YAW BEARING ARRANGEMENT

Abstract

Yaw bearing arrangement for a wind turbine, comprising a yaw bearing with a yaw ring and radial adjustment acting on the inner radial lateral surface of the yaw ring, the radial adjustment comprising at least a housing, at least one sliding pad and one or more threaded adjustment bolts arranged in threaded housing bores and connected with the sliding pad for a radial adjustment of the sliding pad towards the lateral surface and axial bores for accommodating fixation bolts, wherein the housing is a ring or a ring segment with a plurality of radial, at least partially threaded bores, each radial bore accommodating a radial sliding unit comprising radial sliding pad and a threaded radial adjustment bolt for radial moving the sliding pad.

Claims

1. A yaw bearing arrangement for a wind turbine, comprising a yaw bearing with a yaw ring and radial adjustment acting on the inner radial lateral surface of the yaw ring, the radial adjustment comprising at least a housing, at least one sliding pad and one or more threaded adjustment bolts arranged in threaded housing bores and connected with the sliding pad for a radial adjustment of the sliding pad towards the lateral surface and axial bores for accommodating fixation bolts, wherein the housing is a ring or a ring segment with a plurality of radial, at least partially threaded bores, each radial bore accommodating a radial sliding unit comprising radial sliding pad and a threaded radial adjustment bolt for radial moving the sliding pad.

2. The yaw bearing arrangement according to claim 1, wherein the ring or the ring segment comprises a plurality of axial threaded bores, each bore accommodating an axial sliding unit comprising an axial sliding pad and a at least partially threaded axial adjustment bolt for axial moving the axial sliding pad.

3. The yaw bearing arrangement according to claim 1, wherein each radial bore or each axial bore or each radial bore and each axial bore has a first threaded bore section having a first diameter and a second unthreaded bore section, having a smaller second diameter, accommodating the sliding pad.

4. The yaw bearing arrangement according to claim 3, wherein the radial bolt or the axial bolt or each bolt comprises a first threaded bolt section and a second unthreaded bolt section engaging into the second bore section.

5. The yaw bearing arrangement according to claim 1, wherein a biasing member is provided for biasing the sliding pad towards the lateral surface.

6. The yaw bearing arrangement according claim 5, wherein the biasing member is a spring resting on the bolt and the sliding pad, or that the biasing member is an elastic intermediate pad or ring arranged between the bolt and the sliding pad.

7. The yaw bearing arrangement according to claim 6, wherein the spring is arranged in a hollow spring compartment provide at the sliding pad.

8. The yaw bearing arrangement according to claim 1, wherein the sliding pad comprises a sliding part made of polymer material and a lightning part made of metal, with the lightning part being electrically connected to the bolt.

9. The yaw bearing arrangement according to claim 8, wherein the lightning part is arranged in the ring-shaped sliding part.

10. The yaw bearing arrangement according to claim 1, wherein a lubrication bore is provided in the bolt and the sliding pad ending at the sliding surface of the sliding pad.

11. The yaw bearing arrangement according to claim 1, wherein the ring or the ring segment are separate parts or are integral parts of a bedframe.

12. A wind turbine comprising at least one yaw bearing arrangement according to claim 1.

Description

BRIEF DESCRIPTION

[0016] Some of the embodiments will be described in detail, with references to the following Figures, wherein like designations denote like members, wherein:

[0017] FIG. 1 shows a schematic drawing of a wind turbine;

[0018] FIG. 2 shows a perspective view of an inventive yaw bearing arrangement;

[0019] FIG. 3 shows a cross sectional view of a part of an inventive yaw bearing arrangement with a first adjustment unit;

[0020] FIG. 4 shows a principal view of a second adjustment unit;

[0021] FIG. 5 shows a principal view of a third adjustment unit;

[0022] FIG. 6 shows a principal view of fourth adjustment unit; and

[0023] FIG. 7 shows a cross sectional view of a part of the yaw bearing arrangement of FIG. 1 with an axial sliding unit.

DETAILED DESCRIPTION

[0024] FIG. 1 shows a principal view of a wind turbine 1 comprising a tower 2 and a nacelle 3 comprising a hub 4 with rotor blades 5. The nacelle 3 is rotatable relative to the tower 3 by means of a yaw bearing arrangement 6. For rotation purpose one or more motors are arranged at the nacelle 3 driving a pinion meshing with the gear of a yaw ring 7 fixed to the tower 2. As the drive is provided at the nacelle 3 the nacelle 3 can be rotated relative to the fixed yaw ring respectively the tower 2.

[0025] FIG. 2 shows a perspective view of an inventive yaw bearing arrangement 6. This yaw bearing arrangement comprises a yaw ring 7 with a gear toothing 8 at its outer circumference. The yaw ring 7 is attached to the tower 2 by means of a plurality of bolts inserted into axial bores 9, which maybe threaded or unthreaded.

