CH695790A5 - Wind generator rotor axle is adjustable in pitch and yaw planes towards oncoming wind - Google Patents

Abstract

A wind generator has a two-bladed rotor with a central shaft located within a sleeve. The sleeve is supported at about the mid-point by a pivot joint, allowing for variation of the angle of attack to the oncoming wind (21). The lower part of the pivot joint rests on an upright column that may be rotated in azimuth yaw plane to or from the oncoming wind. The rotor blades further have adjustable tip tabs (24).

Description

       

  The invention relates to a wind turbine according to the preamble of the first patent claim and the method for orientation of a wind turbine for such a wind turbine.

Modern wind turbines have at least one wind turbine, which is rotatable about an approximately horizontal axis of rotation, wherein the axis of rotation is held on a vertical tower. The axis of rotation is rotatable to the tower either automatically or in a direction controlled by the wind in a horizontal plane about a vertical (longitudinal axis of the tower).

This rotation serves on the one hand the tracking of the wind turbine in the wind, on the other hand, but also a gradual off-the-wind leadership in too strong storms.

   The idea is to give the storm less and less attack surface and thus to protect the system.

In many systems, the horizontal axis is slightly inclined from the horizontal. This has primarily the task of preventing the rotor blades of the wind turbine can hit against the tower at high wind pressure. The rotor blades are flexible due to their design and bend in places relatively strong with the wind.

The invention has for its object to provide an improved wind turbine construction, which allows improved wind energy utilization thanks to an alignment of the wind turbine perpendicular to the wind, even if the wind does not blow horizontally, such. at the foot of hills or the like

   The wind turbine should also allow the rotor blades to be placed in low wind again more in the wind, with originally inclined horizontal axis. This object is achieved in that in addition to the rotatable arrangement of the horizontal axis about the vertical, a pivotable arrangement thereof is provided about a horizontal, so that the angle between the horizontal axis and the vertical is adjustable.

By this adjustability can be better responded to a wide variety of wind types. In weak wind, the wind turbine can be made more and more vertical, because the rotor blades bend only slightly towards the tower.

   In strong winds, however, the angle can be increased more and more, so on the one hand more freedom of movement for deflection in the direction of the tower is present, but on the other hand, the wind turbine is more and more taken out of the wind. In contrast to the known off-the-wind take by tilting the wind turbine to the wind direction results from the invention, the advantage that the forces acting on the wind turbine - as long as they are directed into the wind - occur relatively symmetrical to the horizontal axis.

   In addition, fewer demands are made of the lateral pivoting device for rotation about the vertical by the invention, since the windmill according to the invention is also loaded relatively symmetrically to the vertical.

The pivoting of the horizontal axis from the horizontal is so far opposed to the fact that the wind speeds are lower on the ground than in height. The stronger the storm, the more so according to the invention, the wind turbine or the upper rotor blade is removed from the level by tilting or flat spots. The fact that at the same time the wind turbine or the lower rotor blade is brought up from the ground is not compensatory insofar as these resulting bending forces on the tower increase exponentially with the wind speed.

   If the wind turbine or the rotor blades - according to a particular embodiment of the invention - also have a pitch control, so even the wind turbine could still gain energy in the horizontal position by the rotor blades are driven like blades of a paddle wheel. At selected pit inclination, the windmill can also generate vertical forces that push the tower down and thereby increase its resistance to storms.

   With design variants in which the pitch adjustment is adjustable within a 360-degree rotation, can be better selected among the force components occurring, so that e.g. not only in oblique positions, but even in the horizontal position and not only at a standstill, but also in rotation for a drive (tilting of the blades to the wind direction provides on one side of the wind turbine more attack surface than on the other) and / or for a festigenden Pressure on the tower is taken care of.

In extreme cases, the wind turbine - can be pivoted - according to a particular embodiment of the invention - in a horizontal position, which equates to a storm shutdown.

   In wind turbines with a long - horizontally arranged gear generator assembly - the complete horizontal position may be problematic because the generator comes when pivoting near the tower. Therefore, according to a particular embodiment, systems are preferred with a very short generator, which can be swiveled and comes to rest perpendicular to the horizontal position of the rotor blades.

The invention is of course not limited to wind turbines that run in front of the tower, but also includes wind turbines that run after the tower. For these wind turbines, the possible impact of the rotor blades on the tower was not a problem until now, because in windy conditions, these windmills bend their rotor blades away from the tower.

   Regardless of this, a further embodiment of the invention provides the rotor blades with bending sensors, so that, before the occurrence of a critical bending value, wing positions are sought which oppose the wind less attack surface.

According to a particular embodiment, two wind turbines may be provided in the invention, one of which runs in front of the tower and the other after the tower. This idea is known per se, but the combination with the pivoting feature is new. However, upstream and trailing wind turbines can only be adjusted or swiveled at a limited angle.

In the former group and the latter group, however, the invention results in another advantage: So winds that do not run parallel to the ground, can be better detected and exploited.

