SEALED BEARING MODULE

Abstract

A sealed bearing module for a tidal turbine that has a rotor having rotor blades disposed on a rotor hub and a rotor shaft carrying the rotor for transmitting a drive torque from the rotor hub to a transmission or a generator in a nacelle which nacelle has a housing. The bearing module includes a first bearing ring and a second bearing ring, the first bearing ring is a split bearing ring having a first bearing ring part and a second bearing ring part, the second bearing ring has at least one axially extending bore for attaching the second bearing ring directly to the nacelle housing, the first bearing ring is configured to be connected to the rotor shaft and/or to the rotor hub, and the split bearing ring is preloaded by a preload element.

Claims

1. A sealed bearing module for a tidal turbine, the tidal turbine including a rotor having rotor blades disposed on a rotor hub and a rotor shaft carrying the rotor for transmitting a drive torque from the rotor hub to a transmission or generator in a nacelle, the nacelle including a housing, the bearing module comprising: a first bearing ring and a second bearing ring, wherein: the first bearing ring comprises a split bearing ring including a first bearing ring part and a second bearing ring part, the second bearing ring has at least one axially extending bore for attaching the second bearing ring directly to the nacelle housing, the first bearing ring is configured to be connected to the rotor shaft and/or to the rotor hub, and the split bearing ring is preloaded by a preload element.

2. The sealed bearing module according to claim 1, wherein the bearing module is a double row tapered roller bearing.

3. The sealed bearing module according to claim 2, wherein the tapered roller bearing is configured in a back-to-back arrangement and the first bearing ring is an inner bearing ring, or wherein the tapered roller bearing is configured in a face-to-face arrangement and the first bearing ring is an outer bearing ring.

4. The sealed bearing module according to claim 1, wherein the first bearing ring part and the second bearing ring part each includes a through-bore through which the preload element is passable in order to preload the first and second bearing ring parts against each other.

5. The sealed bearing module according to claim 4, wherein the preload element comprises a threaded rod.

6. The sealed bearing module according to claim 5, wherein an intermediate element is provided between the rotor hub and the split bearing ring, wherein the threaded rod is supported by one end on the intermediate element and supported by the other end on the second bearing ring part.

7. The sealed bearing module according to claim 1, wherein the preload element is a clamping ring including a force-imparting element configured to exert a force on the second bearing ring part, and wherein the rotor shaft includes a support element on which the first bearing ring part is supported.

8. The sealed bearing module according to claim 7, wherein the clamping ring includes a bore configured to allow the clamping ring to be connected to the rotor shaft.

9. The sealed bearing module according to claim 1, wherein the bearing module further includes a seal system for sealing the bearing module.

10. The sealed bearing module according to claim 9, wherein the seal system includes a slip surface and a plurality of seal units, wherein each seal unit includes a seal element including a seal lip that is disposed on the slip surface and that is respectively carried by a seal carrier ring.

11. The sealed bearing module according to claim 9, wherein the preload element comprises a threaded rod or a clamping ring.

12. The sealed bearing module according to claim 1, wherein the preload element comprises a clamping ring, wherein the bearing module is a double row tapered roller bearing having either a back-to-back configuration or a face-to-face configuration and when the tapered roller bearing is configured in a back-to-back arrangement the first bearing ring is an inner bearing ring, and when the tapered roller bearing is configured in a face-to-face arrangement the first bearing ring is an outer bearing ring, and wherein the bearing module further includes a seal system for sealing the bearing module, the seal system including a slip surface and a plurality of seal units, each seal unit comprising a seal element including a seal lip that disposed on the slip surface and respectively carried by a seal carrier ring.

13. A tidal turbine including: a rotor including rotor blades disposed on a rotor hub, a rotor shaft carrying the rotor, and a nacelle including a generator, wherein a drive torque is transmitted from the rotor hub to a transmission or to the generator by a sealed bearing module, the sealed bearing module comprising: a first bearing ring and a second bearing ring, wherein: the first bearing ring comprises a split bearing ring including a first bearing ring part and a second bearing ring part, the second bearing ring has at least one axially extending bore for attaching the second bearing ring directly to the nacelle housing, the first bearing ring is connected to the rotor shaft and/or to the rotor hub, and the split bearing ring is preloaded by a preload element.

