DE102010054124A1 - submarine - Google Patents

Abstract

A submarine has an inline thruster as a drive device. The inline thruster can be moved from a storage position in a space between a pressure body of the submarine and an outer skin surrounding the pressure body with a linear drive arranged outside the pressure body into a linear end position outside the outer skin and in the end position in a plane normal to its linear direction of travel rotatable with a rotary drive.

Description

The invention relates to a submarine with the features specified in the preamble of claim 1.

Out DE 10 2009 019 539 is a submarine known in addition to a propeller main drive additionally has an auxiliary drive with an inline thruster. The auxiliary drive is used to maneuver the submarine in non-operating or very low speeds of the propeller main drive in the smallest possible space. If the auxiliary drive is not needed, it is located in a space between the pressure hull of the submarine and an outer skin spaced therefrom. If the auxiliary drive is to be used, its inline thruster is moved from there by means of a pivoting mechanism into an operating position on the outside of the outer skin. For this purpose, the in-line thruster is arranged in a frame which is pivotable through an angle of about 90 ° from a storage position of the inline thruster between the pressure hull and the outer skin of the submarine to a working position outside the outer skin. In the working position, the axial direction of the in-line thruster rotatably mounted in the frame and, consequently, its thrust direction can be set with a rotary drive in a plane parallel to a longitudinal axis of the submarine in an angular range of 180 °.

It proves to be disadvantageous in the known submarine that the auxiliary drive has a relatively complicated structural design and occupies a comparatively large space between the pressure body and outer skin in the storage position. Furthermore, the opening through which the in-line thruster is moved from the storage position to the working position is relatively large. Accordingly, a comparatively long gap is formed on the outer skin of the submarine between a fairing, with which the opening is closed when the auxiliary drive is not operating, and the outer skin surrounding this fairing. This gap is unfavorable in that it can lead to unwanted flow noise in military submarines.

Against this background, the object of the invention is to provide a submarine which has an auxiliary drive with an inline thruster, which occupies less space in a storage position between the pressure hull and the outer skin of the submarine than previously used in submarines auxiliary drives, the inline Thruster should be spent on a small opening on the outer skin in its working position outside the outer skin.

This object is achieved by a submarine with the features specified in claim 1. Advantageous developments of this submarine result from the dependent claims, the following description and the drawings. In this case, according to the invention, the features specified in the dependent claims in each case, but also in a technically meaningful combination, the inventive solution according to claim 1 further.

The submarine according to the invention, which is typically but not necessarily a manned submarine and preferably a military submarine, has an in-line thruster. This in-line thruster forms a drive device and preferably an auxiliary drive which for example serves to maneuver the submarine or can be used to keep the submarine calm in the flow when special forces are suspended. The main drive can be provided in the submarine according to the invention, a propeller drive, which is arranged in the usual manner at the rear of the submarine. The inline thruster is stored when not in use in a space between a pressure body and a spaced on the outside of the pressure body of the pressure body outer skin of the submarine. Preferably, this space is formed on an underside or in the area of the keel on the foredeck of the submarine.

According to the invention, the inline thruster is rotatable with a arranged outside the pressure body linear drive from a storage position in the space between the pressure body and the outer skin in a linear end position and rotatable in the end position in a plane normal to its linear travel direction with a rotary drive. That is, in the storage position, the in-line thruster is already aligned so that the orientation of a rotor axis of rotation of the inline thruster coincides with that in the final position, ie, the working position of the in-line thruster outside of the submarine's outer skin. From the storage position of the inline thruster is translationally or straight into its defined, ie previously fixed end position movable in which he has a distance from the hull of the submarine. There, the axial direction and, concomitantly, the thrust direction of the inline thruster can be adjusted by means of the rotary drive in a plane normal to its translational extension direction. By the linear thruster is linearly movable from its storage position to its end position, its maximum space across its extension direction in the storage position is essentially determined solely by its maximum cross section in a plane normal to the extension direction. In this respect, the inline thruster is needed of the submarine according to the invention a significantly smaller space in the space between the pressure hull and the outer skin of the submarine than the previously known swing-out inline thruster. In addition, an opening on the outer skin, over which the inline thruster is moved from the storage position to the end position and vice versa, and, consequently, a closure closing the opening, can be designed to be significantly smaller than previously required.

