DE102017109697B3 - Attachment of a thrust bearing of a watercraft - Google Patents

Abstract

The invention relates to a shaft system for a watercraft with a thrust bearing (2), a foundation (3) and a fastening device for fastening the thrust bearing (2) to the foundation (3) with at least one support device (4, 5) between the Pressure bearing (2) and the foundation (3) is arranged so that it supports the thrust bearing (2) in a spatial direction (X, Y) on the foundation (3), wherein the support means (4, 5) has a spherical thrust bearing (10) comprising two adjoining bearing discs (11, 12) with a spherically formed surface, wherein the support means (4, 5) has a length adjusting device (13) for adjusting an axial length of the support means (4, 5), characterized in that the Length adjusting device (13) has a threaded ring (14) with an internal thread, which is in engagement with an external thread of a bearing disc (11) of the spherical thrust bearing.

Description

The present invention relates to a wave device for a watercraft with a thrust bearing, a foundation and a fastening device for fastening the thrust bearing to the foundation with at least one support device, which is arranged between the thrust bearing and the foundation, that they the thrust bearing in a spatial direction on the Foundation supported, wherein the support means comprises a spherical thrust bearing comprising two abutting bearing discs with a spherically shaped surface, wherein the support means comprises a length adjusting device for adjusting an axial length of the support means.

Watercraft, such as submarines, are usually equipped with a wave plant over which the vessel is propelled. In addition to a motor, the shaft system typically has a drive shaft connected to a propeller. The drive shaft is often stored in a thrust bearing which allows the transmission of the thrust from the propeller axial thrust on the vessel and absorbs the hydraulic thrust of the shaft by the upcoming external water pressure.

The attachment of the thrust bearing is usually carried out by means of a fastening device on a foundation of the watercraft. Such fasteners may include a plurality of support means, such as wedge-shaped fittings, disposed between the thrust bearing and the foundation to compensate for angular misalignment between the thrust bearing and the foundation, thus establishing alignment of the thrust bearing with the propeller and drive axles. In order to fix the thrust bearing in all spatial directions, such support means are usually arranged in each of three mutually perpendicular spatial directions between the thrust bearing and the foundation. The support devices also serve to absorb loads, in particular shock loads.

The fittings used for support are adapted to the mounting position of the thrust bearing. When performing maintenance or repair work that requires the expansion of the thrust bearing, there is the disadvantage that the fittings are usually not reusable when re-installing the thrust bearing. Usually new fittings must be made, resulting in an increased material and assembly costs.

The publication DE 10 2008 037 677 A1 discloses a propeller pod drive with a thrust bearing which is mounted spherically. However, a simple adjustment of the length of the Abstzützeinrichtung the shaft system is not provided here and only revealed by tightening or loosening a clamping screw.

Against this background, it is an object of the present invention to provide a shaft system, which allows disassembly and realignment of a thrust bearing on a foundation with reduced material and installation costs.

To solve the problem, a shaft system for a watercraft according to claim 1 is proposed.

In the shaft system according to the invention, an angular offset between the thrust bearing and the foundation can be compensated via the support device. The support means comprises a spherical thrust bearing, which comprises two abutting bearing discs with a spherically formed surface. Depending on the angular misalignment between the thrust bearing and the foundation, the bearing discs may shift against each other. It is therefore not necessary to adapt the support device after disassembly and realignment of the thrust bearing against the foundation or to manufacture new. Rather, it is possible to reuse the support device. As a result, the material and assembly costs in the maintenance and repair of the thrust bearing can be reduced. Also, the installation space can be reduced because no access to the space between thrust bearing and foundation is required.

Preferably, the spherical thrust bearing on a first bearing disc having a concave curved surface, and a second bearing disc having a convexly curved surface. In this respect, the first bearing disc in the manner of a bearing cup and the second bearing disc may be formed as accommodated in the bearing cup bearing disc with a curved surface. The bulges of the surfaces of the two bearing discs are preferably adapted to one another such that the bearing discs in the region of the curved surfaces over the entire surface abut each other. For example, the first bearing disk may have a concave curvature with a radius which is identical to a radius of the convex curvature of the second bearing disk. The bearing discs of the spherical thrust bearing preferably have a main extension plane, which is arranged perpendicular to a main loading direction of the spherical thrust bearing.

