DE29706980U1 - Gondola of a wind turbine - Google Patents

Description

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Applicant: Kassel, 15 April 1997 rw/st

Walter SCHULTE Attorney File 17151

Eikenberg No. 46
D-37688 Beverungen

Representative:
Patent attorneys
Walther · Walther & Hinz
Heimradstrasse 2
D-34130 Kassel

Nacelle of a wind turbine

The invention relates to a nacelle of a wind turbine, comprising a rotor arranged at one end of the nacelle and a generator that can be coupled to the rotor.

Wind turbines of the type mentioned above are well known; the nacelle containing the rotor and generator is arranged on a mast or tower. Three-bladed rotors are usually used here, as these ensure relatively even running. However, it has now been shown that, particularly for systems in the megawatt range - systems up to 1.5 MW are actually manufactured in series - a rotor diameter of over 60 m is common. Such rotors have a very high dead weight, which means that the bearings on the generator are subject to an immensely high load. In addition, the high weight of the rotor and the distance of the rotor from the center of the tower on which the nacelle is rotatably mounted result in a considerable moment on the tower, which has a direct impact on the dimensioning of the tower and thus on the overall costs.

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knocks down.

The invention is therefore based on the object of creating a nacelle of a wind turbine of the type mentioned at the beginning, in which the occurring forces - and here in particular the forces acting on the bearings - and possibly also the individual components of the wind turbine, such as the tower, can be minimized in their dimensions.

The object is achieved according to the invention in that the nacelle has a second rotor that can be attached to the other, opposite end of the nacelle, whereby this second rotor can be coupled to the generator. It has been shown that such a tandem arrangement of two rotors on a nacelle can achieve increased smoothness. A faster and smoother start-up of the rotors is made possible in particular by the fact that the rotors each have only two blades. Nevertheless, the wind yield is greater than with a single three-bladed rotor arranged on a nacelle. Of course, the rotor blades of the two rotors must have the same angle to the wind. It is also important that the tandem arrangement of the rotors can reduce the forces on the bearings for the rotors arranged in the area of the generator, particularly in connection with the use of two-blade rotors. The reason for this is that the weight of the individual rotors is less than that of a three-bladed rotor, although the power output is greater when using two rotors with two blades each - so there are four blades in the wind in total - than with a single three-bladed rotor. In addition, the force applied to the tower is more favourable in that the moments of the two rotors in relation to the forces acting on the tower essentially balance each other out. Significant manufacturing costs can be saved, particularly by reducing the bearing forces and by reducing the load on the tower.

The

It has proven to be particularly advantageous if the two rotors are attached to the nacelle in such a way that the rotor blades of the two rotors are offset from each other by 90 degrees, as this enables a much faster and smoother start-up, as already mentioned at the beginning. In addition, the wind losses are also lower than if the blades of the rotors were arranged one behind the other on the nacelle, covering each other.

The blades of the rotors are advantageously adjustable in order to take the wind pressure off the rotors in strong winds in order to prevent the rotor blades from being destroyed. According to a special feature of the invention, the rotors have blades of different sizes, whereby it can be achieved that if the blades of the rear rotor, i.e. the rotor that is arranged on the side of the nacelle facing away from the wind, are larger than those of the front rotor, then the nacelle turns into the wind by itself. The same effect can of course also be achieved if the blades of the rear rotor, in contrast to the blades of the front rotor, offer the wind a larger surface area to attack.

According to a special feature of the invention, it is provided that the nacelle has several generators arranged in series. The structural design can be such that the generators can be coupled to the rotor or rotors in such a way that a further generator can be connected to the generator already running. In detail, this is done in such a way that in light winds only one generator is advantageously coupled to the two rotors. If the wind speed increases, a further generator and possibly a third generator can be connected. In order to enable individual generators to be connected independently, the two rotors can be connected by a main shaft, with the other generators connected in series to the first generator having hollow shafts.

which can be coupled to the main shaft via couplings. In this case, the main shaft in the area of the generator, which can always be driven, can be coupled to this generator via a coupling. The coupling is advantageously arranged after the generator on the main shaft, which can be driven permanently. In order not to transfer bending moments, which inevitably occur with such a long main shaft, to the rotors of the generators, the main shaft is mounted on a cardanic bearing.

