WO2019234179A1

WO2019234179A1 - Wind power plant

Info

Publication number: WO2019234179A1
Application number: PCT/EP2019/064847
Authority: WO
Inventors: Carsten Eusterbarkey; Alf Trede
Original assignee: Senvion Gmbh
Priority date: 2018-06-06
Filing date: 2019-06-06
Publication date: 2019-12-12
Also published as: DE102018004464A1; EP3803113A1

Abstract

The invention relates to a wind power plant comprising a rotor which can be rotated about a rotor axis and has a plurality of rotor blades, and a drive train (1) which is connected rotatably to said rotor and has a rotor shaft (2), wherein the drive train (1) is mounted on a machine carrier (7). The rotor shaft (2) has a locking ring (21) which is aligned coaxially with it and has at least three locking depressions (22) on its outer circumference. The machine carrier (7) has at least three locking bolts (10), which are displaceable and are oriented radially with respect to the rotor shaft (2), for the selective simultaneous engagement into in each case one locking depression (22) of the locking ring (21).

Description

Wind turbine

The invention relates to a wind turbine.

In known wind energy plants, a rotor rotatable about a substantially horizontal axis and having rotor blades arranged thereon can be set in rotation by wind. The rotor is firmly connected to a rotor shaft - possibly via a gear - with a generator for converting the rotational energy of the rotor into electrical energy. The power-transmitting rotating components from the rotor to the generator are collectively referred to as a drive train and are arranged in a gondola rotatably mounted on a tower. The drive train is mounted at several points, wherein usually at least one bearing is arranged in the region of the rotor shaft. In a so-called. Three-point bearing further storage of the driveline takes place directly over the transmission, d. H. The rotor shaft itself does not have any further bearing, but is mounted indirectly via the integrated mounting only there due to the fixed connection to a transmission or even with a slow-running large generator.

For certain maintenance, it may be necessary to lock the rotor shaft and thus the driveline in a certain position. For this purpose, the documents EP 1 251 268 A2 and EP 2 620 636 A1 propose rings which are fastened to the rotor shaft and have a multiplicity of outboard bores into which a bolt can optionally engage for locking.

In particular, in such wind turbines, in which the rotor shaft is mounted at the end remote from the rotor only indirectly via the gearbox, the rotor shaft must during assembly of the wind energy plant and in gearbox replacement or other maintenance work, in which the transmission is separated from the rotor shaft be secured by a designated holder. From the documents EP 1 617 075 A1 and EP 1 748 182 B1 corresponding brackets are known, in each of which a separate support frame must be transported into the nacelle of the wind turbine and mounted there before the transmission can be separated from the rotor shaft. The use of corresponding holding frames is very expensive. The invention has for its object to provide a comparison with the prior art improved wind turbine.

This object is achieved by a wind turbine according to the main claim. Advantageous further developments are the subject of the dependent claims. Accordingly, the invention relates to a wind energy plant comprising a rotor rotatable about a rotor axis and having a plurality of rotor blades and a rotor connected thereto

Drive train with a rotor shaft, wherein the drive train is mounted on a machine carrier, the rotor shaft has a coaxially aligned Arretierungsring with at least three Arretierungsvertiefungen on its outer circumference and the machine carrier at least three radially aligned to the rotor shaft and slidable locking pin for selectively simultaneous engagement in a respective detent recess has the Arretierungs- ring.

The invention is based on the finding that a simultaneous engagement of at least three locking bolts in the locking ring of a rotor shaft of a wind energy plant not only ensures locking of the rotor against unwanted rotational movement, but also sufficient support of the rotor shaft. Because of this support, a drive train element attached to the rotor shaft, such as a gearbox or the generator, can also be released from the rotor shaft, even if the rotor shaft is supported indirectly via the drive train element in question. Since, according to the invention, the locking ring is fixedly connected to the rotor shaft and the locking pins are part of the machine carrier, additional components are not required for locking the rotor or for supporting the rotor shaft in the wind energy installation according to the invention.

If the number of locking openings corresponds to the number of locking bolts, their respective arrangement is to be coordinated with one another such that, at least in one rotational position of the rotor shaft, each locking bolt can engage in one locking opening in each case. If locking openings and locking pins are distributed uniformly over the circumference, a locking in a number of rotational positions of the rotor shaft corresponding to the number of locking openings or locking bolts is possible. In order to lock and support the rotor in as many different positions as possible, it is preferred if the number of locking recesses is greater than the number of locking bolts. If the locking recesses are suitably arranged, the rotor shaft and thus the rotor can be locked in a number of rotational positions exceeding the number of locking pins.

It is preferred if the locking recesses are distributed uniformly over the circumference of the locking ring, so the angular distance between each two adjacent locking recesses is thus constant. In this case, the rotor shaft or the rotor can be locked in a number of rotational positions corresponding to the number of locking recesses.

