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Title:
MARINE PROPULSION UNIT
Document Type and Number:
WIPO Patent Application WO/2020/120844
Kind Code:
A1
Abstract:
Described is a marine propulsion unit comprising a rotary casing (1) rotatable about a central axis A, and blades (2) extending axially from the rotary casing (1) for rotation with the rotary casing (1) about the central axis A, wherein each blade (2) is mounted for pivotal movement about blade axes B. A blade shaft portion (3) of each blade (2) is at least partly surrounded by a blade housing (4) and by a blade portion (5) of each blade (2) is outside the blade housing (4), wherein the blade housing (4) is releasable attached to the rotary casing (1), and each blade (2) being supported in the blade housing (4) by means of bearings for said pivotal movement.

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Inventors:
MAKSIMAINEN AKI (FI)
PELJO VELI-PEKKA (FI)
PELLINEN PETRI (FI)
Application Number:
PCT/FI2019/050895
Publication Date:
June 18, 2020
Filing Date:
December 16, 2019
Export Citation:
Click for automatic bibliography generation   Help
Assignee:
ABB OY (FI)
International Classes:
B63H5/10
Foreign References:
US2230708A1941-02-04
US2916093A1959-12-08
SU510407A11976-04-15
US1823169A1931-09-15
EP2944556A12015-11-18
Attorney, Agent or Firm:
BOCO IP OY AB (FI)
Download PDF:
Claims:
Claims

1. Marine propulsion unit comprising

a rotary casing (1) rotatable about a central axis A, and

blades (2) extending axially from the rotary casing (1) for rotation with the rotary casing (1) about the central axis A, wherein each blade (2) is mounted for pivotal movement about blade axes B,

characterized

by a blade shaft portion (3) of each blade (2) is at least partly surrounded by a blade housing (4) and by a blade portion (5) of each blade (2) is outside the blade housing (4), wherein the blade housing (4) is releasable attached to the rotary casing (1), and

by each blade (2) being supported in the blade housing (4) by means of bearings (6a and 6b) for said pivotal movement.

2. The marine propulsion unit according to claim 1, characterized

by the rotary casing (1) comprising a lower surface (7) that is configured to be in direct contact with water.

3. The marine propulsion unit according to claim 2, characterized

by the rotary casing (1) comprises mounting seats (8) configured to releasable receive the blade housing (4) of each blade (2), and

by the mounting seats (8) extend from the lower surface (7) of the rotary casing (1) and form apertures in the rotary casing (1).

4. The marine propulsion unit according to claim 3, characterized

by the blade housing (4) has an outer surface (9) and the mounting seat (8) has an inner surface (10), and

by the outer surface (9) of the blade housing (4) abuts the inner surface (10) of the mounting seat (8) so as to prevent lateral movement of the blade housing (4) in the mounting seat (8).

5. The marine propulsion unit according to claim 3 or 4, characterized

by the blade housing (4) has a first section where the cross-section form and the outer dimensions of the blade housing (4) corresponds to the cross-section form and inner dimensions of a second section of the mounting seat (8) so as to prevent lateral movement of the blade housing (4) in the mounting seat (8).

6. The marine propulsion unit according to any of the claims 3 to 5, characterized

by the blade housing (4) comprise a first lower flange (25) having an upper surrounding surface (26) configured to abut a lower surrounding surface (27) of a second lower flange (28) that surrounds the mounting seat (8) when the blade housing (4) is brought into a mounting position in the mounting seat (8) from the side of the lower surface (7) of the rotary casing (1).

7. The marine propulsion unit according to any of the claims 3 to 6, characterized

by the mounting seats (8) being designed and dimensioned to allow inserting and removal of a blade housing (4) having a blade (2) supported in the blade housing (4) by means of bearings (6a and 6b) solely from the side of lower surface (7) of the rotary casing (1).

8. The marine propulsion unit according to claim 1, characterized

by the rotary casing (1) comprises a central portion (29),

by each blade housing (4) comprises a first lateral attachment member (30),

by each blade housing (4) being releasable attached to the rotary casing (1) so that the first lateral attachment member (30) of each blade housing (4) being attached to a corresponding second lateral attachment member (31) provided laterally at the central portion (29) of the rotary casing (1).