Permanently excited four-pole generators are particularly suitable as generators for a gearless drive, since these generators supply electrical energy even at low speeds. Such motors have the further advantage that they are lighter than externally excited motors. In addition, as already explained above, such permanently excited four-pole generators do not require a gear. Furthermore, the nacelle according to the invention can be equipped with an electric motor, which not only causes the nacelle to track when the wind is changing, but also offers the possibility of tilting the nacelle towards the wind so that the rotor blades are no longer driven by the wind. This produces the same effect as if the rotor blades were adjusted accordingly, although turning the nacelle using an electric motor is much easier than adjusting the individual rotor blades. It is also intended to use braking systems to stop the rotors if the wind is too strong or during maintenance work. Electromagnetically actuated disc brakes can be used for example; Electrohydraulic braking systems are also possible, whereby an electric motor in conjunction with a gear unit feeds the brake shoes onto the disk of a disk brake, whereby the disk is arranged on the rotor shaft. With a clutch installed in the area of a continuously driven generator, two braking systems are provided, since when the clutch is disengaged, for whatever reason, each rotor must be able to be braked. This means that one

Braking system arranged at each end of the main shaft to allow each rotor to be stopped individually.

The invention is explained in more detail below by way of example with reference to the drawings.

Figure 1 shows the gondola in a side view;

Figure 2 shows a front view.

According to Figures 1 and 2, the nacelle, designated as 1, rests on the tower 10. The tower 10 is connected to the nacelle 1 by a slewing ring 20, which is connected to an electric motor 21 by means of a pinion, whereby the motor 21 serves to rotate the nacelle relative to the tower. This means that with the help of the motor 21 in conjunction with the slewing ring of the tower 10, it is possible, as is actually known, to guide the nacelle to the wind when the wind is rotating or, if the wind is too strong, to rotate the nacelle out of the wind so that the rotor blades are no longer exposed to the wind force.

The nacelle 1 comprises a housing 2, whereby the housing 2 has a pair of rotors 30, 40 at each end, whereby the two pairs of rotors are arranged on the nacelle in such a way that the rotor blades 31, 32; 41, 42 are each offset by 90° to one another (Figure 2). In the housing 2 of the nacelle 1, there are also three generators 50, 60 and 70, which are connected in series. The two rotors 30, 40 can be coupled to one another by a shaft, whereby this shaft, also referred to as the main shaft 80, is essentially constantly coupled to the generator 50. However, the main shaft 80 can be divided by the coupling 51, so that each rotor 30 or 40 can be separately fixed by the two brakes 100 or 110. The brakes 100 and 110 each show an electric motor 101 and 111 with a spindle drive, whereby the

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Spindle drive brake shoes are moved towards the brake discs.

When the wind increases, the generators 60 and 70 are then switched on via the couplings 61 and 71. In terms of design, it is specifically provided that in the area of the generators 60 and 70 the rotors of the generators are coupled to a hollow shaft 63, 73, which has an inner diameter that is dimensioned such that the main shaft 80 can be guided through these hollow shafts 63, 73. The hollow shafts are each connected at one end to one coupling half of the coupling 61 or 71, and can be coupled to the other coupling half of the coupling 61 or 71, which are attached to the main shaft 80.

Claims (12)

Expectations 1. Nacelle of a wind turbine, comprising a rotor (40) arranged at one end of the nacelle (1) and a generator (50) that can be coupled to the rotor (40), characterized in that the nacelle {1} has a second rotor (30) that can be attached to the other, opposite end of the nacelle (1), this second rotor (30) being able to be coupled to the generator (50). 2. Gondola according to claim 1, characterized in that the rotors (30, 40) are designed as two-blade rotors. 3. Gondola according to claim 1, characterized in that the rotor blades (31, 32; 41, 42) of the two rotors (30, 40) have the same angle to the wind. 4. Nacelle according to one of the preceding claims, characterized in that the two rotors (30, 40) can be attached to the nacelle (1) in such a way that the rotor blades (31, 32; 41, 42) of the two rotors (30, 40) are offset from one another by 90 degrees. 5. Nacelle according to one of the preceding claims, characterized in that the blades (31, 32; 41, 42) of the rotors (30, 40) are adjustable. 6. Nacelle according to one of the preceding claims, characterized in that the blades (31, 32; 41, 42) of the rotors (30, 40) have a different size. 7. Nacelle according to one of the preceding claims, characterized in that the nacelle (1) has several generators (50, 60, 70) arranged in series. 8. Nacelle according to one of the preceding claims, characterized in that the generators (60, 70) can be coupled to the rotor or rotors (30, 40) in such a way that a further generator (60, 70) can be connected to the generator (50) already running. 9. Nacelle according to one of the preceding claims, characterized in that the two rotors (30, 40) can be connected by a main shaft (80), whereby further generators (60, 70) connected in series with the first generator (50) have hollow shafts (63, 73) which can be coupled to the main shaft (80) via couplings (61, 71). 10. Nacelle according to one of the preceding claims, characterized in that the main shaft (80) is cardanically mounted. 11. Nacelle according to one of the preceding claims, characterized in that the main shaft (80) can be coupled to one of the generators (50) that is located closest to the respective rotor (40). 12. Nacelle according to one of the preceding claims, characterized in that each rotor (30, 40) is assigned a braking system (100, 110).