EP3759345A1

EP3759345A1 - Generator for a wind turbine, wind turbine comprising same, method for locking a generator, and use of a locking device

Info

Publication number: EP3759345A1
Application number: EP19708822.2A
Authority: EP
Inventors: Frank SAATHOFF
Original assignee: Wobben Properties GmbH
Current assignee: Wobben Properties GmbH
Priority date: 2018-02-28
Filing date: 2019-02-28
Publication date: 2021-01-06
Also published as: US20210048000A1; WO2019166552A1; CN112041559A; DE102018104627A1

Abstract

The invention relates to a generator, in particular a generator (120) for a wind turbine, comprising a rotatably mounted generator rotor; a generator stator which corresponds to the generator rotor (121) and which has a support structure (123) for securing in the wind turbine (100); and at least one locking device which can be coupled between the generator rotor (121) and the generator stator (122) such that a force flow between the generator rotor (121) and the generator stator (122) is produced and which is designed to lock the generator rotor (121) relative to the generator stator (122) in a specified position in the coupled state. According to the invention, the locking device (130) has a damping element (131) which is designed to have a variable shape so as to deform as a result of the force flow between the generator rotor (121) and the generator stator (122).

Description

Generator of a wind turbine, wind turbine with selbigem,

Method for locking a generator and use of a

locking device

The present invention relates to a generator, in particular a generator of a wind turbine with a rotatably mounted generator rotor, a generator stator corresponding to the generator stator having a support structure for attachment to the wind turbine, and at least one locking device which can be coupled between generator rotor and generator stator in that a force flow arises between the generator rotor and generator stator, and which is set up in the coupled state to lock the generator rotor relative to the generator stator in a predetermined position. Furthermore, the invention relates to a wind turbine with selbigem. Furthermore, the invention relates to a method for locking a rotor, a generator and the use of a locking device.

Wind turbines are well known. They are used to record wind energy by means of rotor blades and convert it into electrical energy by means of the generator. In this case, the generator comprises a generator stator, which has a support structure for attachment in the wind power plant, and a generator rotor, which is operatively connected to the rotor of the wind power plant. The generator rotor is rotated relative to the generator stator. Due to the relative rotation of the generator rotor to

Generator stator is generated electric current, so that the kinetic energy of the wind is converted into electrical energy. The occurring magnetic interactions can lead to the formation of audible narrow-band sounds, which creates an additional acoustic burden on the environment.

To combat this unwanted noise, the wind turbine is the subject of vibration testing. The vibration characteristics of generators, for example, are captured by modal analyzes, with the aim of a far-reaching assessment of the expected life of the generator and the potential impact on the environment.

When carrying out modal analyzes, in particular experimental modal analyzes, a defined external excitation is applied. The vibration behavior of the individual components of a module is detected and analyzed by sensors.

In a modal analysis of wind turbines, it is necessary for safety reasons to lock the generator rotor relative to the generator stator. Locking devices are known from the prior art which can be brought into positive engagement with the generator rotor and prevent it from rotating about a horizontal axis. The locking devices known from the prior art have the particular aim of providing a secure locking. This is explained in particular by the fact that appropriate safety precautions should be taken to work for persons working on the wind turbines. Therefore, in known in the prior art Rotorarretiervorrichtungen primarily combinations of bolts and corresponding openings are provided.

The known from the prior art locking devices can provide a secure rigid locking of the rotor, however, this rigid connection of generator rotor and generator stator leads to a superposition of Vibrations of both components, whereby the result of a modal analysis is falsified.

It was therefore an object of the present invention, in generators of wind turbines of the type described above, to overcome the disadvantages found in the prior art as much as possible. The invention was in particular the object of providing a generator with a locking device which locks the generator rotor relative to the generator stator in a predetermined position and at the same time minimizes the transmission of vibrations of the generator rotor to the generator stator. In any case, the invention was based on the object of specifying an alternative generator.

The invention solves the underlying problem by proposing a generator with the features of claim 1. In particular, the invention proposes that the locking device has a damping element, which is designed such variable in shape that it deforms due to the power flow between the generator rotor and generator stator.

