DEVICE FOR MOUNTING A LINE PIPE IN A ROTARY SHAFT OF A WIND TURBINE, ROTOR SHAFT AND WIND TURBINE

Abstract

A device for mounting a line pipe in a rotor shaft of a wind turbine. The invention also relates to a rotor shaft for a wind turbine and to the wind turbine itself. The device includes a rotor shaft which is configured to be partially hollow and in which the line pipe is arranged. In the line pipe, different media are routed from a fixed nacelle of the wind turbine in the direction of a rotor hub connected to the rotor shaft. These can be not only electrical lines but also optical waveguides and media lines for gases and liquids. The mounting of the line pipe is achieved by a device having a plurality of eccentric fixing elements, wherein the line pipe is oriented concentrically by rotating the eccentric fixing elements.

Claims

1. A device for mounting a line pipe in a rotor shaft of a wind turbine, wherein the line pipe routes lines for different media from a fixed nacelle of the wind turbine in the direction of a rotor hub connected to the rotor shaft, wherein the rotor shaft is partially hollow, the device comprising: a plurality of eccentric fixing elements configured to be rotated so as to orient the line pipe concentrically.

2. The device of claim 1 further comprising: at least three rotatable spacers fixedly connected to at least one of said eccentric fixing elements; and, two circular discs connected to one another via said at least three rotatable spacers.

3. The device of claim 1, wherein said plurality of eccentric fixing elements includes six eccentric fixing elements.

4. The device of claim 1, wherein: said plurality of eccentric fixing elements are embodied in the form of a circle segment having an outer circular arc; and, said outer circular arc has a constant outer radius.

5. The device of claim 4 further comprising: at least three rotatable spacers fixedly connected to at least one of said eccentric fixing elements; said at least three rotatable spacers defining an axis of rotation; said outer circular arc of each of said eccentric fixing elements defining a center point of said outer circular arc; and, said center point of each eccentric fixing element being disposed outside said axis of rotation of a corresponding one of said rotatable spacers.

6. The device of claim 2, wherein said circular discs each define a centrally arranged circular cutout.

7. The device of claim 2 further comprising: a bearing configured for mounting the line pipe; and, said bearing being disposed between said two discs and fixedly connected to one of said two discs.

8. The device of claim 2 further comprising: a plurality of u-shaped spacer plates; and, one of said plurality of u-shaped spacer plates being arranged between each two mutually adjacent ones of said rotatable spacers and being fixedly connected to each of said two mutually adjacent discs.

9. The device of claim 2, wherein said two discs each define a respective outer edge and a respective circumference; and, each of said two discs has a seal at said respective outer edge over the entirety of said respective circumference.

10. A rotor shaft of a rotor for a wind turbine having a rotor hub, the rotor shaft comprising: a rotor shaft body being at least partially hollow so as to define a rotor shaft interior; said rotor shaft interior being connected to the rotor hub; said rotor shaft interior defining a cylindrical axial space facing the rotor hub and an axial leadthrough facing away from the rotor hub; said axial leadthrough defining a first radial diameter and being configured for a fixed line pipe; said cylindrical axial space defining a second radial diameter; and, said second radial diameter being greater than said first radial diameter with the result that a shoulder is arranged between said cylindrical axial space and the axial leadthrough.

11. The rotor shaft of claim 10 further comprising: a removable device for rotatably mounting the line pipe arranged directly in front of said axial leadthrough; and, said removable device being configured to be connected in a force-fitting manner to the rotor shaft and thus sealing the axial leadthrough.

12. The rotor shaft of claim 10, wherein the rotor is configured to rotate; the rotor shaft further comprising a transmission device configured for different media for connection between a fixed nacelle and the rotating rotor being arranged completely in the rotor shaft.

13. The rotor shaft of claim 12, wherein said transmission device is configured for at least one of electricity, light, gases and fluids.

14. A wind turbine comprising: a rotor having a rotor shaft; a rotor hub; said rotor shaft being at least partially hollow so as to define a rotor shaft interior; said rotor shaft interior being connected to said rotor hub; said rotor shaft interior defining a cylindrical axial space facing the rotor hub and an axial leadthrough facing away from the rotor hub; said axial leadthrough defining a first radial diameter and being configured for a fixed line pipe; said cylindrical axial space defining a second radial diameter; and, said second radial diameter being greater than said first radial diameter with the result that a shoulder is arranged between said cylindrical axial space and the axial leadthrough.

15. The wind turbine of claim 14 further comprising: a removable device for rotatably mounting the line pipe arranged directly in front of said axial leadthrough; and, said removable device being configured to be connected in a force-fitting manner to the rotor shaft and thus sealing the axial leadthrough.

16. The wind turbine of claim 14, wherein the rotor is configured to rotate; the wind turbine further comprising a transmission device configured for different media for connection between a fixed nacelle and the rotating rotor being arranged completely in the rotor shaft.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0020] The invention will now be described with reference to the drawings wherein:

[0021] FIG. 1 shows a rotor shaft and a gearbox in a three-dimensional side view with the device according to the invention arranged therein;

[0022] FIG. 2 shows the device according to the invention in a three-dimensional front view without the bearing inserted;

[0023] FIG. 3 shows the device according to the invention in a three-dimensional front view with the bearing inserted; and,

[0024] FIG. 4 shows a detail view of a spacer with two eccentric fixing elements arranged thereon.