According to the invention, the support device has a length adjustment device for setting an axial length of the support device. About the length adjustment, the Support device adapted to the distance between the pressure bearing and the foundation. By the length adjustment, it is possible to first introduce the support means in an area between the thrust bearing and the foundation, in particular wherein the support means is not applied to both the thrust bearing and on the foundation. After the introduction of the support means, the axial length of the support means by means of the length adjustment can be changed so that the support device rests both on the thrust bearing and on the foundation. This is particularly advantageous when access to the foundation is limited, for example, when the introduction of support means is not possible from all sides of the foundation.

According to the invention, the length adjusting device has a threaded ring with an internal thread, which is in engagement with an external thread of a bearing disk of the spherical thrust bearing. The length of the supporting device can be adjusted by rotating the threaded ring and the bearing disk. For example, the threaded ring may be rotated relative to the bearing disk to adjust the length. Alternatively, it is possible to rotate the bearing disc relative to the threaded ring to adjust the length.

In this context, it has proven to be advantageous if the threaded ring is supported on the thrust bearing or on the foundation. The threaded ring may be rotatably fixed to the thrust bearing or on the foundation, in particular by means of a torque arm, for example a support plate, which is arranged on a threaded ring, thrust bearing or foundation and can absorb the torque when turning. Alternatively, it is possible that the threaded ring bears against the thrust bearing or the foundation, wherein the threaded ring is rotatable relative to the element on which it rests. Preferably, the support means in a first direction first threaded rings and the support means in a second direction have second threaded rings, wherein the first threaded rings rotatably connected to thrust bearing or foundation and the second threaded rings are rotatable relative to the foundation and thrust bearing.

According to an advantageous embodiment it is provided that first support means for supporting the thrust bearing in a first spatial direction have a Längeneinstelleinrichtung over which a distance between a bearing disc of the spherical thrust bearing and the thrust bearing is adjustable to adapt to a distance between the thrust bearing and the foundation.

Alternatively or additionally, it is preferably provided that second support means for supporting the thrust bearing in a second spatial direction have a length adjustment, via which a distance between a bearing disc of the spherical thrust bearing and the foundation is adjustable to adapt to a distance between the thrust bearing and the foundation. The second spatial direction is preferably arranged transversely, particularly preferably perpendicular, to the first spatial direction.

It has proven to be advantageous if the first support means are connected to a bolt which passes through a flange of the thrust bearing, through the bearing discs of the spherical thrust bearing and through the foundation. About such a bolt axial centering of the bearing discs in the area between the flange of the thrust bearing and the foundation can be done.

Particularly preferably, the bolt is rotatably connected to a bearing disc of the spherical thrust bearing, in particular with a bearing disc whose external thread is in engagement with an internal thread of a threaded ring. For example, this rotationally fixed connection can be produced by a positive connection between the bolt and the bearing disk, preferably by a hexagonal or octagonal shape of the bolt in the region of the bearing disk. Such a configuration has the advantage that the bearing disc can be rotated by a rotation of the bolt. Access to the bearing disc is therefore not absolutely necessary, rotation of the bearing disc can therefore be initiated by a rotation of the bolt starting from one of the bearing plates facing away from the flange of the thrust bearing or the foundation. In this respect, it is possible to adjust the length of the support device by a rotation of the bolt.

According to an advantageous embodiment, the bolt on the ends of the bolt arranged securing elements, in particular nuts. About the securing elements, the thrust bearing, in particular a flange of the thrust bearing can be braced against the foundation. Preferably, the securing element is a mechanical or hydraulic clamping nut. Alternatively preferred may be provided in addition to the securing element, a mechanical or hydraulic clamping nut. By the use of a clamping nut can be ensured that the bolt exerts sufficient force to hold the thrust bearing on the foundation.

An embodiment has proved to be advantageous in which a snap ring on the bolt is arranged. By means of the snap ring, an undesired slippage of the bolt through an opening in the foundation or an opening in the thrust bearing can be prevented.

According to an advantageous embodiment, the second support means on a bearing disc whose back is in contact with a counterbolt. In this respect, the bearing discs of the second support means are preferably as continuous discs, i. without an opening for passing a bolt formed. The counter bolt can act on the back of the bearing disc to set the bearing disc.