If it is further provided that the angular distance between two adjacent locking bolts corresponds to the angular spacing of two adjacent locking recesses or a multiple thereof, it is ensured that when a locking bolt engages in a locking recess, any other locking bolt can likewise engage in a locking depression.

In particular, in order better to be able to derive the forces occurring in the described support via the locking device, it is preferred if more than three locking bolts are provided. The load on the individual locking bolts is generally lower, the more locking bolts are provided. In addition, with more locking bolts, the individual locking bolts can often be made smaller, which can simplify the integration of the locking bolts into the machine carrier. It is further preferred if at least part of the locking bolts are combined in locking bolt groups, within which the angular distance between two adjacent locking bolts corresponds to the angular distance between two adjacent locking recesses. Particularly advantageous have three Arretierungsbolzengruppen proven each with identical number of locking pin. The locking bolts and / or locking bolt groups may be arranged symmetrically with respect to a vertical plane through the axis of the rotor shaft. The locking bolts and / or locking bolt groups can also be distributed uniformly over the circumference around the rotor shaft.

Even if the locking ring can be a separate component fixedly connected to the rotor shaft, it is preferred if the locking ring is integrated directly into the rotor shaft, that is to say is formed integrally with the rotor shaft. In particular, the arresting ring be integrated in a provided at the end remote from the rotor mounting flange of the rotor shaft. The mounting flange usually has a radial bore pattern of axial through-holes for attachment of another drive train element, such as, for example, a transmission, or for direct attachment of the generator. It is preferred if the locking recesses are each arranged centrally between two adjacent axial through-holes of the mounting flange.

The locking bolts can be hydraulically displaceable. For this purpose, the locking bolts may, for example, be connected to a piston arranged in a cylinder or be made in one piece therewith. To ensure the engagement of the locking bolts in locking recesses, it can be provided that the locking bolts have a bore with an internal thread for engagement of a securing bolt and the locking recesses radial through-holes to the interior of the rotor shaft for the passage of securing bolts at its radial end face. Starting from the inside of the rotor shaft, suitable securing bolts can be inserted through the radial through holes and screwed into the locking pins. This can be safely avoided accidental retraction of the locking pin, which would lead to a repeal of the rotor lock or the support of the rotor shaft.

It is preferred if the locking pins are each surrounded by a compensating bushing and / or in each of the locking recesses a compensating bushing is provided to compensate for manufacturing tolerances and to ensure a uniform introduction of force into all the locking bolts. The compensating bushes are designed so deformable that on the one hand manufacturing tolerances can be compensated, on the other hand sufficient resistance can be made during loading during locking and / or support, in order to transmit the forces occurring.

The compensating bushings can be made of plastic. It is also possible for the compensation bushing to be designed as a coating applied directly to the locking bolt and / or in the locking recesses.

On the rotor shaft, a transmission or a gearless direct driven large generator can be connected. The invention will now be described by way of example with reference to an advantageous embodiment. Show it:

FIG. 1 shows a schematic overview of a drive train according to the invention;

and FIGS. 2a, b: schematic detail views of a drive train according to the invention.

1 shows a drive train 1 of a wind turbine (not shown), starting from which, with reference to FIGS. 2a, b, the present invention will be explained.

Of the drive train 1 of the wind turbine, only the rotor shaft 2 as well as partially the gear 3 connected thereto are shown in FIG. In the transmission 3 is a planetary gear, the planet carrier 4 is fixedly connected to the rotor shaft 2. Not shown is the actual rotor comprising the rotor blades at the opposite end of the gear 3 of the rotor shaft 2 and the not shown end of the transmission 3 arranged generator.

The drive train 1 is rotatably mounted on the machine carrier 7 in a region remote from the transmission 3 by means of a rolling bearing 6 arranged in a bearing housing 5 and interacting directly with the rotor shaft 2. In addition, the transmission 3 is fastened to the machine carrier 7 via a gearbox 8. Due to the connection with the planet carrier 4, the rotor shaft 2 is mounted indirectly via its bearing 9 opposite the machine carrier 7 at this end. In the case of the drive train 1 shown in FIG. 1, a so-called three-point mounting is realized in which the transmission 3 can not be easily detached from the rotor shaft 2 due to the indirect mounting of the rotor shaft 2. Rather, to release the transmission 3, a prior support of the rotor shaft 2 is required. In place of the transmission 3, a slow-running, directly driven large generator is possible. In FIGS. 2a, b, a detailed illustration of the transmission-side end of the rotor shaft 2 with gearbox frame 8 and machine carrier 7 is shown by a wind energy installation according to the invention with a drive train 1 that is comparable in principle to FIG. The gear 3 is in Figure 2a, b of the designated holding elements 3 'disassembled, what - as below executed - in the wind turbine according to the invention also readily possible.

