or 7 as far as dependent on claim 2, wherein the distance between the openings (12) substantially corresponds to 0.1-5% of the cord, such as 0.5-2% of the cord. A wind turbine according to any one of the preceding claims, wherein the fluid displacement means are arranged for forcing fluid with a frequency of 50-5000 Hz, such as 50-500 Hz, alternately through the openings (12). A wind turbine according to any one of the preceding claims, wherein the fluid displacement means are controllable depending on a signal detected by a sensor. The wind turbine according to claim 10, wherein each rotor blade (3, 4, 5) is provided with a sensor, and wherein the fluid displacement means of each rotor blade (3, 4, 5) are controllable depending on the signal detected by the sensor of that rotor blade (3, 4, 5). 15 A wind turbine according to claim 10 or 11, wherein the fluid displacement means of each rotor blade (3, 4, 5) can be switched on and off. 13. Wind turbine according to one of claims 10-12, wherein the sensor is designed for detecting wind speed and / or wind direction. 14. Wind turbine according to claim 11 or 12, wherein each rotor blade (3, 5, 5) has an azimuth angle determined by the angle from the vertical to that rotor blade (3, 5, 5) viewed in the direction of rotation, and wherein the sensor is designed to detect the azimuth angle, and the control unit (17) is arranged to switch on the fluid displacement means at an azimuth angle between 60-180 ° and to switch off the fluid displacement means at an azimuth angle outside it. A wind turbine according to any one of the preceding claims, wherein the fluid displacement means are arranged for forcing fluid out through a first group of openings (12) and simultaneously forcing fluid through a second group of openings (12) during a first time period, and forcing fluid through the first group of openings (12) and simultaneously forcing out fluid through the second group of openings (12) during a second time period after the first time period. Wind turbine according to one of the preceding claims, wherein the fluid displacement means are provided with at least one fluid chamber (15) which is arranged inside the rotor blade (3, 4, 5) and connected to at least one opening (12), and wherein the fluid chamber (15) is provided with means for changing the volume of the fluid chamber (15) for forcing fluid outward and inward through the opening (12) connected thereto. The wind turbine of claim 16, wherein the means for changing the volume of the fluid chamber (15) comprises a flexible membrane (16). A wind turbine according to claim 16 or 17, wherein the means for changing the volume of the fluid chamber (15) divides the fluid chamber (15) into two sub-chambers (19,20), and wherein the first sub-chamber (19) is connected to a first opening (12) and the second sub-chamber (20) is connected to a second opening (12). 20 A rotor with a number of rotor blades (3, 4, 5), each of which has a front edge (7) and a rear edge (6), characterized in that at least one rotor blade (3,4, 5) is provided with a a series of openings (12) which are arranged near the rear edge (6), as well as fluid displacement means for forcing fluid inwardly and inwardly through said openings (12). Rotor blade, comprising a front edge (7) and a rear edge (6), characterized in that the rotor blade (3, 4, 5) is provided with a series of openings (12) arranged near the rear edge (6) as well as fluid displacement means for forcing fluid outwardly and inwardly through said openings (12). A method for operating a wind turbine according to any of claims 1-18. 22. Method as claimed in claim 21, wherein a quantity, such as wind speed and / or wind direction, is detected by a sensor, a signal corresponding to that quantity detected by the sensor is transmitted to a control unit, and the fluid displacement means are controlled by the control unit depending on that signal.