An advantageous embodiment provides that the second support means comprise threaded rings having recesses, in particular holes or grooves, for attaching a hook wrench, a pin or key surfaces on their outer contours. In the recesses or on the key surfaces, a tool can be attached, with which the threaded ring can be rotated. In an embodiment in which the threaded ring is rotatably provided with respect to the foundation and the thrust bearing, in this way the length of the support means can be adjusted by turning the threaded ring.

An advantageous embodiment provides that the shaft system has at least three support means, each support means is disposed in each case between the thrust bearing and the foundation that it supports the thrust bearing in a spatial direction of the foundation, wherein in each of three mutually perpendicular directions at least a support device between the thrust bearing and the foundation is arranged. Such a configuration has the advantage that the thrust bearing can be fixed to the foundation in all three spatial directions and loads, in particular shock loads, can be accommodated in all three spatial directions.

The object mentioned at the outset is also achieved by a watercraft, in particular a submarine, which has a shaft system described above.

In the vessel, the same advantages can be achieved, as they have already been described in connection with the shaft system. Furthermore, the advantageous features and configurations explained in connection with the wave installation can be used individually or in combination with the watercraft.

• Die 1 zeigt ein Wasserfahrzeug gemäß einem Ausführungsbeispiel der Erfindung in einer schematischen Darstellung.
• Die 2 zeigt ein Drucklager einer Wellenanlage mit einer Befestigungseinrichtung gemäß einem Ausführungsbeispiel der Erfindung in einer perspektivischen Darstellung.
• Die 3 zeigt das Drucklager einer Wellenanlage mit der Befestigungseinrichtung gemäß 2 in einer Draufsicht.
• Die 4 zeigt eine Schnittdarstellung entlang der Schnittlinie IV-IV in 3.
• Die 5 zeigt eine Schnittdarstellung entlang der Schnittlinie V-V in 3, jedoch ohne den Flansch des Drucklagers.
• Die 6 zeigt das Fundament mit der Befestigungseinrichtung der Wellenanlage aus 2 in einer Seitenansicht.
• Die 7 zeigt das Fundament mit der Befestigungseinrichtung der Wellenanlage gemäß 6 in einer perspektivischen Darstellung.
• Die 8 zeigt das Fundament mit der Befestigungseinrichtung der Wellenanlage gemäß 6 in einer Draufsicht.
• Die 9 zeigt eine Schnittdarstellung entlang der Schnittlinie IX-IX in 8.

Further details, features and advantages of the invention will become apparent from the drawings, as well as from the following description of preferred embodiments with reference to the drawings.

• The 1 shows a watercraft according to an embodiment of the invention in a schematic representation.
• The 2 shows a thrust bearing of a shaft system with a fastening device according to an embodiment of the invention in a perspective view.
• The 3 shows the thrust bearing of a shaft system with the fastening device according to 2 in a top view.
• The 4 shows a sectional view along the section line IV-IV in 3 ,
• The 5 shows a sectional view along the section line VV in 3 but without the flange of the thrust bearing.
• The 6 shows the foundation with the fastening device of the shaft system 2 in a side view.
• The 7 shows the foundation with the fastening device of the shaft system according to 6 in a perspective view.
• The 8th shows the foundation with the fastening device of the shaft system according to 6 in a top view.
• The 9 shows a sectional view along the section line IX-IX in 8th ,

In the various figures, the same parts are always provided with the same reference numerals and are therefore usually named or mentioned only once in each case.

In the 1 is a schematic drawing of a trained as a submarine watercraft 100 illustrated according to an embodiment of the invention. The watercraft 100 has a pressure body 101 on. To drive the watercraft includes 100 a wave plant 50 with a motor 51 , a drive shaft 52 and one over the drive shaft 52 powered propeller 53 , The drive shaft 52 is in a pressure bearing 2 stored, which is the transfer of the originating from the propeller axial thrust on the vessel 100 , in particular on the pressure hull 101 of the watercraft 100 , allows.

The 2 shows part of the shaft system 50 of the watercraft 100 with the thrust bearing 2 , The thrust bearing 2 is about a fastening device 1 with one on the pressure body 101 of the watercraft 100 fixed foundation 3 connected. The foundation 3 has two sub-foundations 3.1 on. The partial foundations 3.1 are each according to Art a half-shell formed, which below the thrust bearing 2 is arranged and three adjacent walls 3.2 comprising a lower portion of the thrust bearing 2 , in particular a flange 2.1 of the thrust bearing 2 , store and surrounded on three sides.

