WO2000068073A1

WO2000068073A1 - Electric rudder propeller of lower installation height

Info

Publication number: WO2000068073A1
Application number: PCT/DE2000/000537
Authority: WO
Inventors: Wolfgang Rzadki; Manfred Heer
Original assignee: Siemens Aktiengesellschaft; Schottel Gmbh & Co. Kg
Priority date: 1999-05-11
Filing date: 2000-02-25
Publication date: 2000-11-16
Also published as: JP2002544039A; ATE246629T1; CA2373465C; CA2373465A1; KR100655006B1; CN1122616C; KR20020021633A; EP1177130A1; PT1177130E; ES2204550T3; DE50003193D1; CN1359345A; EP1177130B1; DK1177130T3

Abstract

The invention relates to an electric rudder propeller for a high-speed marine ship, comprising a multi-phase electric motor which is mounted in a gondola-shaped housing beneath the stern of the ship, using a rotatable, preferably two-part shaft. Said motor can be supplied with electric drive energy by means of a slip ring assembly and can be rotated using drive motors. The rudder propeller is mounted in close proximity to the outer hull (6) in the stern of the ship, in particular, above the water line, using a flat ring bearing (7). The slip ring assembly (8) is located in the upper section (3) of the shaft (2, 3) at the level of the ring-shaped bearing (7) and the drive motors for the rotational movement (9) are low in design and are located at least partially in the interior of the ring bearing (7).

Description

description

Electric rudder propeller with low installation height

The invention relates to an electric rudder propeller with a low installation height for a seagoing fast ship, with a multi-phase electric motor which is fastened in a nacelle-like housing via a rotatable, preferably two-part shaft under the stern of the ship and can be supplied with electrical drive energy and via a slip ring arrangement Drive motors is rotatable.

From the brochure of the companies Siemens and Schottel, title "The SSP Propulsor", No. 159U559 04982, April 1998, a rotating rudder propeller is known in which the slip rings for the transmission of the electrical drive energy as well as the hydraulic drive motors for the rotary movement and whose hydraulic pumps are arranged in a drive machine room (propulsor 500 m) above the rudder propeller. The cables are fed to the slip rings from above.

The object of the invention is to design the known drive in such a way, in particular in the case of Roro ships, that there is more space in the stern of the ship. For Roro ships, e.g. allow a continuous internal Cardeck to be constructed without having to lift the tailgate for the Cardeck and the Cardeck itself. Sufficient repair and maintenance options should still be available. The outflow conditions of the stern should be designed to be optimized for resistance, taking into account the flow conditions that result from the use of rudder propellers.

The object is achieved in that the rudder propeller is mounted in the stern of the ship via a flat ring bearing in the vicinity of the outer skin, in particular above the waterline, the slip ring arrangement in the upper part of the Shaft is housed at the level of the annular bearing and the drive motors for the rotary movement are of low construction and are at least partially arranged in the interior of the ring bearing. This results in the desired low installation arrangement for the electric rudder propeller according to the invention. It initially appears to be impossible to accommodate the slip rings and the drive motors for the rotary movement etc. in the upper part of the shaft with its narrow point "pivot bearing" in such a way that it is still possible to climb down. However, the invention can be implemented by optimizing the size of all parts and largely dispensing with horizontal struts. It is possible to move the drive motors for the rotary movement into the area below the slip ring arrangement.

The flat ring bearing can be arranged above the waterline or alternatively below the waterline. In the case of an arrangement below the water line, it is advantageously kept under excess pressure. The arrangement known from Canadian patent specification 1,311,657 with an entry of the shaft into the ship below the water line and an internal extension of the shaft up to above the water line is significantly less favorable. A seawater intrusion into the interior of the camp can occur here.

