DE102012102686A1 - Divided shaft for use in e.g. offshore wind energy plant for generating electric power, has rotor-side and generator-side parts connected with each other by connecting elements, so that rotational torque is transferred between parts - Google Patents

Abstract

The shaft (15) has rotor-side and generator-side parts (15a, 15b) including first and second connecting elements. The parts are connected with each other by the connecting elements such that rotational torque (M) is transferred between the parts of the shaft. The connecting elements are formed as a flange, and a connection is formed between the connecting elements using a third connection element e.g. screw. The parts are connected with a rotor (12) and a gear box or generator (16) of a wind energy plant i.e. offshore wind energy plant (1).

Description

The invention relates to a split shaft for a wind turbine.

For the production of electrical energy increasingly wind turbines are used. These usually have a tower with a gondola rotatable horizontally thereon, on which a rotor is arranged. The rotor is connected via a shaft, also called rotor shaft, to a generator for generating electrical energy, so that the torque M of the rotor, which is caused by the force of the wind on the rotor blades, can be transmitted to the generator. It can be interposed between the slow but highly stressed rotor shaft and the generator, a transmission which increases the speed of the rotor shaft to the generator. The bearing of the rotor shaft can be done in part via a rotor bearing and bearing blocks that receive the transmission. Such a bearing block is provided with frictional connection means, e.g. a screw connection to a machine carrier fastened.

With regard to the mechanical stress, special demands are placed on all components of a wind energy plant, since these have to withstand high and differently directed forces in particular. Due to the irregularities of the wind in terms of its strength and direction, which can change within a short time, permanently occur forces of different strengths in the tensile, compressive and transverse directions, which are greater, the stronger the wind and the larger the wind turbine , In storms or hurricanes wind turbines must withstand even extreme loads. The wind also generates vibrations on the rotor, which are forwarded via the rotor shaft to all other components, in particular the directly connected components such as bearing blocks, gearbox and generator.

The components must withstand the stresses undamaged over a long period of operation, especially in off-shore systems, as their maintenance is much more complex and therefore more expensive than onshore wind turbines. However, these components, particularly the rotor shaft itself as well as the directly over the rotor shaft exposed to the forces and vibrations bearing blocks, gearbox and generator, in spite of modern materials and construction techniques are exposed to considerable wear, so they i.A. must be replaced at least once during their lifetime. In particular, vibrations lead to heavy wear of the tooth flanks of the transmission.

For the replacement of components usually heavy equipment is necessary, which must be transported to the tower of the wind turbine. Often, the entire gondola must be removed from the tower and put back on. This causes an enormous effort, especially in off-shore wind turbines. In some cases, the components can only be replaced on land. This leads to long service lives of the wind turbines and enormous costs for the replacement of the components.

The object of the present invention is to reduce the expense of repair, in particular the replacement of the bearing of the rotor shaft and or or the rotor shaft itself a wind turbine.

The object is achieved by a split shaft of a wind turbine according to claim 1, whose parts can be connected together. Advantageous developments are described in the subclaims.

Thus, the present invention according to claim 1 relates to a split shaft of a wind turbine with a first part of the shaft with a first connection element and a second part of the shaft with a second connection element, wherein the two parts of the shaft are connected to each other via their first and second connection element can be that a torque M between the first and second part of the shaft can be transmitted.

The present invention is based on the finding that a split shaft can be dismantled and exchanged more easily than the hitherto integrally designed shafts for wind turbines, since the individual parts are shorter and lighter than a continuously formed shaft. Thus, the shaft can be disassembled in the nacelle of the wind turbine or only a part to be replaced from the shaft of the other components and shaft pieces are separated and replaced. Likewise, the bearings of a split shaft can be replaced easier and faster, as the shaft can be easily disassembled or at least can be raised. As a result, the bearings can be relieved and the necessary working space can be created to replace the bearings or their sub-elements within the nacelle. This can e.g. within the nacelle by means of suitable handling devices, which are also significantly lighter and smaller in a split shaft. As a result, the cost of a complete or partial shaft replacement or replacement of the shaft bearing is reduced and saved costs.

In particular, can be dispensed with the complete disassembly of the gondola, as it has been often required to replace the shaft on the ground in the nacelle. Such an exchange leads to significant downtime of the wind turbine and requires, inter alia, in terms of the cranes to be used, including personnel a very high cost. These disadvantages are significantly increased if the wind turbine is an off-shore system and the dismantled nacelle must first be brought ashore.