   This applies in particular wind turbines, which are placed on hills or the like., Where often the wind direction is at an angle to the horizontal (updrafts, winds, etc.). Above all, wind turbines that run after the tower can be used optimally on hilltops in order, for example, to exploit rising winds.

A particular embodiment of the invention provides to use a wind sensor which measures the inclination of the wind to the horizontal and controls a corresponding tracking of the inclination of the horizontal axis of the wind turbine.

After the knowledge of the invention, the expert various solutions for the realization of the pivoting of the wind turbine are familiar. A preferred solution provides to provide a pivot bearing about a horizontal axis above the pivot bearing for the rotation of the horizontal axis about the vertical.

   The pivot bearing is realized for example by a bearing shaft across two lateral bearing walls, which also include means for adjusting the inclination. This can be hydraulic drive cylinder but also gears or the like .. For simple constructions, according to a variant of the invention, the adjustability of the inclination of the horizontal axis may also be restricted to the assembly case, i. that the inclination angle of the horizontal axis is determined during assembly by the fitters and a further adjustment is possible only in the course of a conversion of the system.

In weak winds, the wind is optimally utilized by the invention, since the wind turbine can always be swiveled perpendicular to the effective wind direction and takes place in this vertical position to Windeinfallsrichtung the largest Windkraftausnützung.

   According to a particular embodiment of the invention, the drive shaft of the wind turbine is connected via a universal joint with a transmission or with a generator, so that a pivoting movement of the horizontal axis can also be provided only for the wind turbine, without having to pivot mit gear, generators.

By the invention, the technique of pitch adjustment of rotor blades is basically not necessarily required, i. E. The invention can be applied both to wind turbines with pitch-controlled and non-controlled rotor blades.

Based on embodiments, the invention is illustrated in more detail.
<Tb> FIG. 1 <sep> shows an arrangement according to the invention with rotor blades, generator and swivel joint;


  <Tb> FIG. 2 <sep> the structure of Figure 1 in a pivoted position.


  <Tb> FIG. 3 <sep> a structure with integrated generator and hydraulic swivel control;


  <Tb> FIG. 4 <sep> a special design with 180-degree pivoting;


  <Tb> FIG. 5 <sep> a novel vertical generator design with gimbal force transmission;


  <Tb> FIG. 6 <sep> a detail of a possible pivoting device;


  <Tb> FIG. 7 <sep> a swiveling system with two wind turbines arranged in parallel before and after the wind and


  <Tb> FIG. 8 <sep> the possible internal structure of a system according to FIG. 7.

The figures are described across the board, like reference numerals mean like components, reference numerals with different indices mean functionally similar components. The figures do not limit the scope of the invention.

The principle of the invention is best seen from the difference of Fig. 1 to Fig. 2. On a tower 3 is a pivot bearing 27, which connects the rigid tower 3 with a rotatable upper part 3a. The upper part 3a carries a pivot bearing 9a, through which the rotation axis 6b runs. About this axis of rotation 6b of the upper part 3a is pivotable, which carries a generator 15a. About the axis of rotation 2 of the wind turbine 1, the rotational force of the rotor blades 5 is transmitted to the generator 15 a.

   The axis of rotation 2 of the wind turbine 1, which approximately coincides with the horizontal 6a in the normal operating state, can be swiveled out of this horizontal 6a around the axis of rotation of the swivel joint 6b. The resulting swivel angle 7 is in the present case a few degrees to almost 90 degrees. With appropriate design of the pivot bearing 9a and the generator 15a and larger pivot angle 7 can be achieved. To optimize the pressure and flight conditions, the rotor blades 5 are provided with adjustable rotor blade tips 24 and the upper part 3a for orientation in the wind with a control wing 23rd

A structure according to FIG. 1 can be used so that the rotor blades 5 (in the wind direction 21) run in front of the tower 3, or that the rotor blades 5 run to the tower 3 (wind direction 21a).

   In the case of a wind direction 21b, obliquely from below, it would be advantageous for better wind utilization to pivot the axis of rotation 2 upwards, as shown for example in FIG. On the other hand, results in the position of FIG. 2 and wind direction 21 for the wind a smaller attack surface on the rotor blades 5 and thus a lower load. For the wind direction 21 according to FIG. 2, the position shown is thus a strong-wind position.

Fig. 3 shows a slightly different structure with a wind turbine 1 in front of the tower 3, with a bearing 25 for receiving the horizontal forces and the rotational forces of the wind turbine 1 and an integrated narrow generator 15b. The wind turbine 1 can be pivoted via a hydraulic drive cylinder 12 with its axis of rotation 2 from the horizontal 6a.

   In this case, the upper part 3a of the tower 3 pivots about the pivot bearing 9b.

The upper part 3a together with the hydraulic drive cylinder 12 is pivotable about a pivot bearing 27. All shown bearings and construction elements are shown only symbolically and it is up to the expert to choose optimized components and designs. Symbolically, a sensor 22 is shown, which can measure the wind direction, in particular also in deviation from the horizontal 6a. (See.

   Wind direction 21 in Fig. 3.)