If the shaft is mounted above the water line in a ring bearing of large diameter, the bearing diameter being approximately equal to or greater than the winding length of the electric motor, this results, particularly if, as advantageously provided, that ring bearing also has a large inner diameter such a spacious upper part of the shaft of the rudder propeller that the size-optimized slip ring arrangement and the rotary motors can be completely accommodated in it. In this way, a separate machine room above the rudder propeller can be dispensed with very advantageously, and installation height can be saved. The ring bearing can be arranged directly under the Cardeck. It is advantageous if the shaft has a shaft upper part which is arranged sunk above the waterline of the ship and largely in the stern of the ship. In this way it is very advantageously achieved that all essential parts of the rotary drive are arranged protected outside the water flowing around the hull. If the height of the lower part of the shaft corresponds approximately to the nacelle diameter, the result is an overall very low-profile drive, since relatively small propeller diameters can be selected on account of the high-speed double propellers provided for use. A drive of flat going ships is advantageously possible in the embodiment according to the invention.

In a further embodiment of the invention it is provided that the drive motors for the rotary movement as a flat construction

Hydraulic radial piston motors are formed. This results in a particularly favorable version of the rotary motors with small dimensions and high torque.

It is advantageously provided that the shaft, if necessary, via an intermediate deck part directly below the lowest loading deck in the rear area, e.g. the Cardeck on Roro ships, with which the hull is connected. Such a small intermediate cover part, which can also be designed as an annular disk, results in an advantageously particularly stable and low-profile mounting option for the electric rudder propeller. The intermediate cover part can be fitted via assembly elements, e.g. Boxes, as well as immediately, e.g. by placing them on the raised floor in the rear area.

For Roro ships in particular, it is advantageous if the shaft is mounted under a rudder propeller end cover in the stern of the ship, the end cover advantageously being part of the Cardeck when the ship is designed as a Roro ship. This results in a particularly good utilization of those available in the stern of the ship Height that enables the inner Cardeck to be approached directly via the tailgate. The cardeck can be used in full length of the ship, so that the main cardeck uses space to an unprecedented extent. A full utilization of the area of the weather deck is also ensured, whereby the capstan drives etc. can advantageously be arranged under the weather deck to enlarge the usable area.

In an embodiment of the invention, it is provided that the end cover has access openings to individual units of the rudder propeller, e.g. to the slip ring arrangement, to the drive motors for the rotary movement and other essential functional elements. For maintenance work and small repairs, the end cover in the Cardeck does not have to be removed, but the corresponding units can be accessed via manhole-like access openings.

It is advantageously provided that the upper part of the rudder propeller is fireproofly sealed from the bottom deck in the stern area. In this way, the safety requirements of Roro or Ropax ships can advantageously be taken into account without having to change the advantageous design of the electric rudder propeller, which requires a minimum installation height.

For the electric rudder propeller it is further provided that the slip rings for energy supply and control of the motor are at least partially designed as concentric slip rings. This results in a low design for the energy and signal transmission components. For more than 3-phase electric motors, for example for 6-phase or 12-phase electric motors, but also for split electric motors, it is particularly provided that the energy supply slip rings are only 3-phase and that there is branching to one more as a 3-phase winding system of the Motor behind the slip ring arrangement via power semiconductors, which form a decentralized converter and which are arranged in the shaft. With a low-profile, relatively simple slip ring body, the energy supply can also be carried out for multi-phase or split electric motors. This simplifies the construction and considerably reduces the overall height of the slip ring arrangement. In this way, multi-phase winding systems can advantageously be supplied with controlled electrical energy. The power semiconductors can be cooled very advantageously very well by means of heat dissipation elements which are connected to the shaft jacket which is well cooled by the flowing sea water.

The cables for the energy transmission are advantageously guided from the side to the slip ring arrangement of the shaft. This requires a separate connection element on the slip ring arrangement. The resulting additional costs are more than offset by the space gained. The connecting element can advantageously run on the cardeck of a Roro ship between the vehicle tracks. So it does not reduce the low installation height of the rudder propeller.

Due to the arrangement of the drives for the rotary movement and the slip ring body etc. in the upper part of the shaft, they must be close to the auxiliary units in the shaft, e.g. the bilge pumps and

Oil pumps etc. If necessary, there are also power semiconductors in this area, since the lower shaft part is designed to be streamlined and narrow (also acting as a rudder). The formation of heat pockets cannot be ruled out. To remedy this, at least one fan is arranged in the upper part of the shaft, which allows air to circulate in the upper part of the shaft, and possibly also an air exchange.