9. The marine propulsion unit according to claim 8, characterized

by the rotary casing (1) comprises an outer casing (32) surrounding the central portion (29) of the rotary casing (1),

by the outer casing (32) comprises mounting seats (8) configured to releasable receive the blade housing (4) of each blade (2), and

by the mounting seats extend from a lower outer surface of the outer casing (32) of the rotary casing.

10. The marine propulsion unit according to claim 9, characterized

by the outer casing (32) is composed of several outer casing sections (34) separated by division planes (35) dividing each mounting seat (8) in the outer casing (32) in at least two mounting seat section so the that adjacent outer casing sections (34) of the outer casing (32) comprises a mounting seat section of at least one mounting seat (8).

11. The marine propulsion unit according to claim 9 or 10, characterized

by the mounting seats (8) in the outer casing (32) of the rotary casing (1) being designed and dimensioned to allow inserting and removal of a blade housing (4) having a blade (2) supported in the blade housing (4) by means of bearing (6a and 6b) solely from the side of lower outer surface (33) of the outer casing (32) of the rotary casing (1). 12. The marine propulsion unit according to any of the claims 1 to 11, characterized

by the rotary casing (1) having a hollow interior (39), and

by the first lateral attachment member (30) of each blade housing (4) being releasable attached to a corresponding second lateral attachment member (31) provided laterally at the central portion (29) of the rotary casing (1) by means of fastening means extending from the hollow interior (39) of the rotary casing (1) into the first lateral attachment member (30) of each blade housing (4).

13. The marine propulsion unit according to claim 12, characterized

by threaded holes (36) in the first lateral attachment member (30) of each blade housing (4) being aligned with holes (37) at said corresponding second lateral attachment member (31) provided laterally at the central portion (29) of the rotary casing (1), and

by the fastening means comprising bolts (38) screwed into the threaded holes (36) in the first lateral attachment member (30) of each blade housing (4) from the hollow interior (39) of the rotary casing (1) so that the heads of each bolt (38) being inside the hollow interior (39) of the rotary casing (1).

14. The marine propulsion unit according to any of the claims 1 to 13, characterized

by the marine propulsion unit comprising a mounting body (11), and

by the rotary casing (1) being rotatable mounted at said mounting body (11) for said rotation about the central axis A.

15. The marine propulsion unit according to any of the claims 1 to 13, characterized

by the marine propulsion unit comprising a mounting body (11),

by the rotary casing (1) being rotatable mounted at said mounting body (11) for said rotation about the central axis A,

by the rotary casing (1) having a hollow interior (39),

by the marine propulsion unit being provided with a manhole arrangement (40) for providing access to the hollow interior (39) of the rotary casing (1), and

by the manhole arrangement (40) leading through the mounting body (11) into the hollow interior (39) of the rotary casing (1).

16. The marine propulsion unit according to any of the claims 1 to 15, characterized

by the bearings comprise a first bearing (6a) and a second bearing (6b), and

by the first bearing (6a) being provided inside the blade housing (4) at a first end of the blade shaft portion (3) of the blade (2) and by the second bearing (6b) being provided inside the blade housing (4) at the opposite second end of the blade shaft portion (3) of the blade (2). 17. The marine propulsion unit according to claim 16, characterized

by the first bearing (6a) is a cylindrical bearing or a roller bearing.

18. The marine propulsion unit according to claim 16 or 17, characterized

by a first seal arrangement (12) between the blade shaft portion (3) of the blade (2) and the blade housing (4) at the side of the first bearing (6a) that faces the second bearing (6b).

19. The marine propulsion unit according to any of the claims 16 to 18, characterized

by the second bearing (6b) is a spherical roller bearing.

20. The marine propulsion unit according to any of the claims 16 to 19, characterized

by a second seal arrangement (13) between the blade shaft portion (3) of the blade (2) and the blade housing (4) at the side of the second bearing (6b) that faces the blade portion (5) of the blade (2).

21. The marine propulsion unit according to any of the claims 16 to 20, characterized

by a third seal arrangement (24) between the blade shaft portion (3) of the blade (2) and the blade housing (4) at the side of the second bearing (6b) that faces the first bearing (6a).

22. The marine propulsion unit according to any of the claims 1 to 21, characterized

by each blade comprising a pivoting means (14) functionally connected between the blade (2) and the blade housing (4) to pivot the blade (2) with respect to the blade housing (4) by means of the pivoting means (14) for performing said pivotal movement of the blade (2) about blade axes

B.

23. The marine propulsion unit according to claim 22, characterized

by each pivoting means (14) comprising one of an electric motor, a hydraulic arrangement, and a mechanical arrangement or a combination thereof.