Also, in a split shaft, it is possible to have at least one such piece in place, i. within the wind turbine or at least once central vorzuhalten for a wind farm with multiple wind turbines, as a spare part, since a portion of a wave causes lower costs and takes up less storage space than a complete wave.

According to one aspect of the invention, the first and / or second connection element is connected non-positively to the respective part of the shaft.

It is advantageous hereby that a firm and rigid fit of the connection element or of the two connection elements on or on the shaft can be achieved, so that the connection element or the connection elements does not rotate with respect to the parts of the shaft during the rotation of the shaft will or will, but a safe transmission of the torque M from the rotor to the transmission or the generator can be done. For this, e.g. a connecting element by means of shrinkage are applied to the corresponding part of the shaft.

According to a further aspect of the invention, the first and / or second connection element is or are designed as a flange. The connection between the first and / or second connection element can be produced in a form-fitting manner by means of at least one connection element.

It is advantageous here that the connection between the connection elements by means of a flange together with connecting elements can be made easily and quickly. This is important for assembly and disassembly in the limited space of a nacelle of a wind turbine. Also, for this purpose, only simple and known aids, such as small cranes and conventional tools, are needed, which are simply placed or suspended in the nacelle and simply, e.g. can be transported in the interior of the tower of the wind turbine by means of a simple diaper velvet basket. As connecting elements, e.g. Bolts and nuts, bolts and the like can be used.

It is also possible to perform the flange split. This is advantageous because then an e.g. can be removed from the shaft piece by dividing it by two half-shells, and e.g. a closed running around the shaft bearing can be removed from the shaft in the longitudinal direction L. If the flange is formed in one piece, the flange would have to be removed from the shaft in the longitudinal direction L in order to allow the bearing to be removed, which is also possible, but may also be possible. causes a greater effort or takes more work space to complete. Otherwise, the bearing would have to be split to remove it from the shaft without having to remove the flange.

According to one aspect of the invention, the shaft is divided into two parts.

The division of a wave is advantageous because in this way a division of the shaft can be provided without further weakening the stability of the shaft and thus its torque transmission through further connection points.

When disassembling a section of the shaft u.U. It should be noted that the rotor must be secured against tilting, as the support in the nacelle caused by this can be interrupted if the shaft between the rotor bearing and the gear or generator breaks. On these grounds it is advantageous to provide an at least three-part shaft so that one or the middle piece can be dismounted and e.g. can be raised and in each case a shaft piece on the rotor and the gearbox or generator is present, via each of which a support can be made.

According to a further aspect of the invention, the first part of the shaft can be connected to the rotor and the second part of the shaft to the gear or generator of a wind turbine.

It is advantageous that the split shaft used in a wind turbine and in a simple and conventional manner with the components of the wind turbine, between which it is to transmit a torque M, can be installed.

The present invention also relates to a wind energy plant with a shaft according to one of claims 1 to 5.

According to one aspect of the invention, the wind turbine is an off-shore wind turbine.

An embodiment and further advantages of the invention are explained below in connection with the following figures. It shows:

1 a schematic sectional view of the upper portion of a wind turbine with a split shaft;

2 a schematic detailed sectional view of the split shaft after 1 ; and

3 a schematic perspective view of a connection element.

1 shows a schematic sectional view of the upper portion of a wind turbine 1 with a split shaft 15 . 15a . 15b , The wind turbine 1 has a gondola 10 on the top of a tower 11 is mounted rotatably about its longitudinal axis. The tower 11 in turn, by means of a foundation or a base plate (not shown) on the ground, in an off-shore wind turbine 1 the seabed, firmly anchored.

At the gondola 10 is a rotor in the wind direction W 12 around the longitudinal axis L of the nacelle 10 provided rotatably mounted. The rotor 12 essentially has a rotor blade receptacle 14 on, at the rotor blades 13 , i.Allg. three rotor blades 13 , evenly offset and are each mounted rotatably about their longitudinal axes.

The rotor 12 is by means of a rotor shaft 15 with the generator 16 the wind turbine 1 connected and. Optionally, between the rotor shaft 15 and the generator 16 a transmission may be provided (not shown). The rotor shaft 15 is in both cases via a shaft bearing 17 in the gondola 10 rotatably mounted about the longitudinal axis L. In this way, the rotor shaft can 15 turn around the longitudinal axis L and so the rotation and the torque M, by the at the rotor blades 13 attacking wind W can be caused on the generator 16 transferred, whereby electrical energy can be obtained from the wind W.