The generator according to the invention can be used both in wind turbines, which are operated without gear and in wind turbines, which have a transmission. The damping element of the locking device, which is designed so that it deforms due to the power flow between the generator rotor and generator stator, thus dampens the vibrations of the generator rotor and the generator stator and prevents the generation of a resonant vibration. The coupling of the locking device between generator rotor and generator stator can be done both positive and non-positive. Due to the resulting force flow between the generator rotor and generator stator, the rotation of the generator rotor relative to the generator stator is prevented. In a preferred embodiment of the generator according to the invention, the damping element is embodied in such a form variable manner that the generator rotor can be moved in the radial direction relative to the generator stator. According to the invention, a detent is thus proposed which does not hinder the oscillation behavior of the generator rotor and generator stator in the radial direction as far as possible, and thus influences the measured values of a modal analysis, such as the natural frequency, only to a small extent.

The damping element of the present invention is advantageously further developed in that it is designed in such a form variable that the generator rotor is movable in the axial direction relative to the generator stator. According to the invention, a locking is thus proposed, which the

Oscillation behavior of generator rotor and generator stator in the axial direction largely unimpeded and thus the measured values of a modal analysis, such as the natural frequency, only slightly influenced. The present invention is advantageously further developed in that the damping element is designed in such a form variable that the mobility of the generator rotor relative to the generator stator in the circumferential direction, compared with the mobility in the radial or axial direction is limited. According to the invention, a locking device is thus proposed which proposes a secure locking of the generator rotor relative to the generator stator, but dampens the power flow between the generator rotor and generator stator in the circumferential direction but at least limited.

By a movement of generator rotor and generator stator in the circumferential direction, the damping element undergoes a tensile or compressive force. A relative movement of the generator stator and the generator rotor in the axial or radial direction causes shearing forces, which act on the damping element. Since the shear modulus G is smaller in a known manner than the modulus of elasticity E, consequently, the required shear stress, which must be used to move a defined point by the distance DI, is less than the tensile or compressive stress, which for a shift by DI would have to be spent. In a preferred embodiment of the present invention, the locking device has a holding arm, which has a stator-side end and a rotor-side end, wherein at the stator end a receptacle for the damping element is formed, which is adapted to receive the damping element, which with the support structure in Plant can be brought. Thus, a holding arm is proposed, which provides a cost-effective and easy to handle connection between the damping element and the clamping unit.

In a particularly preferred embodiment of the invention, a clamping unit is formed on the rotor-side end of the support arm, which has at least one recess through which connection means, in particular screws, are feasible, and which is adapted to connect the locking device with the generator rotor. It is thus proposed a clamping unit, which provides a simple and fast coupling and decoupling of the locking device of the generator rotor.

In a further particularly preferred embodiment of the invention, the support structure has a plurality of segments, wherein each of the segments has a first side and a second, arranged in the circumferential direction opposite side, and a first locking device with the first side of the support structure is brought into abutment and at least one further arresting device can be brought into abutment with the second side of the support structure, the direction of action of the first arresting device extending substantially opposite to the direction of action of the second arresting device. The invention makes use of the knowledge that by locking by two oppositely directed locking devices of the generator rotor can be locked even when it comes to a greatly varying stress on the rotor of the wind turbine due to rotating winds. Furthermore, the force flow of the rotor acting on the supporting structure is introduced more uniformly into the supporting structure and thus leads to a lower stress on the segments of the supporting structure and the components of the wind power plant connected to it. In a preferred embodiment of the invention, the damping element with a pressurized fluid, in particular compressed air can be filled. The invention makes use of the knowledge that by filling with a pressurized fluid, the degree of damping in the tangential, radial and axial directions can be controlled. Furthermore, the stiffness of the Dämpungselements by the filling is controllable such that the shear or Walk behavior of Dämpungselements and thus the locking of the generator rotor relative to the generator stator in the tangential, radial and axial direction is controllable.

If compressed air is used as the filling medium for the damper elements, there is the further advantage that in the case of leakage there is no contamination in the generator, as might be the case, for example, when using oil as the filling medium.