24. The marine propulsion unit according to claim 22 or 23, characterized

by each pivoting means (14) being independently operable.

25. The marine propulsion unit according to any of the claims 22 to 24, characterized

by the blade portion (5) of each blade (2) comprising an elongated leading edge (15) and an elongated trailing edge (16), and

by the marine propulsion unit comprising a steering unit (22) configurable to control the pivoting means (14) so that the trailing edge (16) of the blade portion (5) of each blade (2) moves in an ordinary cycloid or curtate cycloid path when the marine propulsion unit moves. 26. The marine propulsion unit according to any of the claims 22 to 25, characterized by the blade housing (4) encapsulates the pivoting means (14).

27. The marine propulsion unit according to any of the claims 16 to 21 and any of the claims

22 to 26, characterized

by the pivoting means (14) being functionally connected to the blade shaft portion (3) of the blade (2) between the first bearing (6a) and the second bearing (6b).

28. The marine propulsion unit according to claim 27, characterized

by each pivoting means (14) being an electric motor, and

by the electric motor surrounds the blade shaft portion (3) of the blade (2) in the blade housing (4).

29. The marine propulsion unit according to claim 28, characterized

by a stator (17) of the electric motor is attached to the blade housing (4), and

by a rotor (18) of the electric motor is attached to the blade shaft portion (3) of the blade

(2).

30. The marine propulsion unit according to any of the claims 1 to 29, characterized

by the blade housing (4) comprising a bolt flange (19) at the blade housing (4), and by the bolt flange (19) being configured to co-operate with fastening means (20) at the rotary casing (1) for releasable attaching the blade housing (4) to the rotary casing (1).

31. The marine propulsion unit according to any of the claims 1 to 30, characterized

by the rotary casing (1) having a hollow interior (39), and

by the marine propulsion unit being provided with a manhole arrangement (40) for providing access to the hollow (39) interior of the rotary casing (1).

32. A combination of a marine vessel and a marine propulsion unit according to any of the claims

1 to 31, characterized

by the rotary casing (1) having a hollow interior (39) and by the rotary casing being provided with a manhole arrangement (40) for providing a passage between the hollow interior (39) of the rotary casing (1) and the marine vessel.

Description:
MARINE PROPULSION UNIT

Field of the invention

The invention relates to a marine propulsion as defined in the preamble of independent claim 1.

The invention relates generally to cylcloidal-marine propulsion systems such as to flappin foil propulsors for marine vessels or the like.

Publication EP 2 944 556 presents a cycloidal marine-propulsion system. One problem with such cycloidal marine-propulsion system is that due to the relatively complex construction, mounting of a cycloidal marine-propulsion system to a ship and servicing of a cycloidal marine- propulsion system that is mounted to a ship is not easy

Objective of the invention

The object of the invention is to provide a marine propulsion unit that is easy to mount to a ship and that is easier to service.

Short description of the invention

The marine propulsion of the invention is characterized by the definitions of independent claim 1.

Preferred embodiments of the marine propulsion are defined in the dependent claims 2 to 31.

Claim 32 relates to a combination of a marine vessel and a marine propulsion unit according to any of the claims 1 to 31.

List of figures

In the following the invention will described in more detail by referring to the figures, which

Figure 1 shows a first embodiment of the marine propulsion unit,

Figure 2 shoes the marine propulsion unit shown in figure 1 in a state, where one blade unit is removed,

Figure 3 shows a blade unit of the marine propulsion unit shown in figure 1,

Figure 4 shows the blade unit shown in figure 3 from another angle,

Figure 5 shows the marine propulsion unit shown in figure 1 in partly cut view,

Figure 6 shows a detail of the blade unit shown in figure 3 in cut view,

Figure 7 shows another embodiment of the marine propulsion unit in cut view,

Figure 8 shoes the marine propulsion unit shown in figure 1 in cut view and in a state, where one blade unit is removed,

Figure 9 shows in partly cut view a second embodiment of the marine propulsion unit, Figure 10 shows in partly cut view the marine propulsion unit shown in figure 9 in a state, where one blade unit is either being removed from a seat extending from the lower surface of the rotary casing by moving the blade housing of the blade unit out of said seat from the side of the lower surface or the rotary casing or being mounted into seat extending from the lower surface of the rotary casing by moving the blade housing of the blade unit into said seat from the side of the lower surface or the rotary casing,