14. The tidal turbine according to claim 13, wherein the preload element comprises a threaded rod.

15. The tidal turbine according to claim 13, wherein the preload element comprises a clamping ring.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0032] FIG. 1 is a sectional view of a sealed bearing module for a tidal turbine according to a first embodiment of the present disclosure.

[0033] FIG. 2 is a sectional view of a sealed bearing module for a tidal turbine according to a second embodiment of the present disclosure.

[0034] FIG. 3 is a sectional view of a sealed bearing module for a tidal turbine according to a third embodiment of the present disclosure.

DETAILED DESCRIPTION

[0035] In the following, identical or functionally equivalent elements are designated by the same reference numbers.

[0036] FIG. 1 shows a sealed bearing module 1. The bearing module 1 serves to transmit a drive torque from a rotor hub (not shown) of a rotor of a tidal turbine to a transmission or generator (not shown) in a nacelle of the tidal turbine. Here the transmission of the drive torque is effected in the Figures shown from the left (rotor side) to the right (generator side) via a rotor shaft 2 that transmits a rotation of the rotor hub to the subsequent transmission or the generator. Here the bearing module 1 can be accommodated in particular in a housing 4 of the nacelle. Here the housing 4 protects the bearing and provides mechanical stiffness against bearing deformation.

[0037] The bearing module 1 includes an inner ring 6 and an outer ring 8, between which rolling elements 10 are disposed. In the embodiment shown the bearing module 1 is a double row tapered roller bearing in back-to-back arrangement in which the inner ring is configured as a split ring including a first ring part 6-1 and a second ring part 6-2. As a not-shown alternative embodiment the double row tapered roller bearing can also be configured in face-to-face arrangement including a split outer ring.

[0038] The outer ring 8 includes a through-bore 12, into which an attachment means is insertable in order to connect the outer ring 8 to housing 4. In the embodiment shown in FIG. 1 a threaded rod 14 is provided as attachment means in the through-bore 12, which threaded rod 14 is screwed into the housing 4 by one end. A nut 16 is screwed on the opposite end, via which nut 16 the attachment means is supported on the outer ring 8. Of course the outer ring 8 can also be connected to the housing 4 via bolts that are screwed into the housing 4.

[0039] In order to close housing 4 in the region of outer ring 8, a cover 18 is provided that is connected to the housing 4 via an attachment means and that covers the outer ring 8. As shown in FIG. 1 the attachment means can be a bolt 20 that is screwed from the cover 18 into the housing 4. The attachment means is supported on the cover 18 by a nut or a bolt head 22 that can be countersunk in a recess 24 of the cover 18.

[0040] A preload element is provided to secure and preload the split inner ring 6. In the embodiment shown in FIG. 1 the preload element is configured as clamping ring 26. This includes a through-bore 28 in order to attach the clamping ring 26 to the shaft 2. A bolt 30 is inserted into the through-bore 28 of the clamping ring 26, which bolt 30 is screwed into the rotor shaft 2 by one end. The other end of the bolt 30 is supported on the clamping ring 26 via a nut or a bolt head 32.

[0041] In order to preload the inner ring 6, the clamping ring 26 includes a force-imparting element 34 that projects over the clamping ring 26 in a direction of the inner ring and can thus exert force on the second bearing ring 6-2 in a direction parallel to the longitudinal axis of the shaft 2. In contrast the first bearing ring part 6-1 is supported on a support element 36. This support element 36 can be configured as a projection of the shaft 2 and can be generally referred to as a shaft shoulder.

[0042] The rotor shaft 2 is connected to the rotor hub via a bolt 37. In this way the drive torque can be transmitted directly from the rotor hub to the rotor shaft 2 and thus to the subsequent transmission or generator.