It is also advantageously provided that the transition from the upper to the lower part of the shaft lies in the plane of the outer skin of the ship, preferably completely above the water line. So the flange between top and bottom part of the ship can be removed from the flow around the hull and the shaft can also be replaced with the electric motor for repairs without having to take the ship into the dock. For a "dry" replacement, it is sufficient if the ship is trimmed to the bow.

In a further embodiment of the invention, it is provided that the motor shaft of the rudder propeller has an inclination that is approximately adapted to the course of the stern of the ship. This results in a particularly favorable outflow in the stern area of the ship, which uses the flow accelerated by the propellers very advantageously to reduce the stern resistance of the ship. Then the rudder propeller according to the invention can be arranged far back without any flow disadvantages. Then the space gain is greatest due to its advantageous training. Overall, not only the use of the rudder propeller according to the invention with a small installation height results in a better utilization of the space available in the hull in the stern area, but also no flow deterioration of the stern area compared to conventional rudder propellers arranged below the ship.

The invention is explained in more detail with reference to drawings, from which, as well as from the subclaims, further details essential to the invention can be found. In detail show:

1 shows a rudder propeller according to the invention with its installation which takes up little space, FIG. 2 shows a double rudder propeller arrangement in the rear area of the

3, the twin rudder propeller arrangement according to FIG. 2 from above,

4 shows the upper shaft part with lateral cable feed from the side, 5 shows the upper shaft part corresponding to FIG. 4 from above and FIG. 6 shows a compressed section through a ring bearing arrangement with a particularly low installation height.

1 shows a Roro or Ropax application with a very low installation height between the outer skin 6 and Cardeck 5. All components of the electric rudder propeller with the exception of the shaft 2 and the motor part 1 are fitted into this low installation height.

To achieve the adjustment described above, the following measures are taken, for example:

Between the outer skin 6 and Cardeck 5, a small intermediate cover part 10, possibly designed as an annular disk, is used, on which the rudder propeller is founded. The fixed parts of the ring bearing 7 are arranged above the intermediate cover part 10. An advantageously fireproof sealed cover 4 is installed in the cardeck 5, through which the underlying rudder propeller unit is accessible. In this - large - cover 4 various, not shown, small covers are used, which make the essential functional parts of the rudder propeller easily accessible. The slip ring arrangement 8 and the rotary motors 9 are largely located in the interior of the ring bearing 7 and in the upper shaft part 3. The ring bearing 7 with the intermediate cover part 10, which is particularly small here, is advantageously arranged in the stern of the ship via a box structure 11.

The large cover 4 can be supported directly or indirectly on the intermediate cover part 10, so that the space under the cover 4 has a very low overall height and the overall installation height is therefore optimally low. The rigid energy Supply cables are advantageously brought from the side to the slip ring arrangement, so that the cover 4 is smooth and can be mounted directly above the slip ring arrangement.

The rudder propeller itself is advantageously inclined so that its drive axis rises to the rear. This improves the outflow even with a short tail. The separating flange between the upper part of the rudder propeller 3 and the shaft can lie approximately in the plane of the outer skin, so that with a relatively far aft arrangement of the rudder propeller and its short design, no flange parts have to be arranged in the flow around the fuselage.

The cover 4 is advantageously given a fire-resistant seal, so that in the event of a fire in this part of the drive system, the cardecks above it are not endangered. Conversely, the function of the propulsion system is not impaired by a fire on the Cardeck and the ship remains ready to sail.

The low height between the intermediate cover part and cover is also achieved by using flat-construction radial piston hydraulic motors for the azimuth drive. The medium voltage of the main motor, low voltage for the auxiliary systems and the signals for the control / regulation of the motor are transmitted via the electrical, in particular multi-part, slip ring arrangement 8 located in the upper part 3 of the shaft. The rudder propeller itself can be rotated 360 °. The slip rings of the slip ring arrangement 8 are in particular arranged concentrically to one another, the signal transmission antennas (not shown in more detail) advantageously being located on the outside. In FIG 2, the two rudder propeller units are designated 18 and 19. In this construction, the intermediate deck part is advantageously located directly on the raised floor 17. The ring bearing is fastened, for example, by means of claws, and the rotary motors, like the slip ring body, are arranged according to the invention in the space 16 below the card deck 15. This results in a low overall height for the installation of the rudder propellers arranged far astern.