The rotor shaft 2 has at its gear-side end an inwardly directed fastening flange 20, which at the same time also forms a locking ring 21, on which a multiplicity-uniformly distributed over the circumference-here 36, of radially extending, conically shaped Arretierungsvertiefungen 22 is provided. From the bottom of the locking recesses 22, a radial through-hole 23 extending up to the inner wall of the fastening flange 20 is provided in each case. Between each two locking depressions 22 or radial through bores 23, an axial through-bore 24 is provided, via which the rotor shaft 2 is connected in known manner to the planet carrier 4 of a transmission 3 or else to the input shaft of a large transmission. Generator can be connected (see Figure 1).

On the machine carrier - more precisely on the transmission gear 8 fixedly connected thereto - locking pins 10 which are oriented in the radial direction and are hydraulically displaceable are provided whose outer shape is adapted to the conical shape of the locking recesses 22. In each case four locking pins 10 are combined to form a locking pin group 11, with adjacent locking pins 10 of a locking pin group 1 1 each having the same angular spacing as two adjacent locking recesses 22. The locking bolt groups 11 are distributed uniformly over the circumference such that all locking bolts 10 can be brought into engagement with a respective locking recess 22 at the same time.

Due to the uniform distribution of the Arretierungsbolzengruppe 1 1 over the circumference, which is symmetrical at the same time in a relative to a vertical plane through the axis of the rotor shaft 2, the rotor shaft 2 and the associated rotor not only locked, but also supported at the same time be that in the state shown in Figure 2a, b, the transmission 3 and a large generator can be easily removed. If a gear 3 or large generator to the holding elements 3 'is mounted (see Figure 1) and a locking of the rotor shaft 2 and the rotor for other reasons no longer required, the locking bolts 10 can be hydraulically withdrawn, bringing the Drive train 1 is freely rotatable again.

In order to prevent the lock or support is released accidentally by the locking pin 10, the locking pin 10 at its front side with a respective Innerthreaded blind hole 12. In this blind hole 12, a locking screw (not shown) guided through a through-bore 23 on the locking ring 21 can engage, with which a locking bolt 10 can finally be secured in the position shown in FIG. 2a, b. To compensate for possible manufacturing tolerances, the locking bolts 10 may each have a compensation bushing made of plastic on the areas provided for engagement with the locking recesses 22 and / or the locking recesses 22. The compensating bushing can also be designed as a coating applied directly to the locking bolt 10 or into the locking recesses 22.

Claims

claims

1. Wind energy plant comprising a rotor rotatable about a rotor axis with a plurality of rotor blades and a torsionally connected drive train (1) with a rotor shaft (2), wherein the T riebstrang (1) is mounted on a machine carrier (7), characterized that

the rotor shaft (2) has a locking ring (21) oriented coaxially therewith with at least three locking recesses (22) on its outer circumference and the machine support (7) has at least three locking bolts (10) aligned and displaceable radially to the rotor shaft (2). for optionally simultaneous engagement in each ne detent recess (22) of the locking ring (21).

2. Wind energy plant according to claim 1,

characterized in that

the number of locking recesses (22) is greater than the number of locking pins (10).

3. Wind energy plant according to claim 1,

characterized in that

the locking recesses (22) are evenly distributed over the circumference of the locking ring (21).

4. Wind energy plant according to claim 3,

characterized in that

the angular distance between two adjacent locking bolts (10) corresponds to the angular spacing of two adjacent locking recesses (22) or a multiple thereof.

5. Wind energy plant according to one of the preceding claims,

characterized in that

more than three locking bolts (10) are provided, wherein at least a part of the locking bolts (10) are preferably combined in locking bolt groups (11), within which the angular distance between two adjacent locking bolts (10) corresponds to the angular distance between two adjacent locking bolts (10). ments (22).

6. Wind energy plant according to one of the preceding claims,

characterized in that

the locking bolts (10) and / or locking bolt groups (11) are distributed symmetrically with respect to a vertical plane through the axis of the rotor shaft (2) and / or evenly over the circumference.

7. Wind energy plant according to one of the preceding claims,

characterized in that

the locking ring (21) is integrated in the rotor shaft (2), preferably in an attachment flange (20) of the rotor shaft (2) provided at the end remote from the rotor (2).

8. Wind energy plant according to one of the preceding claims,

characterized in that

the locking pins (10) are hydraulically displaceable.

9. Wind energy plant according to one of the preceding claims,

characterized in that

the locking bolts (10) have at their radial end face a bore (12) with internal thread for engagement of a securing bolt and the locking recesses (22) have radial through holes (23) to the interior of the rotor shaft (2) for the passage of securing bolts.

10. Wind energy plant according to one of the preceding claims,

characterized in that

the locking bolts (10) are each surrounded by a compensating bushing and / or in each of the locking recesses (22) a compensating bushing is provided to compensate for manufacturing tolerances and to ensure a uniform force in all locking pins (10).

1 1. Wind turbine according to one of the preceding claims,

characterized in that

the compensating bushes are made of plastic.

12. Wind energy plant according to one of the preceding claims,

characterized in that on the rotor shaft (2) a transmission (3) or a gearless directly driven large generator is connected.