According to the invention, the rotor shaft 15 at least made in two parts, so that the rotor shaft 15 a first part 15a , which is preferably the rotor-side part 15a is that with the rotor 12 rigidly connected, and a second part 15b , preferably the generator-side part 15b is directly or through a gear (not shown) with the generator 16 is connected has. The two parts 15a . 15b the rotor shaft 15 are via a connection point 2 connected to each other such that the rotation and the torque M of the rotor-side part 15a over the junction 2 on the generator side part 15b can be transferred.

A schematic detailed sectional view of the split shaft 15 . 15a . 15b is in 2 shown. 3 shows a schematic perspective sectional view of a connection element 21 . 22 , Preferably, the first and second connection element 21 . 22 identical or at least symmetrical to their common contact surface 21b constructed so that in the following the reference numerals of the first connection element 21 used, but this mutatis mutandis, for the second connection element 22 Have validity.

The first part 15a the rotor shaft 15 has a first connection element 21 on, which preferably as (connecting) flange 21a is trained. In its longitudinal axis L, which in the assembled state of the longitudinal axis L of the rotor shaft 15 and their parts 15a . 15b corresponds, the flange points 21a through openings 21d , eg six through openings 21d on. The flange 21a has a contact surface 21b on, with he with the corresponding contact surface of the second connection element 22 can be composed. Now become two such flanges 21a the first and second connection element 21 . 22 with their contact surfaces 21b put on each other, they can through fasteners 23 such as screws and nuts or bolts from each of the contact surfaces 21b facing away backs 21c be connected to each other.

The first connection element 21 also has a wave recording 21e on, preferably in one piece with the flange 21a is formed and in the longitudinal direction L at least on its the flange 21a side facing away from an opening for receiving the respective part 15a . 15b the rotor shaft 15 having. In this opening, the respective part 15a . 15b the rotor shaft 15 eg by shrinking against rotation with the corresponding connection element 21 . 22 get connected.

In this way, a divisible shaft 15 between the rotor 12 and the gearbox or generator 16 a wind turbine 1 be provided with simultaneous transmission of the torque M.

LIST OF REFERENCE NUMBERS

L

Longitudinal axis of the gondola 10 as well as the rotor 12 and the (rotor) shaft 15

M

Torque of the rotor shaft 15

W

wind direction

1

Wind turbine

10

gondola

11

tower

12

rotor

13

rotor blades

14

Rotor blade receiving

15

(Rotor) shaft

15a

rotor-side part of the (rotor) shaft 15

15b

generator-side part of the (rotor) shaft 15

16

Generator or gearbox

17

shaft bearing

2

junction

21

first connection element

21a

(Connecting) flange

21b

Contact surface of the (connection) flange 21a

21c

Rear of the (connection) flange 21a

21d

Openings of the (connection) flange 21a

21e

shaft mount

22

second connection element

23

Connecting element, e.g. Screws, bolts etc.

Claims (7)

Split wave ( 15 . 15a . 15b ) of a wind turbine ( 1 ), with a first part ( 15a ) the wave ( 15 ) with a first connection element ( 21 ), and a second part ( 15b ) the wave ( 15 ) with a second connecting element ( 22 ), the two parts ( 15a . 15b ) the wave ( 15 ) via its first and second connection element ( 21 . 22 ) in such a way that a torque M between the first and second part ( 15a . 15b ) the wave ( 15 ) can be transmitted. Split wave ( 15 . 15a . 15b ) according to claim 1, wherein the first and / or second connection element ( 21 . 22 ) frictionally with the respective part ( 15a . 15b ) the wave ( 15 ) connected is. Split wave ( 15 . 15a . 15b ) according to claim 1 or 2, wherein the first and / or second connection element ( 21 . 22 ) is formed as a flange, and wherein the connection between the first and / or second connection element ( 21 . 22 ) by means of at least one connecting element ( 23 ) can be produced in a form-fitting manner. Split wave ( 15 . 15a . 15b ) according to one of the preceding claims, wherein the shaft ( 15 ) is divided into two parts. Split wave ( 15 . 15a . 15b ) according to claim 4, wherein the first part ( 15a ) the wave ( 15 ) with the rotor ( 12 ) and the second part ( 15b ) the wave ( 15 ) with the gearbox or generator ( 16 ) of a wind turbine ( 1 ) can be connected. Wind energy plant ( 1 ) with a split shaft ( 15 . 15a . 15b ) according to one of the preceding claims. Wind energy plant ( 1 ) according to claim 6, wherein the wind turbine ( 1 ) an off-shore wind turbine ( 1 ).

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