As effective direction of the locking device is understood here that the effective direction extends, preferably in the circumferential direction of the generator, substantially perpendicular to the contact surface between the respective support structure and the respective damping element.

A further preferred embodiment of the invention provides a braking device which is adapted to reduce the relative speed of the generator rotor or at least to hold the generator rotor after reaching standstill temporarily, wherein the braking device comprises a brake unit and a brake disc, which is operatively connected to the generator rotor ,

The invention makes use of the finding that the braking device facilitates the positioning of the generator rotor relative to the generator stator, whereby the locking, in particular the positive locking, of the generator rotor relative to the generator stator is facilitated.

In a further preferred development of the invention, the locking device can be coupled to the brake disk. The invention makes use of the fact that the brake disc is usually more accessible than the generator rotor itself, and by the locking of the Brake disk in a predetermined position relative to the generator stator of the operatively connected generator rotor is also locked.

In a particularly preferred embodiment of the invention, the brake disc recesses, and the clamping unit is adapted to be coupled by means of a clamping connection, in particular a clamping connection in the region of the recesses, with the brake disc.

According to a further aspect of the present invention, the underlying object is achieved by a wind energy plant with a nacelle, a machine carrier arranged in the nacelle and a rotor rotatably mounted on the nacelle, characterized by a generator operatively connected to the rotor according to at least one of the previously described embodiments. With regard to the advantages achieved and preferred embodiments, reference is made in this respect to the above explanations of the generator. By providing the wind turbines with such a generator according to the invention, it makes use of the corresponding advantages.

Preferably, the wind turbine according to the invention further comprises a device for rigid locking, which is adapted to rigidly lock the generator rotor relative to the generator stator, in particular for performing maintenance and installation work, in a predetermined position in the coupled state, and further after completion of the Work to be solved again. The device is preferably designed as a holding brake or as a positive locking device.

According to a further aspect of the present invention, the object mentioned is achieved by a method for locking a rotor of a generator, in particular a generator according to one of the preferred embodiments described above, comprising the steps of: holding the generator rotor relative to the generator stator in a predetermined position, coupling a locking device between the generator rotor and Generatorsta- gate such that a force flow between the generator rotor and generator stator arises, wherein the locking device comprises a damping element which is designed so that it deforms as a result of the power flow between the generator rotor and generator stator, and decoupling the damping locking device of the generator rotor and / or generator stator. The locking device is preferably a locking device according to one of the preferred embodiments described above. The method makes use of the same advantages and preferred embodiments as the generator according to the invention. With regard to the advantages achieved and preferred embodiments, reference is therefore made to the above embodiments of the generator.

In a particularly preferred embodiment of the method that includes carrying out a modal analysis for determining the dynamic behavior of the generator. The modal analysis is preferably carried out after the coupling of the locking device between the generator rotor and generator stator, and before the decoupling of the locking device of the generator rotor and / or generator stator. It is thus proposed a method for vibration control of wind turbines.

Preferably, damping element with a pressurized fluid, in particular compressed air can be filled. The method is advantageously further developed in that the damping element is first mounted in the step of coupling between the generator and the stator, and then filled in such a way that it comes into contact with the support structure. The filling of the Dämfungselements in the mounted state and / or the locking device facilitates the assembly significantly. According to a final aspect of the present invention, the above-mentioned object is achieved by the use of a damping locking device in the initiation and implementation of a modal analysis for determining the dynamic behavior of a generator, in particular a generator according to at least one of the embodiments described above, wherein the locking device comprises a damping element which is like that is formed variable in shape that it deforms due to the power flow between the generator rotor and generator stator.

With regard to the advantages achieved and preferred embodiments, reference is made in this respect to the above explanations of the generator, in particular damping locking device of the generator. The use of such a locking device in the initiation and implementation of a modal analysis for determining the dynamic behavior of a generator according to the invention, it makes the appropriate benefits to own. The occurring magnetic interactions, which can lead to the formation of audible narrow-band tones and possibly a deterioration of the life, are caused in particular by the relative movement of generator rotor and generator stator in the radial direction. In the investigation of the vibration characteristic, it is therefore of particular importance to detect the vibrations of the rotor and stator in the radial direction without interference.