[0043] In order to seal the bearing module 1, the bearing module 1 includes a seal system 38. The seal system 38 includes a plurality of seal units. Each of the seal units includes a seal carrier ring 40 and a seal lip 42 disposed therein. One of the seal units is directly connected to the cover 18 of the housing 4 by a seal carrier ring 40-1. For this purpose an attachment means 44, for example, a screw, is screwed through the seal carrier ring 40-1 into the cover 18 from the side of the seal unit. This seal unit thus serves for attaching the seal system 38 to the housing 4. In this way, the entire seal system 38 can be easily removed as needed from the housing 4 and exchanged.

[0044] A seal cover 46 serves for sealing outward. A plurality of seal units including their seal carrier rings 40-2, 40-3, 40-4, etc. are disposed between this seal cover 46 and the seal unit including the seal carrier ring 40-1. Each of these seal carrier rings 40 includes a seal element 42 including a seal lip. The seal carrier rings 40 are connected to each other via attachment means 48. Here two seal carrier rings 40 are always connected to each other. Here the attachment means 48 are circumferentially offset from one another in the axial direction.

[0045] In operation the seal lips of the seal elements 42 slip against a slip surface 50. The slip surface 50 can be configured integrally with the shaft 2 or, as depicted in FIG. 1, be configured on a spacer ring 52 that is disposed on the shaft 2. In order to seal the bearing module 1, a seal can be provided between the spacer ring 52 and the shaft 2. This sealing can be realized, for example, by O-rings 54.

[0046] If one of the seal lips is worn out, the associated seal element 42 can be exchanged in a simple manner. For this purpose the seal cover 46 is first removed. Then the subsequent seal unit including its seal carrier ring 40 and the seal element 42 can be removed and exchanged as a unit.

[0047] The seal elements 42 serve as a series circuit for keeping seawater out of the bearing. Here the seal element 42-4 must withstand the highest pressure and is therefore worn out first. If the seal element 42-4 no longer withstands the pressure of the seawater, the subsequent seal element 42-3 assumes this function. Here the seal element 42-4 furthermore functions as a filter for larger impurities. In the seal system 38 a sensor (not shown), for example a moisture sensor or pressure sensor, can be disposed that can issue a signal when seawater reaches seal elements 42-3, 42-2, or 42-1. As soon as such a signal is issued, an exchange of the seal elements 42 can be initiated. In addition, seal elements 43-1, 43-2 can be provided on the bearing rings 4, 6, which seal elements 43-1, 43-2 serve to hold lubricant in the bearing.

[0048] FIG. 2 shows a bearing module 1 according to a second embodiment, wherein the embodiments of FIGS. 1 and 2 differ only in the attachment of the outer ring 8 to housing 4.

[0049] As in FIG. 1 the outer ring 8 includes a through-bore 12, into which an attachment means is insertable in order to connect the outer ring 8 to housing 4. In contrast to the embodiment shown in FIG. 1, in FIG. 2 a threaded rod or a bolt 14 is provided as attachment means, which threaded rod or bolt 14 is passed through the through-bore and screwed into the housing 4 by one end, and passes through the cover 18 by the opposite end and is supported on the seal carrier ring 40-1 by the nut or the bolt head 16.

[0050] A second attachment means, as is realized in FIG. 1 by the bolt 20, and the nut or the bolt head 22, can thus be omitted. Optionally the attachment means 44 from FIG. 1 can also be omitted.

[0051] In particular the bearing module 1, as shown in FIG. 2, can be installed on the housing 4 as a complete module. The individual parts, in particular the seal system 38 or the seal carrier ring 40-1, the cover 18, and the outer ring 8 can already be screwed together in advance and represent a structural unit that is preloaded and sealed. This structural unit thus represents a bearing module 1 that is ready for installation in a tidal turbine.

[0052] FIG. 3 shows a bearing module 1 according to a third embodiment, wherein the embodiments of FIGS. 2 and 3 differ by the type of preload element of the inner ring 6 and the arrangement of the inner ring 6.