As the representations in 3 to 9 can be seen, the fastening device 1 several support devices 4 . 5 . 6 on which the thrust bearing 2 each in one of three mutually perpendicular directions in space X . Y . Z support. In a first spatial direction Z , here the vertical spatial direction, is the thrust bearing 2 via first support devices 4 supported between the flange 2.1 of the thrust bearing 2 and the foundation 3 are arranged, cf. 4 , Each partial foundation 3.1 are five first support devices 4 assigned so that the thrust bearing 2 opposite the foundation 3 over a total of 10 first support devices 4 is supported, cf. 6 and 7 , In a second spatial direction X , here a horizontal spatial direction, is the thrust bearing 2 via second support means 5 supported cf. 4 and 5 , Each partial foundation 3.1 are four second support devices 5 assigned so that the thrust bearing 2 a total of eight second support devices 5 is supported, cf. 6 and 7 , Furthermore, the thrust bearing 2 in a third spatial direction Y , here another horizontal spatial direction, via third support devices 6 opposite the foundation 3 supported. The third support facilities 6 are functionally identical to the second support devices 5 formed, but differ in the dimensions of the respective Längeneinstelleinrichtungen 13 , Each partial foundation 3.1 are two third support devices 6 assigned, which are oriented in opposite directions, so that the thrust bearing 2 over a total of four third support devices 6 opposite the foundation 3 is supported.

An angular offset between the thrust bearing 2 and the foundation 3 to compensate, have the first, second and third support means 4 . 5 . 6 each a spherical thrust bearing 10 on. The first support device 4 additionally has a spherical additional bearing 20 in the area of the end-mounted nut. The spherical thrust bearing 10 includes a first bearing disc 11 and a second bearing disc 12 , The first and the second bearing disc 11 . 12 lie against each other along spherically formed surfaces. Here is the first bearing disc 11 concave and the second bearing disc 12 is convex. The curvatures of the first bearing disc 11 and the second bearing disc 12 are matched to each other, in particular identical. For example, the curvatures may be spherical with a given radius, the radius of the concave curvature of the first bearing disk 11 identical to the radius of the convex curvature of the second bearing disc 12 is.

The first support devices 4 which the thrust bearing 2 in the first spatial direction Z opposite the foundation 3 support, all are identical. The first support devices 4 are with a bolt 15 connected by an opening in the flange 2.1 of the thrust bearing 2 , through an opening in the spherical thrust bearing 10 and through an opening in the foundation 3 is arranged running. The first and second bearing discs 11 . 12 the first support facilities 4 each have an opening through which the bolt 15 to be led. The opening of the second bearing disc 12 is larger than the diameter of the bolt 15 executed, so that the bolt 15 opposite the second bearing disc 12 can be turned. On the other hand, the opening of the first bearing disc 11 such to the outer contour of the bolt 15 adapted that the bolt and the first bearing disc 11 rotatably connected to each other. The bolt 15 has a polygonal area 15.1 , For example, with a hexagonal or octagonal cross section, which with a corresponding inner contour of the first bearing discs 11 interacts. Thus, the first bearing disc 11 by turning the bolt 15 to be turned around.

The first bearing disc 11 also has an external thread, which with an internal thread of a threaded ring 14 interacts. The threaded ring 14 rests against the underside of the flange 2.1 of the thrust bearing 2 from. The threaded ring 14 is over a sheet 21 on the flange 2.1 of the thrust bearing 2 established. As a result of a rotation of the bolt 15 the first bearing disc rotates 11 - depending on the direction of rotation - either from the threaded ring 14 out or into the threaded ring, so that the axial length of the support 4 is changed. In this respect form the first bearing disc 11 and the threaded ring 14 a length adjustment device 13 the first support device 4 , The length of the support device 4 can thus be at the distance between the thrust bearing 2 and the foundation 3 be adjusted by the distance between the first bearing disc 11 and the thrust bearing 2 , in particular the flange 2.1 of the thrust bearing 2 , is set.