In particular, the generator may be a synchronous generator, an asynchronous generator, or a double-fed asynchronous generator. An example of a synchronous generator is a multi-pole synchronous ring generator of a wind power plant, wherein other generators including other synchronous generators can be used according to the invention. Such a multi-pole synchronous ring generator of a wind turbine has a plurality of stator teeth, in particular at least 48 stator teeth, often even significantly more stator teeth, in particular 96 stator teeth or even more stator teeth. The magnetically active region of the synchronous generator, namely both the generator rotor and the generator stator, is arranged in an annular region about the axis of rotation of the synchronous generator.

The generator preferably has a magnetically active region, namely both the rotor and the stator, which is arranged in an annular region about the axis of rotation of the synchronous generator. Depending on the structure of the Wind energy plant according to the invention may have a support structure in the inner region, which may be formed but axially offset in some embodiments.

The generator is preferably foreign-excited. In a preferred embodiment, the generator is a slowly rotating generator. This is understood to mean a generator with a speed of 100 revolutions per minute or less, preferably 50 revolutions per minute or less, more preferably in a range of 5 to 35 revolutions per minute. The invention will be described in more detail below with reference to the attached figures with reference to preferred embodiments. Hereby show:

Figure 1: a wind turbine schematically in a perspective

View,

Figure 2: a schematic representation of a rotor of a

Wind energy plant according to FIG. 1,

Figure 3: a section of the view of the rotor and a

Locking device according to Figure 2,

Figure 4: a schematic representation of the locking device according to

FIG. 2,

Figure 5a: a section of the locking device according to Figure 4 without

relative movement

Figure 5b: a section of the locking device according to Figure 4 below

Relative movement in the radial direction Figure 5c: a section of the locking device according to Figure 4 below

Relative movement in the axial direction

Figure 5d: a section of the locking device according to Figure 4 below

Relative movement in the circumferential direction. FIG. 1 shows a wind energy plant 100 with a tower 102 and a nacelle 104. A rotor 106 with three rotor blades 108 and a spinner 110 is arranged on the nacelle 104. The rotor blades 108 are arranged with their rotor blade root on a rotor hub. The rotor 106 is rotated by the wind during operation and thereby drives a generator (not shown) in the nacelle 104.

FIG. 2 shows a generator 120, in particular a generator for the wind power plant 100, with a rotatably mounted generator rotor 121, a generator stator 122 corresponding to the generator rotor 121, which has a support structure 123 for attachment in the wind energy plant 100. The stator support structure 123 further includes a plurality of segments

123 a, b, c and at least one first side 123 'and a second side to 123 "on.

Each segment of the stator support structure 123 a, b, c has at least one first side 123 'a, b, c and a second side 123 "a, b, c. Furthermore, at least three locking devices 130 a, b, c are arranged in the generator 120, which are coupled between the generator rotor 121 and the generator stator 122 in such a way that a force flow is generated between the generator rotor 121 and the generator stator 122.

The locking devices 130 a, b, c lock the generator rotor 121 relative to the generator stator 122 in a predetermined position. In each case, a first locking device 130 'a, b, c with a first side of Statortragstruktur 123'a, b, c in Appendix and a second locking device 130 "a, b, c with a second side of Statortragstruktur 123" a, b , c in Appendix. Figure 3 shows a section of the generator 120 according to Figure 2. According to the preferred embodiment shown, the rotatably mounted rotor 121 is operatively connected to a brake disc 125 which is formed so that it has a plurality of recesses along its circumference. The generator stator 122 is connected to a support structure 123. The

Statortragstruktur 123 is configured to connect the generator stator 122 to the wind turbine 100. The stator support structure 123 further has a plurality of segments 123 a, b, c and at least one first side 123 'and a second side to 123 ". The locking device 130 ', 130 "is connected to the brake disc 125 a

Braking device of the generator rotor 121 coupled. Furthermore, the locking device 130 'with a first side of the support structure 123' and the locking device 130 "with a second side of the support structure 123" of the generator stator 122 in Appendix. The locking device 130 ', 130 "further comprises a holding arm 133, which has a stator-side end with a receptacle 134 for the damping element 131 and a rotor-side end.