Figure 11 shows in partly cut view the marine propulsion unit shown in figure 9,

Figure 12 shows in partly cut view the marine propulsion unit shown in figure 9 in a state, where one blade unit is either being removed from a seat extending from the lower surface of the rotary casing by moving the blade housing of the blade unit out of said seat from the side of the lower surface or the rotary casing or being mounted into seat extending from the lower surface of the rotary casing by moving the blade housing of the blade unit into said seat from the side of the lower surface or the rotary casing,

Figure 13 shows a detail of a blade unit of the marine propulsion unit shown in figure 9,

Figure 14 shows in partly cut view a detail of a blade unit of the marine propulsion unit shown in figure 9,

Figure 15 shows in in partly cut view a third embodiment of the marine propulsion unit, and

Figure 16 shows the marine propulsion unit shown in figure 15 as seen from the side,

Figure 17 in partly cut view the marine propulsion unit shown in figure 15 in a state, where outer casing sections of the outer casing of the rotary casing has been removed and where one blade unit is either being removed from the central portion of the rotary casing or being mounted to the central portion of the rotary casing,

Figure 18 in partly cut view the marine propulsion unit shown in figure 15 in a state, where outer casing sections of the outer casing of the rotary casing has been removed and where one blade unit has been being removed,

Figure 19 shows in partly cut view a fourth embodiment of the marine propulsion unit in a state, where one blade unit is either being removed from a seat extending from the lower surface of the rotary casing by moving the blade housing of the blade unit out of said seat from the side of the lower surface or the rotary casing, or being mounted into seat extending from the lower surface of the rotary casing by moving the blade housing of the blade unit into said seat from the side of the lower surface or the rotary casing,

Figure 20 shows in partly cut view the marine propulsion unit shown in figure 9, and

Figure 21 show in partly cut view and in greater detail an example of the fastening of the blade housing of a blade unit to the central portion of the rotary casing in the embodiments of the marine propulsion units illustrated in figures 9 to 20. Detailed description of the invention

The figures show an embodiment of the marine propulsion unit.

The marine propulsion unit comprises a rotary casing 1 rotatable about a central axis A.

The marine propulsion unit comprises blades 2 extending axially from the rotary casing 1 for rotation with the rotary casing 1 about the central axis A. Each blade 2 is preferably, but not necessarily, mounted for pivotal movement about blade axes B generally parallel to the central axis A as illustrated in figure 5.

A blade shaft portion 3 of each blade 2 is at least partly surrounded by a blade housing 4 and a blade portion 5 of each blade 2 is outside the blade housing 4.

The blade housing 4 is releasable attached to the rotary casing 1.

Each blade 2 is supported in the blade housing 4 by means of bearings 6a and 6b for said pivotal movement i.e. to make possible said pivotal movement.

In the marine propulsion unit, each blade 2 can together with a respective blade housing 4 be considered to form a blade unit (not marked with a reference numeral).

The marine propulsion unit provides for several advantages. The blade 2 that is supported in the blade housing 4 by means of the bearings 6a and 6b provides for a clear spare part package. The blade 2 that is supported in the blade housing 4 by means of the bearings 6a and 6b provides for a pre-assembled module that can be tested and be approved for example by classification societies prior mounting the blade 2 to the rotary casing 1 of the marine propulsion unit. Mounting of the blades 2 to the rotary casing 1 is easy: Because the blade shaft portion 3 of the blade 2 is already fitted into the bearings 6a and 6b for example at a factory, the blade shaft portion 3 of the blade 2 need not to be fitted into the bearings 6a and 6b simultaneously when mounting the blade 2 to the rotary casing 1 for example at a shipyard. This also makes servicing and replacing of individual blades easy. This is an advantage, because the blades 2 can be 2 to 3 meters long. The risk that the bearings 6a and 6b are damaged is consequently reduced.

The marine propulsion unit comprises preferably, but not necessarily, a retaining arrangement (not shown in the figures) for keeping the blade shaft portion 5 of each blade 2 in a respective blade housing. Said retaining arrangement can for example comprise at least one of a wedge connection, a shrink connection, a retaining screw and a retaining ring.

The blades 2 are preferably, but not necessarily, evenly distributed at the rotary casing 1 with respect to the central axis A.

The rotary casing 1 of the marine propulsion unit comprises preferably, but not necessarily, a lower surface 7 that is configured to be at least partly in direct contact with water. The lower surface 7 can be flat as shown in the figures.