In the middle area of the bolt 15 is on the bolt 15 also a snap ring 16 provided that an undesirable slippage of the bolt 15 through the opening in the foundation 3 prevented during assembly. During assembly, therefore, first of all the bolt 15 on the foundation 3 be determined. Then you can use the spherical thrust bearing 10 and the threaded ring 14 be put on the bolt. Finally, the assembly of the thrust bearing 2 on the bolt 15 respectively. The thrust bearing 2 can be compared to the foundation 3 via arranged at the ends of the bolt securing elements 18 . 19 be clamped, which are designed as nuts. The upper securing element is preferably used 18 around a clamping nut.

Between the bottom of the foundation 3 and the fuse element 19 at the bottom of the bolt 15 is an additional warehouse 20 provided, which is also designed as a spherical thrust bearing. The additional warehouse 20 also has two abutting bearing discs which have spherical surfaces. About the additional warehouse 20 can be an inclination of the bolt 15 due to an angular misalignment between thrust bearings 2 and foundation 3 opposite the bottom of the foundation 3 be compensated.

The second support devices 5 and the third support means 6 which the thrust bearing 2 in the second spatial direction X and the third spatial direction Y opposite the foundation 3 support, all are functionally identical. In detail, they differ in the dimensions of Längeneinstelleinrichtungen 13 and the curvature of the spherical thrust bearings 10 , Unlike the first support facilities 4 are the second support devices 5 and the third support means 6 not penetrated by a bolt. The spherical thrust bearings 10 the second and third support devices 5 . 6 have a first bearing disc 11 on, which is designed as a continuous disc. That means the first bearing disc 11 has no centrally disposed opening for carrying a bolt. The first bearing disc 11 has one of the second bearing disc 12 facing concave front and one the foundation 3 facing flat back on. The first bearing disc 11 has an external thread, which engages with an internal thread of a threaded ring 14 stands. threaded ring 14 and first bearing disc 11 form a length adjustment 13 the second and third support devices 5 . 6 ,

The second and / or third support means 5 . 6 can be mounted by placing it in the space between the flange from above 2.1 of the thrust bearing 2 and the foundation 3 is inserted. In this respect, the threaded ring is 14 the second and / or third support means 5 . 6 initially loose on the foundation 3 at. By turning the threaded ring 14 may be the axial length of the second and / or third support means 5 . 6 be set. On the outer contour of the threaded ring 14 are recesses, for example in the form of grooves or holes, provided, in which a hook wrench can engage. Thus, it is possible the threaded ring 14 to rotate by means of a hook wrench to the length of the second or third support means 5 . 6 adjust.

To determine the length adjustment is a counter bolt 17 through an opening in the foundation 3 brought in. The counter bolt 17 lies on the flat rear side of the first bearing ring 11 at. The thread of threaded ring 14 and first bearing disk 11 can thus be secured against unwanted loosening and adjustment.

The shaft system described above 50 for a watercraft 100 , especially for a submarine, has a thrust bearing 2 , a foundation 3 and a fastening device 1 for mounting the thrust bearing 2 on a foundation 3 on. The fastening device 1 includes at least one support device 4 . 5 . 6 which are so between the thrust bearing 2 and the foundation 3 arranged is that they are the thrust bearing 2 in a spatial direction X . Y . Z on the foundation 3 supported. Furthermore, the support means 4 . 5 . 6 a spherical thrust bearing 10 on, the two adjacent bearing washers 11 . 12 with spherically formed surface. This allows an angular offset between the thrust bearing 2 and the foundation 3 be compensated. The spherical thrust bearing 10 brings with it the advantage that the support device 4 . 5 . 6 after disassembly and reorientation of the thrust bearing 2 opposite the foundation 3 does not need to be adapted or rebuilt. Rather, it is possible, the support device 4 . 5 . 6 reuse. This allows the material and assembly costs in the maintenance and repair of the thrust bearing 2 be reduced.