At the stator end of the locking device 130, the damping element 131 is arranged on the receptacle 134. At the rotor-side end, a clamping unit 132 is formed which has one or more recesses 135 through which connection means, for example screw connections, can be made to form a clamping connection.

FIG. 4 shows the locking device 130. The locking device 130 comprises a holding arm 133, which has a stator-side end, on which a receptacle 134 for a damping element and a damping element 131 are arranged. Further, the holding arm 133 has a rotor-side end on which a clamping unit 132 is formed. The clamping unit 132 has at least one recess 135 through which connecting means, in particular screws, to form a clamping connection can be carried out.

The contact surface between support structure 123 and damping element 131 extends substantially perpendicular to an axis 150. The effective direction of the damping element 131, starting from the circumference of the rotor 121, extends substantially parallel to the axis 150.

Figure 5a shows a section of the locking device 130 in the idle state. The locking device 130 comprises an axis of symmetry 140, a holding arm 133 which has a stator-side end, on which a receptacle 134 for a damping element and a damping element 131 are arranged. The damping element 131 is in contact with the support structure 123 of the stator 122. The contact surface between support structure 123 and damping element 131 extends substantially perpendicular to the axis 150.

Furthermore, FIG. 5 a shows an axis 150, which runs essentially perpendicular to the radial of the generator 120 and which essentially coincides with the axis of symmetry 140 of the locking device 130.

The locking device 130 experiences a force Fn in the circumferential direction through the rotor 121, which is transmitted to the damping element 131. The damping element in this case has a height L. FIG. 5b shows a section of the locking device 130 according to FIG. 5a, which experiences a relative movement in the radial direction under the action of a force FR. The locking device 130 further experiences a force Fn in the circumferential direction through the rotor 121, which is transmitted to the damping element 131. The damping element in this case has a height L. The variable-shape damping element 131 experiences essentially a shear around AL as a result of the force FR. Furthermore, FIG. 5 b shows an axis 150 which, under the relative movement in the radial direction, is at a distance AL from the axis of symmetry 140 of FIG

Locking device 130 has.

FIG. 5c shows a detail of the locking device 130 according to FIG. 5a, which under the action of a force FA is a relative movement in the axial direction

Direction learns. The locking device 130 further experiences a force Fn in the circumferential direction through the rotor 121, which is transmitted to the damping element 131. The damping element in this case has a height L. The variable-shape damping element 131 experiences essentially a shear around AL as a result of the force FR.

Furthermore, FIG. 5c shows an axis 150 which, under the relative movement in the axial direction, is at a distance AL from the axis of symmetry 140 of FIG

Locking device 130 has.

5d shows a detail of the locking device 130 according to Figure 5a, which under the action of a force F ₂ (FT2 "Fn) by the rotor 121, a

Relative movement in the circumferential direction undergoes. The force F _T 2 is on the

Transfer damping element 131 so that the height of the variable-shape damping element is compressed by AL.

Furthermore, FIG. 5 d shows an axis 150 which substantially coincides with the axis of symmetry 140 of the locking device 130.

Under the simplified assumption that only forces in the circumferential direction act on the damping element 131, the tension or compressive stress o to be applied for an expansion or compression e is derived as follows: s = E e = E AL, with E as elastic modulus. Under the simplified assumption that only forces in the radial or axial direction act on the damping element 131, the shear stress t to be applied for shear by the angle g is derived as follows: with G as shear modulus.

Thus, since L »AL and G <E, the force to be expended for a relative movement AL in the radial or axial direction is consequently many times less than a force in the axial or radial direction.

Claims

claims

1. generator, in particular generator (120) of a wind turbine (100), with

- A rotatably mounted generator rotor (121);

a generator stator (122) corresponding to the generator rotor (121) and having a support structure (123) for attachment to the wind turbine (100); and

at least one locking device, which in such a manner between generator rotor (121) and generator stator (122) can be coupled, that a force flow between generator rotor (121) and generator stator (122) is formed, and which is adapted to the generator rotor (121) in the coupled state relative to To lock generator stator (122) in a predetermined position, characterized in that the locking device (130) has a damping element (131) which is designed so that it is deformable due to the force flow between generator rotor (121) and generator stator (122 ) deformed.