If the rotary casing 1 comprises such lower surface 7, the rotary casing 1 comprises preferably, but not necessarily, mounting seats 8 configured to releasable receive the blade housing 4 of each blade 2 such that the mounting seats 8 extend from the lower surface 7 of the rotary casing 1 into the rotary casing 1 and form apertures in the rotary casing 1. Alternatively, at least one mounting seat 8 can extend from the lower surface 7 of the rotary casing 1 into the rotary casing 1 so that said at least one mounting seat 8 form a recess in the rotary casing 1.

If the rotary casing 1 comprises such mounting seats, the blade housing 4 has preferably, but not necessarily, an outer surface 9, which can be a circumferential outer surface, as in figure 6, and the mounting seat 8 has preferably, but not necessarily, an inner surface 10, which can be a circumferential inner surface, as in figure 6, such that the outer surface 9 of the blade housing 4 at least partly abuts the inner surface 10 of the mounting seat 8 so as to prevent lateral movement of the blade housing 4 in the mounting seat 8. The inner surface 10 together with the outer surface 9 also functions as steering surfaces when mounting the blade housing 4 together with the blade 2 at the rotary casing 1.

If the rotary casing 1 comprises such mounting seats 8, the blade housing 4 has preferably, but not necessarily, a first section (not marked with a reference numeral) where the cross-section form and the outer dimensions of the blade housing 4 corresponds to the cross-section form and inner dimensions of a second section (not marked with a reference numeral) of the mounting seat 8 so as to prevent lateral movement of the blade housing 4 in the mounting seat 8. The first section together with the second section also functions as steering surfaces when mounting the blade housing 4 together with the blade 2 at the rotary casing 1.

Such first section of the blade housing 4 is preferably, but not necessarily, formed by a circumferential outer surface of the blade housing 4 that has an outer diameter that essentially corresponds to the inner diameter of a second section of the mounting seat 8 in the form of a circumferential inner surface of the mounting seat 8 extending from a lower surface 7 of the rotary casing 1 so as to prevent lateral movement of the blade housing 4 in the mounting seat 8.

If the rotary casing 1 comprises such mounting seats 8, the blade housing 4 can comprise a first lower flange 25 having an upper surrounding surface 26 configured to abut a lower surrounding surface 27 of a second lower flange 28 that surrounds the mounting seat 8 when the blade housing 4 is brought into a mounting position in the mounting seat 8 from the side of the lower surface 7 of the rotary casing 1.

If the rotary casing 1 comprises such mounting seats 8, the mounting seats 8 are preferably, but not necessarily, designed and dimensioned to allow inserting and removal of a blade housing 4 having a blade 2 supported in the blade housing 4 by means of bearings 6a and 6b solely from the side of lower surface 7 of the rotary casing 1. In other words, the so-called pre-assembled module comprising a blade housing 4 having a blade 2 supported in the blade housing 4 by means of bearings 6a and 6b is preferably, but now necessarily, solely insertable and removable from a mounting sear extending from the lower surface of the rotary casing from the side of lower surface 7 of the rotary casing 1. This means that the so-called pre-assembled module can be inserted and removed from the rotary casing 1 without disconnecting the rotary casing for example from the hull 23 of a ship to which the rotary casing 1 is mounted.

In the second embodiment of the marine propulsion unit shown in figures 9 to 14, the third embodiment of the marine propulsion unit shown in figures 15 to 18, and in the fourth embodiment of the marine propulsion unit shown in figure 19, the rotary casing 1 comprises a central portion 29, each blade housing 4 comprises a first lateral attachment member 30, and each blade housing 4 is releasable attached to the central portion 29 of the rotary casing 1 so that the first lateral attachment member 30 of each blade housing 4 is attached to corresponding second lateral attachment member 31 provided laterally at the central portion 29 of the rotary casing 1. The first lateral attachment members 30 can be planar as shown in the figures. The second lateral attachment members 31 can be planar as shown in the figures. A first lateral attachment member 30 of a blade housing 4 can for example be attached to a second lateral attachment member 31 provided laterally at the central portion 29 of the rotary casing 1 by using external fastening means (not illustrated in the figures) once the first lateral attachment member 30 of a blade housing 4 is brought into contact with a second lateral attachment member 31 provided laterally at the central portion 29 of the rotary casing 1. More precisely, as shown in figures 10, 12, 17 and 18, this is done by moving such as lifting the blade housing 4 having a blade 2 supported in the blade housing 4 by means of bearings 6a and 6b in relation to the rotary casing 1 so that the first lateral attachment member 30 of a blade housing 4 is brought into contact with a second lateral attachment member 31 provided laterally at the central portion 29 of the rotary casing 1, whereafter external fastening means are used for releasable fasten the first lateral attachment member 30 of a blade housing 4 to the second lateral attachment member 31 provided laterally at the central portion 29 of the rotary casing 1.

