The present invention relates to a drive device for a vessel.
Electrical drive devices for propulsion and maneuvering of vessels are known in the art. There is a need for an improved drive device for a vessel, in particular for a boat which has a non-electrical primary propulsion, such as a sailboat, a houseboat, a historical vessel, or a replica of a historical vessel, and which overcomes various disadvantages of the related art. Examples of related prior art are US
The present invention has been defined in the accompanying claims.
Possible features and advantages of the invention will be explained in closer detail in the detailed description below, with reference to the non-limiting examples illustrated in the figures.
The invention will be described in the following as non-limiting examples, which illustrate principles of the invention as claimed. Identical reference numerals refer to identical or similar elements throughout the figures.
The drive device is a drive device 100 for a vessel. The drive device 100 is particularly suitable for a vessel in the form of a boat which has a non-electrical primary propulsion, such as a sailboat, a houseboat, a historical vessel, or a replica of a historical vessel. An example of a replica of a historical vessel may be a replica of an ancient wooden boat, for instance a Viking ship.
The drive device 100 may also be designed as a retrofittable drive device.
The drive device 100 includes at least two connectable parts that may be divided vertically in the transverse (as illustrated) or longitudinal direction.
The drive device 100 comprises an electric motor, driving a rotatable drive shaft.
The drive device 100 further comprises an elongate drive device housing 110 which encapsulates the electric motor and the drive shaft.
The drive device 100 further comprises a propeller 140, which is detachably mounted to the rotatable drive shaft.
The drive device housing 110 has an upper connection device 120. The upper connection device is symmetrical about a transverse axis, enabling the drive device housing 110 to be mounted to a structure onboard the vessel in either of two longitudinal directions.
For instance, the drive device housing 110 may be mounted to the structure onboard the vessel via a top mast device connected to the upper connection device. In this case, the upper connection device constitutes a symmetric mast interface of the drive device housing 110.
The drive device housing 110 may also include a lower connection device, illustrated at 130. The lower connection device 130 is symmetrical about a transverse axis 131, enabling the drive device housing to be mounted to a bottom mast or a keel in either of two longitudinal directions.
As shown, the propeller 140 is detachably mounted to the drive shaft 142 with a conical standard shape or splines. A seal 144, such as a double lip seal, is arranged at an end portion of the drive device housing 110 which accommodates the gear device 170. A disc 146 is mounted to the end portion of the drive device housing 110, for instance by means of a plurality of bolts (three illustrated). The propeller 140 is detachably mounted to the drive shaft 142 by means of a lock nut 148 that engages with threads on the drive shaft 142. End portion 192 may be formed as a cap which is secured to the drive shaft by means of a central, axial bolt 194.
The upper mast device 122 may be attached to the drive device 100 at the upper connecting device 120 by means of bolts. These and any other bolts that might otherwise be exposed to water, in particular seawater, may advantageously be covered by bolt covers 111, which may be made by, e.g. an elastomer material and designed to maximize the overall streamlined design while protecting the bolt heads against corrosion.
In an alternative arrangement, the vertical shaft 420 may be manually operable.
In the embodiment of
In this embodiment the upper connecting device 120 of the drive device 100 is connected to an upper mast device 122 which includes a horizontal cavitation plate 700 at its upper end. The horizontal cavitation plate 700 is further connected to another mast device 710 which extends up to a tilt device housing 704 which may include an azimuth motor and gear device that is enabled to rotate the azimuth rotatable shaft 420. A set of two hull fixture clamps 706 are arranged to clamp the tilt device housing 704 to a hull of the boat. An actuator 708 may be arranged to provide a tilt function. A keel 135 is provided at the lower portion of the drive device 100. The keel is attached to the lower connection device 130.
The propeller 140 may be interchangeable. In a first configuration, the detachably mounted propeller 140 is a puller propeller, illustrated as 140A, and the drive device housing 110 is mounted to the structure onboard the vessel in such a direction that the puller propeller 140A appears in a forward direction of the vessel.
In this first configuration, if a mast device 122 is interconnected between the structure onboard the vessel, the mast device is arranged as a puller mast device 122A.
In a second configuration, the the detachably mounted propeller 140 is a pusher propeller, illustrated as 140B, and the drive device housing 110 is mounted to the structure onboard the vessel in such a direction that the pusher propeller 140B appears in an astern direction of the vessel.
In this second configuration, if a mast device 122 is interconnected between the structure onboard the vessel, the mast device 122 is arranged as a puller mast device 122B.
The configuration of the mast device 122 as a puller mast device 122A or as a pusher mast device 122B may be achieved by one and the same physical mast device 122, by mounting the mast device in the desired direction, allowed by the upper connection device's symmetrical design about the transverse axis 122.
In this aspect, the drive device housing 110 includes a lower connection device 130. The lower connection device 130 is symmetrical about a transverse axis 131, enabling the drive device housing to be mounted to a keel in either of two longitudinal directions. In this case, “longitudinal” corresponds to the direction of the axis 134.
As will be understood from
The keel 135 may be provided with a longitudinal, straight groove 136 along its upper portion, which is adapted to fit tightly in a corresponding longitudinal tongue 138 protruding down at the lower connection device 130. The keel may thus be slid on the tongue and secured with a set screw. The symmetrical design about the transverse axis 131 enables the keel to be mounted in either of two longitudinal directions.
The drive device 100 illustrated in
The tilt device 200 includes a tilt device housing 210 which includes an electric azimuth motor 220 connected to a rotatable shaft 420. Advantageously, the electric azimuth motor has a rotor shaft which is connected to a transmission unit 230. The transmission unit 230 advantageously includes a reduction gear. In this case the motor shaft of the azimuth motor 220 is connected to the rotatable shaft 420 via the transmission unit 230.