As can be seen from FIG. 3, the auxiliary units 12 for the azimuth drive, e.g. the hydraulic pumps and their motors also in the space below the cardeck. The two rudder propellers 13 and 14 are supplied with rotational energy via short hydraulic lines. Even so, according to the invention, a separate machine room above the rudder propellers 13 and 14 can advantageously be dispensed with.

In FIG. 4, 21 designates a cable connection piece which is led out to the side, 23 the upper cover of the slip ring arrangement and 22 the upper parts of the drives for the rotary movement. 4 shows a particularly good example of the achievable small installation height.

In FIG. 5, 24 denotes the connecting part of the cable socket 29, 27 denotes an entry into the shaft and 26 a reserve cross section. 28 denotes a fan and 30 a drive for the rotary movement. Since the components shown all still have connection lines, terminals, fastening elements, flanges etc., it shows that an optimization was necessary here, which required detailed considerations.

In FIG. 6, which shows a low-profile ring bearing according to the invention in a partial sectional view, 31 denotes the Ship structure part that forms the foundation of the ring bearing. This can be, for example, an intermediate deck part, part of the double floor or a ring part on the outer skin of the ship. 32 denotes e.g. in the case of a Roro ship, the deck or a cover in the deck. 33 denotes a motor for the rotary drive, which is attached to a carrier 37. With 34 a drive pinion for the rotating ring 35 of the ring bearing is designated. 36 finally designates the shaft of the rudder propeller, which is connected directly to the rotating part of the ring bearing. The connecting elements between the individual parts, such as flanges with screws, weld seams, etc., are not shown, since FIG. 6 is a basic illustration of a particularly low-profile bearing arrangement. Here, the drive motors 33 for the rotary movement are even arranged completely inside the shaft.

In the example shown in FIGS. 2 and 3, the rudder propellers 13, 14, 18 and 19 are exposed to free flow. This is important, in particular, for particularly low-vibration operation, but flow guiding bodies can also be arranged in front of the rudder propellers, which are in particular hook-shaped with the hook tip at the level of the waves of the rudder propellers. This results in particularly good straight running of the ship, a possible improvement in the propulsion efficiency and a possible improvement in the outflow behavior of the ship's stern. Here, however, the propensity to vibrate of the drive system must be optimized in relation to the advantages achieved, so that these flow guide bodies are more suitable for Roro ferries and less for Ropax ferries or for cruise ships. The optimization is dependent on the ship type, speed and area of application. With the appropriate optimization, all types of ships are advantageous with those in front of the rudder propellers orderly, in cross-section approximately teardrop-shaped flow guide bodies can be equipped. Although the flow guide bodies increase the wetted surface, their advantages for ship behavior, outflow resistance and propulsion efficiency can more than compensate for this disadvantage. Their combination (not shown) with the low-fitting, possibly short, rudder propellers according to the invention is particularly favorable, since here the additional wetted area can be kept small.

Claims

claims

1. Electric rudder propeller for a sea-going fast ship with a multi-phase electric motor, which is fastened in a nacelle-like housing via a rotatable, preferably two-part, shaft under the stern of the ship and can be supplied with electrical drive energy via a slip ring arrangement and rotatable via drive motors , characterized in that the rudder propeller is mounted in the stern of the ship via a flat ring bearing (7) in the vicinity of the outer skin (6), in particular above the waterline, the slip ring arrangement (8) in the upper part (3) of the shaft (2 , 3) is accommodated at the level of the annular bearing (7) and the drive motors for the rotary movement (9) are of low construction and are at least partially arranged in the interior of the ring bearing (4).

2. Electric rudder propeller according to claim 1, characterized in that it is mounted below the water line in the stern of the ship.

3. Electric rudder propeller according to claim 1 or 2, characterized in that the ring bearing (7) is connected to the structural parts of the ship's stern via an intermediate deck part (10), possibly in an annular configuration.