In the third embodiment of the marine propulsion unit shown in figures 15 to 18, and in the fourth embodiment of the marine propulsion unit shown in figure 19 the rotary casing 1 comprises an outer casing 32 surrounding the central portion 29 or the rotary casing 1, the outer casing comprises mounting seats 8 configured to releasable receive the blade housing 4 of each blade 2, and the mounting seats 8 extend from a lower outer surface 33 of the outer casing 32 of the rotary casing 1. One purpose of the outer casing is to improve the hydrodynamic characteristics of the marine propulsion unit by creating a smooth design with less edges, cavities and protrusions and the like.

In the third embodiment of the marine propulsion unit shown in figures 15 to 18, and in the fourth embodiment of the marine propulsion unit shown in figure 19 the outer casing 32 of the rotary casing 1 is composed of several outer casing sections 34 separated by division planes 35 dividing each mounting seat 8 in the outer casing in at least two mounting seat sections (not marked with a reference numeral) so the each adjacent outer casing sections 34 of the outer casing 32 comprises a mounting seat section of at least one mounting seat 8.

In the in the third embodiment of the marine propulsion unit shown in figures 15 to 18 the mounting seats 8 in the outer casing 32 of the rotary casing 1 is designed and dimensioned so that outer casing sections 34 must be removed to allow inserting and removal of a blade housing 4 having a blade 2 supported in the blade housing by means of bearings 6a and 6b. Because the outer casing 32 is divided by division planes 35 into several outer casing sections 34, only some outer casing sections 34 and not the complete outer casing 32 needs to be removed to allow inserting and removal of a blade housing 4 having a blade 2 supported in the blade housing by means of bearings 6a and 6b.

In the in the fourth embodiment of the marine propulsion unit shown in figure 19 the mounting seats 8 in the outer casing 32 of the rotary casing 1 is designed and dimensioned to allow inserting and removal of a blade housing 4 having a blade 2 supported in the blade housing by means of bearings 6a and 6b solely from the side of lower outer surface 35 of the outer casing 32 of the rotary casing 1 and without removing outer casing sections 34. In other words, in the fourth embodiment of the marine propulsion unit shown in figure 19, a blade housing 4 having a blade 2 supported in the blade housing by means of bearings 6a and 6b can moved such as lifted up into a mounting seat 8 extending from the lower surface 22 of the outer casing 32 and correspondingly be lowered from a mounting seat 8 extending from the lower surface 22 of the outer casing 32 without removing outer casing sections 34. In the in the fourth embodiment of the marine propulsion unit shown in figure 19 the mounting seats 8 extending from the lower surface 22 of the outer casing 32 are preferably, but not necessarily, designed to that the mounting seats 8 are configured to steer the first lateral attachment member 30 of a blade housing 4 into contact with a second lateral attachment member 31 provided laterally at the central portion 29 of the rotary casing 1 when blade housing 4 having a blade 2 supported in the blade housing by means of bearings 6a and 6b is moved into the mounting seat 8.

If the marine propulsion unit comprises first lateral attachment members 30 at the blade housings and second lateral attachment members 31 at a central potion 29 of the rotary casing 29, electrical power and/or steering signal connectors (not illustrated in the figures) can also be provided in connection with such first lateral attachment members 30 at the blade housings and second lateral attachment members 31 at a central potion 29 of the rotary casing 29 so that optional electrical power and/or steering signal connections between the blade housing 4 having a blade 2 supported in the blade housing by means of bearings 6a and 6b and other parts of the marine propulsion unit can easily be formed in connection with releasable fastening the first lateral attachment member 30 of a blade housing 4 to the second lateral attachment member 31 provided laterally at the central portion 29 of the rotary casing 1.