The linear drive for the inline thruster can basically be a hydraulic or pneumatic linear drive. The inline thruster can be coupled with such a linear drive directly or indirectly via a transmission. However, hydraulic and pneumatic drives have the disadvantage that seawater can leak into the drives and from there into the hydraulic or pneumatic system of the submarine. Therefore, the linear drive for the inline thruster is preferably formed electrically actuated. Consequently, the linear drive is preferably an electromechanical drive, which has the further advantage over pneumatic and hydraulic drives that only electrical lines through the wall of the pressure hull of the submarine must be performed, which is much easier than by the Druckkörperwandung guided compressed air or Hydraulic lines can be sealed pressure-tight.

With the electrically actuated drive, the inline thruster can be directly coupled with motion. For example, an electrically operated linear motor can be provided with which the in-line thruster can be moved from its storage position to its end position outside the outer skin and vice versa. Preferably, however, the linear drive is formed by an electric motor and a gear coupled thereto. This has the advantage that also rotary drive motors can be used, wherein the rotational movement of the rotor of the drive motor is converted by the transmission into a linear movement.

In this context, it is preferably provided that the inline thruster is motion-coupled with a spindle nut of an electrically operated spindle drive. With the spindle drive, a particularly space-saving, narrow linear drive for the inline thruster can be realized. Here, the threaded spindle of the spindle drive is directly coupled to the rotor of an electric motor, d. H. rotatably connected. The longitudinal axis of the threaded spindle is typically aligned in the extension direction of the inline thruster. The screwed onto the threaded spindle spindle, with the inline thruster is connected, is suitably secured against rotation so that it moves in rotation of the threaded spindle in the direction of the longitudinal axis of the threaded spindle, ie in the extension or retraction of the inline thruster.

Although the rotary drive, with which the in-line thruster is rotatable in the end position outside the outer skin of the submarine in a plane normal to the linear extension direction, pneumatically or hydraulically actuated, an embodiment of the rotary drive is preferred, in which this is electrically operated , Thus, a component forming the axis of rotation of the in-line thruster can be connected rotatably directly to the rotor of an electric motor or, if necessary, can itself form the rotor of the electric motor. With the electric motor, the rotation angle of the Inline-Thrusters is infinitely adjustable. The use of an electrically operated rotary drive for the inline thruster is particularly advantageous if its linear drive is designed to be electrically operated, since in this case only one guided through the Druckkörperwandung common electrical supply line for the linear drive and the rotary drive is required.

Particularly advantageous is the inline thruster with the rotary drive in an angular range of 360 ° rotatable. D. h., The inline thruster is in a plane normal to its linear extension direction at least once completely rotatable about its axis of rotation and thus can be rotated in any angular position and so without a reverse thrust thrust in any direction parallel, transverse or oblique Create longitudinal axis of the submarine according to the invention.

Preferably, an extension mast motion-coupled to the linear drive of the inline thruster forms the axis of rotation about which the inline thruster is rotatable in a plane normal to its linear extension direction. Advantageously, the extension mast can then form the rotor of the rotary drive required for this purpose or be rigidly connected to the rotor of the rotary drive. In order to be able to rotate the in-line thruster in an angular range of 360 ° in such an embodiment, the linear drive can advantageously be motion-coupled with the rotary drive. This means that in this development, the linear drive of the inline thruster is also rotated in a plane normal to the linear extension direction of the inline thruster by the same angle as the inline thruster upon rotation of the inline thruster. In the motion coupling of rotary drive and linear drive of the rotary drive is preferably arranged stationarily in the space between the pressure hull and the outer skin of the submarine. In an embodiment in which an electrically actuated spindle drive forms the linear drive of the inline thruster is expediently, the entire linear drive, ie, the threaded spindle and the spindle nut of the spindle drive and a motion-coupled with the threaded spindle electric motor rotatably mounted in the space between the pressure body and outer skin of the submarine.