2. generator (120) according to claim 1,

characterized in that the damping element (131) is designed such variable in shape that the generator rotor (121) in the radial

Direction relative to the generator stator (122) is movable.

3. generator (120) according to at least one of the preceding claims, characterized in that the damping element (131) is designed such variable shape that the generator rotor (121) in the axial direction relative to the generator stator (122) is movable.

4. generator (120) according to at least one of the preceding claims, characterized in that the damping element (131) is formed such form variable that the generator rotor (121) in the circumferential direction relative to the generator stator (122), compared with the mobility in radial or axial direction, is only partially movable.

5. Generator (120) according to at least one of the preceding claims, characterized in that the locking device (130) has a holding arm

(133) having a stator-side end and a rotor-side end,

wherein at the stator end a receptacle (135) for the damping element (131) is formed, on which the damping element (131) is arranged, which is in abutment with the support structure (123).

6. generator (120) according to at least one of the preceding claims, characterized in that at the rotor-side end of the support arm

(133) a clamping unit (132) is formed which has at least one recess (135) through which connecting means, in particular screws, are feasible, and which is adapted to connect the locking device (130) with the generator rotor (121).

7. generator (120) according to at least one of the preceding claims, characterized in that the support structure (123) a plurality of

Segments (123 a, b, c), wherein each of the segments (123 a, b, c) has a first side (123'9 and at least one second side (123 "), and a first locking device (130 ') with the first side of the support structure (123 ') can be brought into abutment and at least one further locking device (130 ") can be brought into abutment with the at least one second side of the support structure (123"), the direction of action of the first locking device (130') in Substantially opposite to the effective direction of the second locking device (130 ") extends.

8. generator (120) according to at least one of the preceding claims, characterized in that the damping element (131) with a pressurized fluid, in particular compressed air, can be filled. 9. generator (120) according to at least one of the preceding claims, characterized by a braking device which is adapted to reduce the relative speed of the generator rotor (121), wherein the Braking device, a mechanical brake unit and a brake disc (125) which is operatively connected to the generator rotor (121) has.

10. generator (120) according to claim 9,

characterized in that the locking device (130 ', 130 ") with the brake disc (125) can be coupled.

1 1. generator (120) according to claim 9 or 10,

characterized in that the brake disc (125) has recesses, and the clamping unit (132) is adapted to be coupled by means of a clamping connection, in particular a clamping connection in the region of the recesses, with the brake disc (125).

12. Wind energy plant,

with a nacelle (104), a machine carrier arranged in the nacelle (104) and a rotor (108) rotatably mounted on the nacelle (104),

characterized by a generator (120) operatively connected to the rotor (121) according to any one of claims 1-1 1.

13. A method for locking a rotor (121) of a generator (120), in particular of a generator (120) according to any one of claims 1-11, comprising the steps:

Holding the generator rotor (121) relative to the generator stator (122) in a predetermined position,

Coupling a damping locking device (130 'a, b, c, 130 "a, b, c) between the generator rotor (121) and generator stator (122) such that a force flow between the generator rotor (121) and generator stator (122) is formed, and decoupling the damping locking device (130) of generator rotor (121) and / or generator stator (122).

14. The method according to claim 13,

the method further precedes the steps:

Braking the generator rotor (121) by a braking device, and Detecting the generator rotor (121) relative to the generator stator (122) in a predetermined position by a locking device.

15. The method according to claim 13 or 14,

the method further comprising performing a modal analysis to determine the dynamic behavior of the generator (120), which is preferably done after the locking device has been coupled in, and before the locking device is decoupled.

16. Use of a locking device (130 'a, b, c, 130 "a, b, c) for locking a rotor of a generator, in particular a Windenergiean- location for performing a modal analysis to determine the dynamic behavior of the generator, wherein the locking device (130 'a, b, c, 130 "a, b, c) has a damping element (131) which is designed so that it deforms due to the power flow between the generator rotor (121) and generator stator (122).