If the marine propulsion unit comprises first lateral attachment members 30 at the blade housings and second lateral attachment members 31 at a central potion 29 of the rotary casing 29, the rotary casing 1 has preferably, but not necessarily, as illustrated in figures 20 and 21, a hollow interior 39, and the first lateral attachment member 30 of each blade housing 4 are preferably, but not necessarily releasable attached to a corresponding second lateral attachment member 31 provided laterally at the central portion 29 of the rotary casing 1 by means of fastening means extending from the hollow interior 39 of the rotary casing 1 into the first lateral attachment member 30 of each blade housing 4 as illustrated in figures 20 and 21. Such fastening allows for easy of attachment of the blade housings 4 to and detaching of the blade housings 4 from the central portion 29 of the rotary casing 1. It is for example possible that threaded holes 36 in the first lateral attachment member 30 of each blade housing 4 are aligned with holes 37 at said corresponding second lateral attachment member 31 provided laterally at the central portion 29 of the rotary casing 1, and that the fastening means comprises bolts 38 screwed into the threaded holes 36 in the first lateral attachment member 30 of each blade housing 4 from the hollow interior 39 of the rotary casing 1 so that the heads of each bolt 38 are at least partly inside the hollow interior 39 of the rotary casing 1.

The marine propulsion unit comprises preferably, but not necessarily, a mounting body 11, configured to attach the marine propulsion unit to a marine vessel or the like such as to a ship, preferably to the hull 23 of a ship, wherein the rotary casing 1 is rotatable mounted at said mounting body 11 for said rotation about the central axis A. The marine propulsion unit comprises preferably, but not necessarily, a mounting body 11, configured to attach the marine propulsion unit to a marine vessel or the like such as to a ship, preferably to the hull 23 of a ship, wherein the rotary casing 1 is rotatable mounted at said mounting body 11 for said rotation about the central axis A, and the rotary casing 1 comprises preferably, but not necessarily, having a hollow interior 39, and the marine propulsion unit is preferably, but not necessarily, provided with a manhole arrangement 40 for providing access to the hollow interior 39 of the rotary casing 1 so that the manhole arrangement 40 leads through the mounting body 11 into the hollow interior 39 of the rotary casing 1, as illustrated in figures 7, 8 and 20. The marine propulsion unit comprises preferably, but not necessarily, a rotating means 21 configured to rotate the rotary casing 1 with respect to the mounting body 11. The rotating means 21 can comprise one of an electric motor, as in the embodiment illustrated in figures 7, 8, and 20 a hydraulic arrangement, and a mechanical arrangement or a combination thereof.

The bearings for supporting the blades in the blade housings 4 comprise preferably, but not necessarily, a first bearing 6a and a second bearing 6b. The first bearing 6a is provided inside the blade housing 4 at a first end (not marked with a reference numeral) of the blade shaft portion 3 of the blade 2 and the second bearing 6b is provided inside the blade housing 4 at the opposite second end (not marked with a reference numeral) of the blade shaft portion 3 of the blade 2. An advantage of this is that the first bearing 6a and the second bearing 6b will as far from each other as possible and this provides for a stable supporting of the blades 2 in the blade housings 4.

If the bearings for supporting the blades in the blade housings 4 comprise a first bearing 6a and a second bearing 6b as described, the first bearing 6a is preferably, but not necessarily, a cylindrical bearing or a roller bearing. One purpose of the first bearing 6a is to transmit radial forces from the blade 2 to the rotary casing 1 via the blade housing 4.

If the bearings for supporting the blades in the blade housings 4 comprise a first bearing 6a and a second bearing 6b as described, a first seal arrangement 12 is preferably, but not necessarily, provided between the blade shaft portion 3 of the blade 2 and the blade housing 4 at the first bearing 6a on the side of the first bearing 6a that faces the second bearing 6b. One purpose of the first seal arrangement 12 is to prevent lubrication from leaking from the first bearing 6a.

If the bearings for supporting the blades in the blade housings 4 comprise a first bearing 6a and a second bearing 6b as described, the second bearing 6b is preferably, but not necessarily, a spherical roller bearing. The spherical roller bearing transmits axial and radial forces from the blade 2 to the rotary casing 1 via the blade housing 4.

If the bearings for supporting the blades 2 in the blade housings 4 comprise a first bearing 6a and a second bearing 6b as described, a second seal arrangement 13 is preferably, but not necessarily, between the blade shaft portion 3 of the blade 2 and the blade housing 4 at the second bearing 6b on the side of the second bearing 6b that faces the blade portion 5 of the blade 2. One purpose of the second seal arrangement 13 is to protect the second bearing against water that at least partly surrounds the blade portion 5 of the blade 2, when the marine propulsion unit is mounted at a marine vessel and when the marine vessel floats in water. Another purpose of the second seal arrangement 13 is to prevent lubrication from leaking from the second bearing 6a.