If both the linear drive and the rotary drive are formed electrically actuated, it is preferably further provided that the linear drive with the rotary drive or vice versa, the rotary drive with the linear drive is voltage-connected. Here, the linear drive and the rotary drive can be connected to each other via an electrical supply line. However, in a configuration in which the rotary drive and the linear drive of the in-line thruster are coupled to one another in terms of motion, this supply line must be designed to be very long in order to enable a rotation angle range of 360 °. Therefore, in this case, an embodiment is preferred in which the linear drive via sliding contacts, for example via a slip ring system, is voltage-connected with an electrical power supply of the rotary drive. In this way, even with any rotation of the linear drive relative to the fixed rotary drive, the power supply of the linear drive via the rotary drive is ensured.

In a further advantageous development, a plug-in connection is provided for supplying voltage to the in-line thruster from a line-connected fixed plug-in connection element to the inline thruster and a plug-in connection element coupled to the spindle nut of the linear drive. Conveniently, the plugged-in with the inline thruster plug connection element is fixedly arranged such that it is then contacted by the motion-coupled with the spindle nut plug connection element when the inline thruster is in its final or working position outside the outer skin of the submarine. Preferably, the motion-coupled with the spindle nut plug connection element is conductively connected via sliding contacts with the power supply of the rotary drive.

The space between the pressure hull and the outer skin of the submarine, in which the inline thruster is stored, is flooded with water. In order to protect the in-line thruster and its drives, especially at a large depth before the prevailing water pressure, the in-line thruster is preferably arranged in its storage position in a pressure-tight sealable housing. Consequently, a housing is arranged in the intermediate space between the pressure body and the outer skin, which receives the in-line thruster together with its linear and rotary drive and encapsulates pressure-tight from the water environment. Typically, the housing has an opening through which the in-line thruster is moved to its end or working position outside the outer skin. This opening is then, when the in-line thruster in its storage position in the housing is advantageously sealed pressure-tight by a lid.

In this context, an embodiment is advantageous in which a cladding element is arranged on an outer side of a stator housing of the inline thruster, which in the storage position of the inline thruster, the housing in which the inline thruster is arranged in the storage position, pressure-tight manner. Conveniently, this cladding element is arranged on the inline thruster in such a way that it closes off an extension opening for the inline thruster formed on the outer skin and thus also forms part of the outer skin of the submarine.

In order to prevent flow turbulences and concomitant flow noise from occurring at the opening of the housing for the storage of the in-line thruster in the case of an extended inline thruster, foreign bodies are advantageously also arranged on the outside of the stator housing of the inline thruster in the extended position of the in-line thruster, the housing in which the in-line thruster is located in the storage position closes.

The invention is explained in more detail with reference to an embodiment shown in the drawing. In the drawing shows:

1 schematically simplified in a sectional side view of a submarine,

2 schematically simplified, a housing with an inline thruster mounted therein in a side view,

3 the housing after 2 in a second side view,

4 the housing after 2 in a sectional view along the section line III-III in 2 .

5 the housing after 2 in perspective,

6 the representation after 2 with an extended inline thruster,

7 the representation after 3 with an extended inline thruster,

8th a sectional view taken along section line VIII-VIII in 6 .