LIST OF REFERENCE NUMBERS

1

fastening device

2

thrust bearing

2.1

flange

3

foundation

3.1

part foundation

3.2

wall

4

Supporting device (first)

5

Supporting device (second)

6

Supporting device (third)

10

spherical thrust bearing

11

bearing disk

12

bearing disk

13

length adjustment

14

threaded ring

15

bolt

15.1

Polygonal area

16

snap ring

17

lock bolts

18, 19

fuse element

20

additional storage

21

sheet

50

shafting

51

engine

52

drive shaft

53

propeller

100

water craft

101

pressure vessels

X, Y, Z

spatial direction

Claims (13)

Shaft system (50) for a watercraft (100) with a thrust bearing (2), a foundation (3) and a fastening device (1) for fastening the thrust bearing (2) to the foundation (3) with at least one support device (4, 5, 6), which is arranged between the thrust bearing (2) and the foundation (3) such that it supports the thrust bearing (2) in a spatial direction (X, Y, Z) on the foundation (3), wherein the support means (4 , 5, 6) comprises a spherical thrust bearing (10) comprising two abutting bearing discs (11, 12) with a spherically formed surface, wherein the support means (4, 5, 6) comprises a length adjuster (13) for adjusting an axial length of the Supporting device (4, 5, 6), characterized in that the Längeneinstelleinrichtung (13) has a threaded ring (14) with an internal thread which is in engagement with an external thread of a bearing disc (11) of the spherical thrust bearing. Shaft system (50) to Claim 1 , characterized in that the threaded ring (14) on the thrust bearing (2) or on the foundation (3) is supported. Shaft installation (50) according to one of the preceding claims, characterized in that first support means (4) for supporting the thrust bearing (2) in a first spatial direction (Z) have a length adjustment device (13) via which for adaptation to a distance between the thrust bearing (2) and the foundation (3) a distance between a bearing disc (11) of the spherical thrust bearing (10) and the thrust bearing (2) is adjustable. Shaft installation (50) according to one of the preceding claims, characterized in that second support means (5, 6) for supporting the thrust bearing in a second spatial direction (X, Y) have a length adjustment device (13) via which to adapt to a distance between the Thrust bearing (2) and the foundation (3) a distance between a bearing disc (11) of the spherical thrust bearing (10) and the foundation (3) is adjustable. Shaft system (50) to Claim 3 , characterized in that the first support means (4) are connected to a bolt (15) passing through a flange (2.1) of the thrust bearing (2), through the bearing discs (11, 12) of the spherical thrust bearing (10) and through the Foundation (3) runs. Shaft system (50) to Claim 3 , characterized in that second support means (5, 6) for supporting the thrust bearing in a second spatial direction (X, Y) have a length adjusting device (13) via which for adaptation to a distance between the thrust bearing (2) and the foundation (3 ) a distance between a bearing disc (11) of the spherical thrust bearing (10) and the foundation (3) is adjustable, wherein the first support means (4) with a bolt (15) are connected by a flange (2.1) of the thrust bearing ( 2), through the bearing discs (11,12) of the spherical thrust bearing (10) and through the foundation (3). Shaft system (50) to Claim 5 or 6 , characterized in that the bolt (15) rotatably connected to a bearing disc (11) of the spherical thrust bearing (10), in particular with a bearing disc (11) whose external thread is in engagement with an internal thread of a threaded ring (14). Wave plant (50) after one of the Claims 5 to 7 , characterized in that the bolt (15) at the ends of the bolt (15) arranged securing elements (18, 19), in particular nuts, having. Wave plant (50) after one of the Claims 5 to 8th , characterized in that on the bolt (15) a snap ring (16) is arranged. Wave plant (50) after one of the Claims 4 or 6 , characterized in that the second support means (5, 6) have a bearing disc (11) whose rear side is in contact with a counterbolt (17). Wave plant (50) after one of the Claims 4 or 6 or 10 , characterized in that the second support means (5, 6) comprise threaded rings (14) having recesses, in particular holes or grooves, for attaching a hook wrench, pin or key surfaces on their outer contours. Shaft installation (50) according to one of the preceding claims, characterized in that the shaft installation has at least three support devices (4, 5, 6), wherein each support device (4, 5, 6) in each case between the thrust bearing (2) and the foundation ( 3) is arranged such that it supports the pressure bearing (2) in a spatial direction (X, Y, Z) on the foundation (3), wherein in each of three mutually perpendicular spatial directions (X, Y, Z) at least one support device ( 4, 5, 6) between the thrust bearing (2) and the foundation (3) is arranged. A watercraft (100) having a shaft assembly (50) according to any one of the preceding claims.

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