Fig. 4 shows a variant in which the wind turbine 1 is pivotable over a greater angle than 90 degrees, so that it can optionally run once before the tower and another time after the tower.

In the construction according to FIG. 5, a gimbal drive is provided for transmitting torque from the rotor blades 5 to the generator 15 with - in this case - two universal joints 26a and 26b and a transmission shaft 28.

Fig. 6 shows in a detail sketch a possible pivoting device 8 with lateral bearing cheeks 20, the inner support cheeks 29 are supported or serve for a gear drive 13 as a support. A rotation of the gear 13 leads to a relative pivoting of the support cheeks 29 relative to the lateral bearing cheeks 20th

   As with the previous training, the upper part 3a of the tower 3 is mounted with the pivoting device 8 on a rotary bearing 27, so that the wind turbines by pivoting about the vertical 4 - as is well known - can be turned into the wind.

In Fig. 7, the machine house 16 is shown schematically with wind wheels 1 and 1a on each side. It is pivotally mounted on the pivot bearing 9a and rotatably mounted on the bearing 27. For automatic alignment in the wind 16 control wings 23 and 23 may be arranged on the machine house.

   The size of the pivoting angle 7 is dependent on the overhangs L1 and L2, with short overhangs the possible pivot angle 7 remains low because the rotor blades 5 and 5a then touch the tower earlier.

Fig. 8 shows schematically the arrangement of the generators 15c and 15d in the machine house 16, wherein the two generators 15c and 15d are connected in the illustrated version by means of a connecting shaft 30 with each other, but the wind wheels 1 and 1a are also autonomously operable from each other, but on the same axis of rotation 2 lying about the hinge 9a pivotally.

LIST OF REFERENCE NUMBERS

[0027]
1: windmill
1a: wind turbine
2: rotation axis of the wind turbine
3: tower
3a: top part of the tower
4: vertical
5: rotor blade
5a: rotor blade
6a: horizontal
6b: rotation axis of the pivot joint
7: swivel angle
8: swivel device
9a: pivot bearing
9b: pivot bearing
12:

   drive cylinder
13: gear drive
15a: generator
15b: generator
15c: generator
15d: generator
16: machine house
20: bearing cheek
21a: wind direction a
21b: wind direction b
22: sensor
23: control wing
23a: control wing
24: Adjustable rotor blade tip
25: bearings
26a: Cardan joint
26b: Cardan joint
27: pivot bearing
28: transmission wave
29: Support cheek
30: connecting shaft
L1, L2: Overhangs


    

Claims (11)

1. Wind turbine with at least one wind turbine (1, 1a) with a generator (15c, 15d) in a machine house (16) and a tower (3), said windmill (1,1a) with its axis of rotation (2) from the horizontal (6a) about the axis (6b) of a pivot bearing (9a) is pivotable, characterized in that the pivot angle (7) between the rotation axis (2) and the horizontal (6a) is adjustable. 2. Wind turbine according to claim 1, characterized in that the adjustability by means of control loop - preferably sensor-controlled - is controllable. 3. Wind power plant according to claim 1 or 2, characterized in that the horizontal axis together with the machine house (16) about a horizontal pivot axis (6b) from the vertical position of the wind turbine (1) is pivotally maximum over the horizontal position to the opposite vertical position. 4. Wind turbine according to claim 3, characterized in that for the adjustability or for the pivoting of the axis of rotation (2) of the wind turbine (1) or the wind wheels (1, 1 a) an electromechanical or electropneumatic drive (12) is provided. 5. Wind turbine according to claim 4, characterized in that the pivoting of the axis of rotation (2) by means of a pivoting device (8) with a gear drive (13) and pivotable bearing cheeks (20). 6. Wind turbine according to one of the preceding claims, characterized in that the rotor blades (5) within a 360-degree rotation along its longitudinal axis (pitch adjustment) are periodically adjustable. 7. Wind turbine according to one of the preceding claims, characterized in that the rotor blades (5) are adjustable so that in strong winds, a stabilizing pressure on the tower (3) is exercised. 8. Wind turbine according to one of the preceding claims, characterized in that the rotor blades (5) are equipped with bending sensors whose data flow into an ongoing optimization of the sash position. 9. Wind turbine according to one of the preceding claims, characterized in that the rotor blades (5) formed like blades or by means of the adjustable rotor blade tips (24) are deformable, whereby the rotor blades (5) are driven like blades of a paddle wheel, so that the wind turbine (1) Turns even in angled positions and / or the horizontal position and ensures energy. 10. A method for orienting a wind turbine (1) of a wind turbine according to one of the preceding claims, characterized in that the wind wheel (1) in dependence on the wind strength and / or in dependence on the deviation of the wind direction (21) from the horizontal (6a ) is adjusted or pivoted about a pivot axis (6b). 11. The method according to claim 10, characterized in that the deviation of the wind direction (21) from the horizontal (6a) by means of sensor (22) is measured and that the pivot position of the wind turbine (1) is controlled by a control loop, the wind speed and / or the wind inclination as a parameter taken into account.