9 the housing after 6 in perspective,

10 enlarges a detail A from 3 and

11 enlarges a detail B out 8th

This in 1 illustrated submarine has a pressure hull 2 on, partially of an outer skin 4 is surrounded. The space between the pressure body 2 and the outer skin 4 is flooded with water. At the stern of the submarine is a propeller drive 6 arranged, which drives the submarine in normal driving. In the foredeck 8th of the submarine is directly on the bow side of the pressure hull 2 an auxiliary drive in the form of an inline thruster 10 arranged. The inline thruster 10 is in the space between pressure hull 2 and outer skin 4 in a pressure-tight housing 12 stored and from there on the keel of the submarine in a working position outside the outer skin 4 traversable.

The housing 12 has a cuboid base body 14 on top of the inline thruster 10 in the storage position. On the outside of the main body 14 are stiffening ribs 16 arranged. The inline thruster 10 is by means of a linear drive from the body 14 of the housing 12 extendable. This linear drive is essentially in a housing part 18 arranged, attached to the main body 14 at one of one on the body 14 trained exit opening for the Inline Thruster 10 connected side connects.

The exit opening of the housing 12 is added in the body 14 retracted inline thruster 10 from a paneling element 20 sealed pressure-tight, that at out of the main body 14 extended inline thruster 10 on an outer region of a stator housing facing away from the extension opening 22 of the inline thruster 10 is arranged. In in the body 14 retracted inline thruster 10 forms the panel element 20 a part of the outer skin 4 of the submarine. To close the extension opening of the housing 12 in the extended state of the inline thruster 10 is a second cladding element 24 provided on the outside of the stator housing 22 the cladding element 20 is arranged directly diametrically opposite ( 8th and 9 ).

Like from the 10 and 11 becomes clear, a spindle drive forms the linear drive of the inline thruster 10 , This spindle drive has a threaded spindle 26 on top of that by an electric motor 28 is driven in rotation. The electric motor 28 is in a foundation 30 arranged in one of the main body 14 remote end region of the housing part 18 is arranged. About the foundation 30 is the case 12 with the inline thruster 10 attached to the boat structure of the submarine. On the threaded spindle 28 is a spindle nut 32 screwed. The spindle nut 32 is secured against rotation and can be so depending on the direction of rotation of the rotor of the electric motor 28 on the threaded spindle 26 from the electric motor 28 away or in the direction of the electric motor 28 move. At the of the electric motor 28 opposite side is on the spindle nut 32 one with the inline thruster 10 connected extension mast 34 attached. By the spindle nut 32 on the threaded spindle 26 from the electric motor 28 is moved away becomes the inline thruster 10 out of the case 12 extended into its final or working position outside the outer skin of the submarine.

To the inline thruster 10 in the end or working position in a plane normal to its linear extension direction or normal to the longitudinal axis of the threaded spindle 28 to be able to turn is a second electric motor 36 intended. This electric motor 36 is in the housing part 18 in one of the electric motor 28 arranged away from the end region. In the usual way, the electric motor 36 a stator 38 in which a rotor 40 is arranged rotatably mounted. The rotor 40 is with the extension mast 34 of the inline thruster 10 motion-coupled. With the electric motor 36 is the inline thruster 10 in an angular range of 360 ° and greater about one of the longitudinal axis of the extension mast 34 rotatable axis formed.

Like the inline thruster 10 is also the entire linear drive rotatable. For this purpose, the linear drive in the housing part 18 in an inner housing 42 arranged. The inner case 42 is substantially tubular and rotatable about its central axis. At one of the inline thruster 10 opposite end is the inner housing 42 from a bearing bush 44 locked. The bearing bush 44 With some play he reaches into an opening of the foundation 30 one. In the bearing bush 44 is the electric motor 28 for driving the threaded spindle 26 arranged.

About an electrical supply line, not shown in the drawing, the electric motor 36 with one in the pressure body 2 arranged the submarine, also not shown in the drawing voltage source line connected. The power supply of the electric motor 28 takes place via the electric motor 36 , This is in the housing part 18 a slip ring 46 arranged. From the 10 and 11 not apparent, is the slip ring 46 in the radial direction divided into two and forms in this way a tubular outer sliding contact, which is fixed in the housing part 48 is arranged and arranged in the outer sliding contact tubular inner sliding contact, on the inner housing 42 is attached and with the inner housing 42 is rotatable relative to the outer sliding contact. With the inner sliding contact is, not shown in the drawing, also rotatable electric motor 28 line-connected.