[0026] The inventive yaw bearing arrangement 6 further comprises radial adjustment means or radial adjustment 10 comprising a housing 11 in the form of a ring 12 being arrangement at the inner diameter of the yaw ring 7. The ring 12 maybe a one-piece ring, it may also be a segmented ring comprising several ring segments, which build the ring form. Instead of a ring 12 the attachment means may also comprise several ring segments extending partially around the inner circumference of the yaw ring 7 but being distanced to each other. For example, four or six or eight ring segments maybe distributed around the circumference, but are distanced with a certain gap to each other. Nevertheless, the basic inventive set up of either a ring or any of these ring segments is the same. While the ring segments or the ring 12 may be separate parts being attached to the nacelle 3 respectively a bedframe of the nacelle 3, the ring segments or the ring 12 can be in integral part of the bedframe of the nacelle, meaning that the segments or the ring 12 is directly casted to or machined out of the bedframe.

[0027] The adjustment means 10 respectively the housing 11 in form of the ring comprises a plurality of axial bores 13, which maybe threaded or unthreaded, into which axial bores 13 fixation bolts are inserted for fixing the housing 11 to a fixation part provided at the nacelle 3, as the adjustment means 10 rotate with the nacelle 3.

[0028] Furthermore FIG. 2 shows a plurality of radial sliding units 14 being oriented in a horizontal direction, and a plurality of axial sliding units 15 being orientated in a vertical direction. These separate sliding units 14, 15 are distributed around the circumference of the ring 12 in relatively high number, as FIG. 2 shows. The radial sliding units 14 are used for radially adjusting and slide guiding the yaw ring 7, while the axial sliding units 15 are used for axially positioning and guiding the yaw ring 7.

[0029] The FIGS. 3-6 show various embodiments of the radial sliding units 14, but the same features and set up also apply to the axial sliding units 15.

[0030] FIG. 3 shows a cross sectional view of a part of the yaw bearing arrangement 6, showing the yaw ring 7 and the housing 11 respectively the ring 12. It also shows two axial bores 13, between which axial bores 13 a radial bore 16 is provided. This radial bore 16 comprises a first threaded bore section 17 having a larger diameter than a second unthreaded bore section 18, which ends adjacent to the lateral inner radial surface 19 the yaw ring 7. The radial bore 16 accommodates a radial sliding unit 14 used for the radial adjustment of the yaw ring 7, comprising an adjustment bolt 20 with a threaded section 21 and an unthreaded section 22 with a smaller diameter. At the free end a tool attachment 23 is provided for screwing the adjustment bolt into the bore 16.

[0031] Furthermore, the radial sliding unit 14 comprises a sliding pad 24 which is arranged in the unthreaded section 18 of the bore 16. As FIG. 3 shows the unthreaded bolt section 22 engages the unthreaded bore section 18 and contacts the sliding pad 24. By screwing the bolt 20 into the bore 16 the position of the sliding pad 21, which contacts the inner lateral surface 19 of the yaw ring 17, can be changed. As a plurality of these separate sliding units 14 is provided, see FIG. 2, it is possible to precisely adjust the radial position of the yaw ring even when strong varying loads rest on the yaw bearing arrangement 6.

[0032] The FIGS. 4 to 6 show various other embodiments of a radial sliding unit 14, which can be inserted into the respective bore 16.

[0033] The radial sliding unit 14 of FIG. 4 also comprises an adjustment bolt 20 with a threaded section 21 having a larger diameter and an unthreaded section 22 having a smaller diameter. It also comprises a sliding pad 24 for contacting the inner lateral surface 19 of the yaw ring 7. In this embodiment an elastic biasing means or biasing member 25 having a plate- or ring-shape is inserted between the sliding pad 24 and the bolt 20. As each of the sliding units 14 comprises such an elastic biasing means or biasing member 25, which biases the sliding pad 24 against the lateral inner surface 19, but which is also used as a damping means or damper for absorbing high load peaks resting on the yaw bearing arrangement due to varying environmental conditions like strongly varying wings etc., a constant contact of all sliding pads 24 to the inner surface 19 is maintained and a damping of loads is possible at all positions.

[0034] This sliding unit 14 can easily be arranged in the respective radial bore 16 by simply inserting the sliding pad 24 and the biasing means or biasing member 25 into the unthreaded section 18 of the bore 16 and screwing the bolt 20 into the threaded section 17.

[0035] FIG. 5 shows another embodiment of a radial sliding unit 14. Also, this adjustment unit 14 comprises a bolt 20 with a threaded section 21 and an unthreaded section 22. It also comprises a sliding pad 24 with a sliding part 29, which is here ring-shaped and which rests directly on the bolt 20. The sliding pad 24 comprises a lightning part 26, which also contacts the inner lateral surface of the yaw ring 7. The lightning part 26 is electrically connected via a cable 27 or the like to the bolt 20. As the bolt 20 is electrically connected to the metal housing 11 which is grounded a secure lightning arrangement is provided.