The rotatable shaft 420 is connected to the drive device housing 110, advantageously as shown, via the mast device 122, which has previously been described above, i.a. with reference to
The electric azimuth motor 220 and its interconnected transmission unit 230 are advantageously arranged pivotably with respect to the tilt device housing. The pivotable arrangement provides a rotation of the azimuth motor 220 and the transmission unit 230 about a horizontal axis A.
Advantageously, to enable an effective tilt function, the tilt device 200 further includes a linear actuator 240 with a first end 242 and a second end 244, the first end 242 being pivotably connected to the tilt device housing and the second end being pivotably connected to a rotatable member 250 which is set in a fixed position from transmission unit 230 arranged to lift the rotatable shaft 420.
The tilt device housing 210 has a curved slit 260 on its underside, allowing the rotatable shaft to move along and within the slit during the tilt movement provided by the linear actuator 240. A skirt to prevent water from splashing into tilt device housing 210 may be mounted protruding down from the curved slit 260. Drainage tubes may be mounted in the lower bottom of the tilt device housing 210.
The elements shown in
The elements shown in
However, it is noted that the linear actuator 240 has been shown in retracted state in
The drive device illustrated in
The tilt device 300 includes a hull fixture clamp device 706, which rotates around horizontal axis B. A tilt device housing 310 which includes an electric azimuth motor 220 connected to a rotatable shaft 420. Advantageously, the electric azimuth motor has a rotor shaft which is connected to a transmission unit 230. The transmission unit 230 advantageously includes a reduction gear. In this case the motor shaft of the azimuth motor 220 is connected to the rotatable shaft 420 via the transmission unit 230.
The rotatable shaft 420 is connected to the drive device housing 110, advantageously as shown, via the mast device 122 with a horizontal cavitation plate 700, which has previously been described above, i.a. with reference to
The tilt device housing with electric azimuth motor 220 and its interconnected transmission unit 230 are advantageously arranged pivotably with respect to the hull fixture clamp device about a horizontal axis B.
Advantageously, to enable an effective tilt function, the tilt device 300 further includes a linear actuator 240 with a first end 242 and a second end 244, the first end 242 being pivotably connected to the hull fixture clamp device XXX and the second end being pivotably connected to the tilt device housing 310, arranged to lift the rotatable shaft 420.
The prolonger spacer 1901 allows e.g. for fitting a larger propeller. A typical extension would be between 2.5-7.6 cm. However, the extension is not limited to this interval and can be both larger and smaller than this.
Further the prolonger spacer 1901 has the same interface between the pod and the mast as the upper connection device 120. This ensures that it is compatible with all pods and masts. It also has the same O-ring sealing as the upper connection device 120.
Further since the horizontal bolts 2102 can be twisted around in the horizontal holes 2103 the horizontal bolts 2103 can be aligned to fit any tilt of the prolonger spacer 2001.
Since the O-rings are the same as in the upper connection device 120 this ensures the water seal between the pod and the mast and it fits all pods and masts.
The isolation plate 2205 is placed between the fastening bracket 2204 of the pod and the hull of the vessel. The isolation plate 2205 ensures that no part of the fastening bracket 2204 and the hull of the vessel touches each other.
The isolation plate 2205 further has an isolation sleeve 2202 at the center that allows the vertical shaft that transfers the power from the engine to the propeller to go through it. This isolation sleeve 2202 goes up through the hull 2201 of the vessel and ensures that the vertical shaft do not touch the hull 2201 of the vessel.
In any of the above embodiments and aspects, the various parts may be manufactured in materials suitable for underwater use, in particular seawater use. Example materials are aluminum, stainless steel, bronze or various composites.
The drive device and its respective parts may advantageously be equipped with safety break off points, which is an advantage to reduce damage in case of running aground in shallow water.
The modular design facilitates for attachment of various types of propellers and propellers embodiment, including foldable propellers, kort nozzles and propeller guards.
Also, a catch line may be attached between the drive device or its respective parts and the vessel, in order to prevent complete loss of equipment in case of a break-off.
The invention has been described in detail above as non-limiting examples. It should be understood that the invention can be modified to include various alterations and substitutions. Hence, the invention is not limited by the foregoing detailed description, but by the scope of the claims.
Number | Date | Country | Kind |
---|---|---|---|
20190359 | Mar 2019 | NO | national |
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/EP2020/057464 | 3/18/2020 | WO |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2020/187991 | 9/24/2020 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
3814961 | Nelson et al. | Jun 1974 | A |
7163426 | Varis | Jan 2007 | B2 |
10906621 | Gebhart | Feb 2021 | B2 |
20100248562 | Daikoku | Sep 2010 | A1 |
20110318978 | Krackhardt et al. | Dec 2011 | A1 |
20170327195 | Bergmann et al. | Nov 2017 | A1 |
Number | Date | Country |
---|---|---|
0 590 867 | Apr 1994 | EP |
2 824 028 | Jan 2015 | EP |
3 241 737 | Nov 2017 | EP |
2004-090841 | Mar 2004 | JP |
2017198892 | Nov 2017 | WO |
Entry |
---|
Search Report in counterpart Norwegian U.S. Appl. No. 20/190,359 issued on Apr. 28, 2020 (3 pages). |
International Preliminary Report on Patentability for corresponding International Application No. PCT/EP2020/057464, mailed May 17, 2021 (12 pages). |
International Search Report for corresponding International Application No. PCT/EP2020/057464, mailed Jul. 27, 2020 (7 pages). |
Written Opinion for corresponding International Application No. PCT/EP2020/057464, mailed Jul. 27, 2020 (11 pages). |
Number | Date | Country | |
---|---|---|---|
20220177100 A1 | Jun 2022 | US |