DESCRIPTION OF THE PREFERRED EMBODIMENTS OF THE INVENTION

[0025] Unless otherwise stated, identical reference signs designate identical objects in the figures.

[0026] FIG. 1 shows a rotor shaft 1, which is configured to be hollow in part, of a wind turbine (not shown in more detail). The rotor shaft 1 has a flange 12 by which it is fastened to a rotor hub (not shown here) of the wind turbine. A fixed line pipe 11 (pitch pipe) extends coaxially within the rotor shaft 1 rotating with the rotor hub. The line pipe 11 routes electrical lines from the fixed nacelle (not shown) of the wind turbine in the direction of the end of the rotor shaft 1 that faces the rotor hub. The rotor shaft interior is subdivided into an axial leadthrough 13 for the fixed line pipe 11 and a cylindrical axial space 14. The cylindrical axial space 14 faces the rotor hub and the axial leadthrough 13 is situated at the end facing away from the rotor hub. The cylindrical axial space 14 has a larger radial diameter than the axial leadthrough 13, with the result that a shoulder 15 is situated between them both. The line pipe 11 is connected via a fixed coupling 17 to a transmission device 2, which is arranged completely within the rotor shaft 1, for electrical connection between the fixed nacelle and the rotating rotor hub. At its end facing away from the rotor hub, the transmission device 2 has a bearing 16 via which the housing of the transmission device 2 is mounted opposite the line pipe 11. It is also possible for the line pipe 11 not to be mounted opposite the transmission device 2. The device 3 according to the invention for mounting the line pipe 11 is arranged directly in front of the axial leadthrough 13 and connected in a force-fitting manner to the rotor shaft 1. The axial leadthrough 13 is sealed by the device 3.

[0027] The device 3 according to the invention is shown in a three-dimensional front view in FIG. 2. It includes two circular discs 31 having in each case a centrally arranged circular cutout 32. The two discs 31 are connected to one another by preferably three spacers 33. A different number of spacers 33 is conceivable. Furthermore, to increase the stability of the entire construction, a u shaped spacer plate 36 is arranged in each case between two spacers 33 and fixedly connected to the two discs 31. Here, the two legs 37 of the u shaped spacer plates 36 point in the direction of the outer diameter of the discs 31. The bent-off regions (legs 37) of the spacer plates 36 prevent the entire device 3 from being able to tilt within the rotor shaft 1. The discs 31 are each provided with a seal 38 at their outer edge over their entire circumference.

[0028] The spacers 33 are arranged rotatably between the discs 31 and can be moved from outside, for example via a hexagon key. Two eccentric fixing elements 34 in the form of a circle segment with an outer circular arc 35 are arranged on each spacer 33, wherein this outer circular arc 35 has a constant outer radius and points in the direction of the inner wall of the cylindrical axial space 14. The center point of the outer circular arc 35 is situated outside the axis of rotation of the rotatable spacers 33. The eccentricity of the fixing elements 34 accordingly results from the non-coinciding axes of rotation of the spacers 33 and the movement axes of the fixing elements 34.

[0029] A bearing 16 is arranged in the circular cutout 32 of that disc 31 which points towards the shoulder 15, and is fixedly connected to this disc 31, as can be seen in FIG. 3. The line pipe 11 is rotatably mounted in the bearing 16. For concentric mounting of the line pipe 11, the device 3 must be oriented within the cylindrical axial space 14. For this purpose, use is made of the six eccentric fixing elements 34, which can be readily moved via a rotary movement of the spacers 33, for example via a hexagon key.

[0030] When mounting the rotor shaft 1, the device 3 is pushed onto the line pipe 11 in the cylindrical axial space 14 up to the shoulder 15. For this purpose, the eccentric fixing elements 34 are turned inwards, preferably to the left. The bearing 16 is then pushed onto the line pipe 11 and fastened to the disc 31 directed towards the axial leadthrough 13. For this purpose, it is expedient for the, in this case outer, disc 31 to have a larger cutout 32 than the inwardly directed one. The bearing 16 and thus the line pipe 11 are oriented concentrically by rotating the concentric fixing elements 34.

[0031] FIG. 4 shows a detail view of a spacer 33 with two eccentric fixing elements 34 arranged on the end sides thereof and the corresponding fastening accessories in an exploded illustration. The two eccentric fixing elements 34 are positively secured against twisting on the spacer 33 by being fixed in a rabbet 39 of the spacer 33.

[0032] It is understood that the foregoing description is that of the preferred embodiments of the invention and that various changes and modifications may be made thereto without departing from the spirit and scope of the invention as defined in the appended claims.

REFERENCE NUMERALS

[0033] 1 Rotor shaft [0034] 11 Line pipe [0035] 12 Flange [0036] 13 Axial leadthrough [0037] 14 Cylindrical axial space [0038] 15 Shoulder [0039] 16 Bearing [0040] 17 Coupling [0041] 2 Transmission device [0042] 3 Device [0043] 31 Circular discs [0044] 32 Circular cutout [0045] 33 Spacer [0046] 34 Eccentric fixing elements [0047] 35 Outer circular arc [0048] 36 u-shaped spacer plates [0049] 37 Leg of the u-shaped spacer plates 36 [0050] 39 Rabbet in the spacer 33