4. Electric rudder propeller according to claim 3, characterized in that the intermediate deck part (10) via a box structure (11) with the structural parts of the

Ship's stern is connected.

5. Electric rudder propeller according to claim 3, characterized in that the intermediate deck part (10), in particular in the form of a ring, is connected to the raised floor (20) of the ship.

6. Electric rudder propeller according to claim 3, 4 or 5, characterized in that the intermediate deck part (10) is arranged directly below the bottom loading deck in the stern area, that is to say, in Roro ships, directly below the card deck (5).

7. Electric rudder propeller according to claim 1, 2, 3, 4, 5 or 6, characterized in that the shaft (2, 3) is mounted under a rudder propeller end cover (4) in the ship's stern.

8. Electric rudder propeller according to claim 7, characterized in that the end cover (4) is part of the card deck (5) when the ship is designed as a Roro ship.

9. Electric rudder propeller according to claim 7 or 8, characterized in that the end cover (4) has access openings to individual units, such as the slip ring arrangement (8), the drive motors (9) for the rotary movement, and other essential functional elements of the rudder propeller.

10. Electric rudder propeller according to one or more of the preceding claims, characterized in that the drive motors (9) for the rotary movement are designed as flat-construction radial piston hydraulic motors.

11. Electric rudder propeller according to one or more of the preceding claims, characterized in that the ring bearing (7) has a ring gear for the rotary movement on the rotatable ring (35) of the ring bearing (7) and the fixed ring with a ship structure part (31), preferably immediately connected.

12th Electric rudder propeller according to one or more of the preceding claims, characterized - net that the motors (33) for the rotary movement are arranged under the ring bearing (7) in the upper shaft part (36), they being held by the carrier (37) and by pinions (34) in the rotatable ring (35) of the ring bearing ( 7) intervene.

13. Electric rudder propeller according to one or more of the preceding claims, characterized in that hydraulic pumps for driving the motors (33) are arranged in the shaft (36), in particular in the form of a power pack.

14. Electric rudder propeller according to one or more of the preceding claims, characterized in that the electrical energy supply to the slip ring arrangement takes place via cables leading from the side to the slip ring arrangement in order to achieve a flat design.

15. Electric rudder propeller according to one or more of the preceding claims, characterized in that the slip ring arrangement has a connection element (21) for a connection from the side coming cables.

16. Electric rudder propeller according to one or more of the preceding claims, characterized in that it has at least one fan in the upper part (3) of the shaft, in particular to avoid heat pockets in the shaft (2, 3) in the region of the auxiliary drives or the like.

17. Electric rudder propeller according to one or more of the preceding claims, characterized in that the upper diameter of the upper shaft part (3) is equal to or greater than the winding length of the electric motor (1).

18. Electric rudder propeller according to one or more of the preceding claims, characterized in that the upper part (3) of the rudder propeller shaft (2,3) is fire-proof sealed from the deck above.

19. Electric rudder propeller according to one or more of the preceding claims, characterized in that in the slip ring arrangement (8) the slip rings for energy supply and control of the motor are at least partially designed as concentric slip rings.

20. Electric rudder propeller, in particular according to one or more of the preceding claims, characterized in that the slip rings for the energy supply of the electric motor are formed in two or three phases and that a branching for a more than two or three-phase winding system of the motor behind the slip ring arrangement , in particular via power semiconductors in the form of a decentralized converter, which is arranged in the shaft (2, 3).

21. Electric rudder propeller according to one or more of the preceding claims, characterized in that the separation point between the upper (3) and lower part (2) of the shaft lies approximately in the plane of the outer skin (6) of the ship and the rudder propeller preferably as far aft in The stern is arranged so that the parting line lies completely above the water line.

22. Electric rudder propeller according to one or more of the preceding claims, characterized in that the separation point between the upper (3) and lower part (2) of the shaft is arranged above the ship's outer skin in a shaft well in the stern of the ship.

23. Electric rudder propeller according to one or more of the preceding claims, characterized in that the length of the ship (2, 3) is dimensioned in such a way and that the motor shaft of the rudder propeller towards the stern is such is arranged in an increasing manner that the flow generated by it attaches itself approximately to the stern course of the ship.