[0036] Furthermore, a hollow spring compartment 28 is provided in the sliding pad 24, in which the biasing means or biasing member 25 in form of a spring is arranged. This spring acts on the lightning part 26, which is firmly connected to the sliding part 29 of the sliding pad 24. The sliding part 29 is made of a polymer, while the lightning part 26 part is made of metal. It is to be noted that certainly also the sliding pad 24 of the embodiments according to FIGS. 3 and 4 are made of a sliding polymer.

[0037] FIG. 6 shows a sliding unit 14 comparable to the one shown in FIG. 3. It comprises a bolt 20 and a sliding pad 24. Additionally, a lubrication bore 30 is provided which extends through the bolt 20 and the sliding pad 24 and ends at the sliding surface 31 of the sliding pad 24 respectively at the free end of the bolt 20 respectively the tool attachment 23. A lubrication means or lubricator like a lubrication pump or the like can be connected to the lubrication bore 30 for pressing a lubrication fluid through the lubrication bore 30 into the contact area of the sliding pad 24 and the lateral inner surface 19 of the yaw ring 7. In an alternative it is possible to insert a tubing connected to the sliding pad into the lubrication bore 30 for providing a lubrication means into the contact area. It is to be noted that all previously described embodiments may certainly also comprise such a lubrication bore 30.

[0038] Finally, FIG. 7 shows a partial view of the yaw bearing arrangement 6, with the yaw ring 7 and the adjustment means 10 with the housing 11. It also shows some radial sliding units 14 partially cut due to the cross section and the respective radial bores 16 into which they are inserted.

[0039] FIG. 7 also shows the axial sliding means 15, one of them in a cross-sectional view.

[0040] The housing 11 comprises a plurality of axial threaded bores 32, into which the respective axial sliding means 15 are inserted. Each sliding means 15 comprises a at least partially threaded bolt 33 comprising a threaded section 34 and, optionally, an unthreaded section 35. Each sliding unit 15 further comprises a sliding pad 36 resting on the axial adjustment bolt 33. This sliding pad 36 is positioned by means of the axial adjustment bolt 33 relative to an axial surface 37 of the yaw ring 7, which is held in place by the plurality of the sliding pads 36 and which can rotate relative to the sliding pad 36.

[0041] FIG. 7 shows the bolt 33 also comprises a tool attachment 38, so that a tool can easily be attached to the bolt 33 for screwing it.

[0042] Furthermore, a lubrication bore 39 is provided, ending with one end at the free end of the bolt 33, here at the tool attachment 38, and extending through the bolt 33 and the sliding pad 36. A lubrication means or lubricator can be connected to the lubrication bore 39 for pressing a lubrication fluid through the lubrication bore 39 in the contact area of the sliding pad 36 and the surface 37, while also here a tubing can be inserted in the lubrication bore 39 connected to the sliding pad respectively the sliding area.

[0043] FIG. 7 shows a threaded bore 32 and an axial bolt 33, both having a constant diameter. It is to be noted that it is certainly possible to also have a stepped bore 32 and a stepped bolt 33, having respective different sections with different diameters, as is shown for example in FIG. 3 for the radial bore 16 and the radial sliding unit 14.

[0044] Furthermore, the axial sliding units 15 may also comprise respective biasing or damping means or damper, as certainly also a lightning part maybe provided. Therefore, all details explained to the radial sliding unit 14 also refer to the axial sliding unit 15.

[0045] While especially FIG. 2 refers to a ring 12 making the housing 11, it is to be noted that all details explained above also refer to the embodiment with several radial adjustment means or radial adjustment 10 comprising a housing 11 in the form of separate ring segments, which are equally distributed around the inner circumference of the yaw ring 7. These ring segments may connect each other building a ring, or they may be separate from each other by a certain angular displacement. The ring or the ring segments may be separate parts, but they can also be integral with the bedframe of the nacelle, either by being cast with or machined out of the bedframe. However, the set-up is, each ring segment comprises a plurality of at least the radial adjustment means or radial adjustment 10 respectively radial sliding units 14, and, if need be, also a plurality of the axial adjustment means respectively the axial sliding units 15. It is to be noted that, also referring to the embodiments of FIGS. 2-7, the axial adjustment means respectively the axial sliding units 15 are only optional, they may be provided, but embodiments of the invention also cover embodiments where no axial adjustment means respectively axial sliding units 15 are provided.

[0046] Although the present invention has been described in detail with reference to the preferred embodiment, the present invention is not limited by the disclosed examples from which the skilled person is able to derive other variations without departing from the scope of the invention.

[0047] For the sake of clarity, it is to be understood that the use of a or an throughout this application does not exclude a plurality, and comprising does not exclude other steps or elements.