[0053] In this embodiment the inner ring 6 includes a through-bore 56. Instead of connecting the rotor hub to the generator via a rotor shaft 2, here an optional intermediate element 57 is provided that includes a through-bore 58. The through-bore 58 of the intermediate element 57 is aligned with the through-bore 56 of the inner ring 6. Here the preload element for preloading the ring parts 6-1 and 6-2 of the inner ring 6 is realized by a threaded rod or a bolt 60 that passes through the through-bores 56, 58.

[0054] The threaded rod 60 is supported on one end by a nut 62 on the second ring part 6-2. The force-imparting element 34 of FIGS. 1 and 2 is realized by the nut 62. On the opposite end the threaded rod 60 is supported on the intermediate element 57 by a nut 64. The threaded rod 60 is thus preloaded by the two nuts 62, 64, of which one can be configured as a head of a bolt. Here the inner ring 6 is supported on a stop surface of the intermediate element 57, which stop surface forms the support element 36.

[0055] In this embodiment the use of a clamping ring 26, as provided in FIGS. 1 and 2, can thus be omitted. Furthermore the transmission of the drive torque from the rotor hub to the generator is effected via the intermediate element 57 and the inner ring 6. A separate rotor shaft 2 can thus be omitted. The connecting element 60 can also be extended and thus the rotor hub is completely connected to the subsequent transmission or generator.

[0056] In summary a compact bearing assembly is provided by the disclosed sealed bearing module. In particular the length of the rotor shaft and thus the size or the weight of the nacelle can thereby be reduced. Furthermore the bearing module can already undergo necessary tests prior to installation at its destination, such as, for example, for seal-tightness, whereby the installation or maintenance complexity after installation is simplified.

[0057] Representative, non-limiting examples of the present invention were described above in detail with reference to the attached drawings. This detailed description is merely intended to teach a person of skill in the art further details for practicing preferred aspects of the present teachings and is not intended to limit the scope of the invention. Furthermore, each of the additional features and teachings disclosed above may be utilized separately or in conjunction with other features and teachings to provide sealed bearing modules.

[0058] Moreover, combinations of features and steps disclosed in the above detailed description may not be necessary to practice the invention in the broadest sense, and are instead taught merely to particularly describe representative examples of the invention. Furthermore, various features of the above-described representative examples, as well as the various independent and dependent claims below, may be combined in ways that are not specifically and explicitly enumerated in order to provide additional useful embodiments of the present teachings.

[0059] All features disclosed in the description and/or the claims are intended to be disclosed separately and independently from each other for the purpose of original written disclosure, as well as for the purpose of restricting the claimed subject matter, independent of the compositions of the features in the embodiments and/or the claims. In addition, all value ranges or indications of groups of entities are intended to disclose every possible intermediate value or intermediate entity for the purpose of original written disclosure, as well as for the purpose of restricting the claimed subject matter.

REFERENCE NUMBER LIST

[0060] 1 Bearing module

[0061] 2 Rotor shaft

[0062] 4 Housing

[0063] 6 Inner ring

[0064] 8 Outer ring

[0065] 10 Rolling element

[0066] 12 Through-bore

[0067] 14 Bolt

[0068] 16 Nut

[0069] 18 Cover

[0070] 20 Bolt

[0071] 22 Nut

[0072] 24 Recess

[0073] 26 Clamping ring

[0074] 28 Through-bore

[0075] 30 Bolt

[0076] 32 Nut

[0077] 34 Force-impingement element

[0078] 36 Support element

[0079] 37 Bolt

[0080] 38 Seal system

[0081] 40 Seal carrier ring

[0082] 42 Seal element

[0083] 43 Seal element

[0084] 44 Attachment means

[0085] 46 Seal cover

[0086] 48 Attachment means

[0087] 50 Slip surface

[0088] 52 Spacer ring

[0089] 54 O-ring

[0090] 56 Through-bore

[0091] 57 Intermediate element

[0092] 58 Through-bore

[0093] 60 Bolt

[0094] 62 Nut

[0095] 64 Nut