If the bearings for supporting the blades in the blade housings 4 comprise a first bearing 6a and a second bearing 6b as described, a third seal arrangement 24 is preferably, but not necessarily, between the blade shaft portion 3 of the blade 2 and the blade housing 4 at the second bearing 6b on the side of the second bearing 6b that faces the first bearing 6a. One purpose of the third seal arrangement 24 is to prevent lubrication from leaking from the second bearing 6a.

Each blade comprises preferably, but not necessarily, a pivoting means 14 functionally connected between the blade 2 and the blade housing 4. The pivoting means 14 is configured to pivot the blade 2 with respect to the blade housing 4 for performing said pivotal movement of the blade 2 about blade axes B, which may be generally parallel to the central axis A. Each pivoting means 14 can comprise one of an electric motor, a hydraulic arrangement, and a mechanical arrangement or a combination thereof. Each pivoting means 14 is preferably, but not necessarily, independently operable. The blade portion 5 of each blade 2 comprises preferably, but not necessarily, an elongated leading edge 15 and an elongated trailing edge 16, and by the marine propulsion unit comprises preferably, but not necessarily, a steering unit 22 configurable to control the pivoting means 14 so that the trailing edge 16 of the blade portion 5 of each blade 2 moves in an ordinary cycloid or curtate cycloid path when the marine propulsion unit moves linearly when propulsing a marine vessel to move the marine vessel linearly or along a curve when propulsing a marine vessel to move the marine vessel along a curve.

If each blade 2 comprises a pivoting means 14, as described, the blade housing 4 encapsulates preferably, but not necessarily, the pivoting means 14. An advantage of this is that the blade housing 4 protects the pivoting means 14 during assembly at the rotary casing 1. Another advantage is that the pivoting means 14 can be sealed in the blade housing 4 against water by means of the blade housing 4. Another advantage of this is that this provides for an assembly- ready unit comprising both the blade 2 and the pivoting means 14 for pivoting the blade 2 with respect to the rotary casing 1. If each blade 2 of the marine propulsion unit comprise a first bearing 6a and a second bearing 6b as described, and if each blade of the marine propulsion unit comprise a pivoting means 14, as described, the pivoting means 14 is preferably, but not necessarily, functionally connected to the blade shaft portion 3 of the blade 2 between the first bearing 6a and the second bearing 6b, as shown in figure 6. In such case, each pivoting means 14 is preferably, but not necessarily, an electric motor (not marked with a reference numeral), wherein the electric motor surrounds the blade shaft portion 3 of the blade 2 in the blade housing 4. If each pivoting means 14 is an electric motor, the stator 17 of the electric motor is preferably, but not necessarily, attached to the blade housing 4, and the rotor 18 of the electric motor is preferably, but not necessarily, attached to the blade shaft portion 3 of the blade 2, as shown in figure 7.

Each blade housing 4 comprise preferably, but not necessarily, at least one bolt flange 19 at the blade housing 4, wherein the bolt flange 19 is configured to co-operate with fastening means 20, such as with a co-operating bolt flange, at the rotary casing 1 for releasable attaching the blade housing 4 to the rotary casing 1.

Each blade housing 4 can for example comprise, as shown in the figures, a bolt flange 19 at one end of the blade housing 4, wherein the bolt flange 19 is configured to co-operate with fastening means 20, such as with a co-operating bolt flange, at the rotary casing 1 for releasable attaching the blade housing 4 to the rotary casing 1.

The rotary casing 1 of the marine propulsion unit has preferably, but not necessarily, a hollow interior 39, and the marine propulsion unit is preferably, but not necessarily provided with a manhole arrangement 40 for providing access to the hollow 39 interior of the rotary casing 1 as illustrated in figures 7, 8 and 20. Such manhole arrangement 40 is preferably, but not necessarily, configured to provide a passage between the hollow interior 39 of the rotary casing 1 and the marine vessel.

It is apparent to a person skilled in the art that as technology advances, the basic idea of the invention can be implemented in various ways. The invention and its embodiments are therefore not restricted to the above examples, but they may vary within the scope of the claims.




 
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