Also the power supply of the Inline Thruster 10 takes place via the electric motor 36 , In the housing part 18 is a connector element 48 to the electric motor 36 arranged adjacent. The inline thruster 10 is via an electrical supply line, not shown, with the connector element 48 connected. At the spindle nut 32 is at the the electric motor 36 facing side, a second connector element 50 arranged. When extending the inline thruster 10 in its end or working position, the second connector element 50 with the spindle nut 32 in the direction of the first connector element 48 moves until one on the connector element 50 formed annular projection in one of the connector element 48 trained annular groove engages. In this position, the connector element 50 via sliding contacts with the slip ring 46 and so with the power supply of the electric motor 36 electrically connected.

LIST OF REFERENCE NUMBERS

2

pressure vessels

4

shell

6

propeller drive

8th

forecastle

10

Inline Thruster

12

casing

14

body

16

stiffening rib

18

housing part

20

cladding element

22

stator

24

cladding element

26

screw

28

electric motor

30

foundation

32

spindle nut

34

retractable mast

36

electric motor

38

stator

40

rotor

42

inner housing

44

bearing bush

46

slip ring

48

Connector element

50

Connector element

A

detail

B

detail

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 102009019539 [0002]

Claims (12)

Submarine with an inline thruster ( 10 ) as a drive device, characterized in that the inline thruster ( 10 ) from a storage position in a space between a pressure body ( 2 ) of the submarine and a pressure hull ( 2 ) surrounding outer skin ( 4 ) with an outside of the pressure hull ( 2 ) arranged linear drive in a linear end position outside the outer skin ( 4 ) is movable and in the end position in a plane normal to its linear travel direction with a rotary drive is rotatable. Submarine according to claim 1, characterized in that the linear drive is designed to be electrically operated. Submarine according to claim 1, characterized in that the inline thruster ( 10 ) with a spindle nut ( 32 ) is electrically coupled to an electrically operated spindle drive. Submarine according to one of the preceding claims, characterized in that the rotary drive is designed to be electrically actuated. Submarine according to one of the preceding claims, characterized in that the inline thruster ( 10 ) is rotatable with the rotary drive in an angular range of 360 ° about its axis in the extension direction. Submarine according to one of the preceding claims, characterized in that the linear drive is coupled for movement with the rotary drive. Submarine according to one of the preceding claims, characterized in that the linear drive is voltage-connected via sliding contacts with an electrical power supply of the rotary drive. Submarine according to claim 5, characterized in that the inline thruster ( 10 ) is voltage connected via sliding contacts with the electrical power supply of the rotary drive. Submarine according to claim 6, characterized in that for the power supply of the inline thruster, a plug-in connection from one with the inline thruster ( 10 ) line-connected fixed connector element ( 48 ) and one with the spindle nut ( 32 ) of the linear drive motion-coupled connector element ( 50 ) is provided. Submarine according to one of the preceding claims, characterized in that the inline thruster ( 10 ) in its storage position in a pressure-tight lockable housing ( 12 ) is arranged. Submarine according to one of the preceding claims, characterized in that on an outer side of a stator housing ( 22 ) of the inline thruster ( 10 ) a cladding element ( 20 ), which in the storage position of the inline thruster ( 10 ) the housing ( 12 ), in which the inline thruster ( 10 ) is arranged in the storage position, pressure-tight manner. Submarine according to one of the preceding claims, characterized in that on the outside of the stator housing ( 22 ) of the inline thruster ( 10 ) a cladding element ( 24 ), which in the extended position of the inline thruster ( 10 ) the housing ( 12 ), in which the inline thruster ( 10 ) is arranged in the storage position, closes.

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