The present invention relates broadly to a mast base assembly for a marine vessel and relates particularly, although not exclusively, to a mast base assembly of an unmanned surface vessel (USV).
According to the present invention there is provided a mast base assembly for a marine vessel, said assembly comprising:
a mast base mounting adapted to secure to the marine vessel;
a mast tilt assembly pivotally mounted to the mast base mounting about a tilt axis for movement of the mast tilt assembly between stowed and operative positions;
a sail slew assembly adapted to mount to a sail associated with the marine vessel, the sail slew assembly operatively coupled to the mast tilt assembly for slewing of the sail about a slew axis of the mast tilt assembly to reorient the sail relative to the marine vessel.
Preferably the sail slew assembly includes a mast slew gear fixed to a mast coupling to which a mast associated with the sail is fitted for slewing movement, the mast coupling mounted to the mast tilt assembly. More preferably the sail slew assembly also includes a sail slew gear mounted to the sail and operatively meshed to the mast slew gear for slewing of the sail. Even more preferably the sail slew gear includes a worm, and the mast slew gear is in the form of a worm gear to which the worm is meshed for slewing of the sail.
Preferably the sail slew assembly further includes a slew gear housing secured to a lower portion of the sail, said gear housing configured to contain the worm and an associated worm drive designed to effect its rotation for slewing of the sail. More preferably the slew gear housing is also configured to contain and rotate about the mast slew gear. Even more preferably the slew gear housing is located internally of and contoured with the lower portion of the sail.
Preferably the mast tilt assembly includes a lever connected to the mast coupling and operatively coupled to a tilt actuator for pivoting of the mast tilt assembly about the tilt axis of the mast base mounting. More preferably the tilt actuator includes a hydraulically-actuated cylinder connected at opposing ends to the lever and the mast base mounting, respectively. Even more preferably the tilt actuator pivots the mast tilt assembly and the associated mast and sail between the stowed and the operative positions in substantially horizontal and vertical orientations, respectively.
Alternatively the mast tilt assembly includes a mast tilt gear connected to the mast coupling and operatively meshed to an actuator gear for pivoting of the mast tilt assembly. In this alternative embodiment the actuator gear includes an actuator worm driven for rotation in both directions via a drive motor to effect pivoting of the mast tilt assembly and the associated sail between the stowed and operative positions.
Preferably the mast base assembly also comprises a mast bearing fitted internally of the mast to permit its slewing movement about the mast coupling. More preferably the mast bearing includes an annular bush fitted between the mast coupling and the mast.
Preferably the sail is a rigid wing sail. More preferably the rigid wing sail is in cross-section generally crescent-shaped. Even more preferably the crescent-shaped wing sail is formed in one-piece. Still more preferably the one-piece wing sail is of a foam sandwich construction.
Preferably the mast is tubular and located substantially mid-way between opposing longitudinal edges of the sail. More preferably the mast is formed integral with the sail. Even more preferably the integral mast is formed internally of the sail.
Alternatively the sail is a rigid wing sail including a pair of elongate rigid panels have an adjoining edge opposing a lateral edge. In this alternative embodiment the wing sail also includes a hinge element arranged to cooperate with the pair of rigid panels at their adjoining edges to permit pivotal movement of said rigid panels relative to one another. In this example the hinge element includes the mast associated with the sail. The sail slew assembly may include a pair of mast slew gears fixed to the mast coupling and dedicated to respective of a pair of sail slew gears mounted to respective of the pair of rigid panels for:
i) pivotal movement of the rigid panels relative to one another; and
ii) slewing of the rigid wing sail relative to the marine vessel.
Preferably the marine vessel includes a deck mounted to a hull, the deck shaped substantially complementary to the sail which at least in part wraps about the deck with the mast tilt assembly in the stowed position. Alternatively or additionally the sail forms part of the deck of the marine vessel with the mast tilt assembly in the stowed position.
Preferably the marine vessel is an unmanned surface vessel.
In order to achieve a better understanding of the nature of the present invention a preferred embodiment of a mast base assembly for a marine vessel will now be described, by way of example only, with reference to the accompanying drawings in which:
a are plan views of the marine vessel of
As shown in
As best shown in
As best seen in
As best shown in
As best seen in
As further illustrated in
In this embodiment the sail 16 is a rigid wing sail of a foam sandwich construction. The rigid wing sail 16 is in cross-section generally crescent-shaped with a foam core and fibreglass skins on its exterior. The mast 34 is tubular and constructed predominantly of carbon fibre of a suitable modulus to provide the required flexural rigidity. Although not illustrated, the sail 16 in its lower portion may be reinforced and shaped to accommodate the sail slew assembly 26. The carbon fibre mast 34 is integral with the sail 16 and in this example located substantially mid-way between opposing longitudinal edges of the sail 16. The sail 16 may also include an end plate 46 for mounting and containment of the sail slew assembly 26.
The sail 16 may include one or more solar panels such as 52A and 52B mounted to its exterior surface for harnessing solar energy in providing supplementary power or charging for the marine vessel 10. Although depicted on the concave surface of the sail 16, the solar panels 52A/B may preferably be located on the convex surface of the sail 16 so that they are exposed to sunlight with the mast tilt assembly 22 in the stowed position with the associated sail 16 wrapping about the deck 12.
a show the marine vessel 10 with the associated sail 16 slewed at various angles depending on the wind direction relative to the vessel 10. The slew angle for the sail 16 relative to the vessel 10 depends primarily on the following factors:
Although not illustrated the mast base assembly 18 includes one or more position sensors designed to detect the position of the sail 16 relative to the vessel 10. The position sensors function in conjunction with the on-board processor to drive the sail slew assembly 26 so that the sail 16 is located at the optimum angular position. The positional sensors also ensure the sail 16 is in appropriate angular alignment for lowering onto the deck 12 to ensure the concave face of the sail 16 wraps about the deck 12 with the mast tilt assembly 22 in the stowed position. As can best be seen in
For ease of reference and in order to avoid repetition, the components of this alternative embodiment which are effectively the same as the preceding embodiment have been designated with an additional “0”. For example, the mast tilt assembly of this other embodiment has been designated as 220. The mast base assembly 180 of this other embodiment is substantially similar to the preceding embodiment except:
In this alternative embodiment the sail slew assembly 260 operates to provide either:
The relative pivotal movement of the rigid sail panels 170A/B effectively reshapes the sail 160 depending on for example the wind direction relative to the marine vessel. The reshaping of the sail 160 may be effected in the course of a tack by “breaking theback” of the sail 160 where its concave face on one tack changes to its convex face on an opposite tack. Unlike the preceding embodiment, the sail 160 need only be slewed through a relatively small angle when tacking, say around 30 to 80 degrees. The sail 160 as shown in
Returning to
In this other embodiment the rigid panels such as 170A and 170B are substantially planar or flat. The flat panels such as 170A may be fabricated in one-piece from metal sheet or plate, such as steel or aluminium. The rigid panels 170A and 170B at their adjoining edges resemble a “piano hinge” interlocked by the mast 340.
Now that a preferred embodiment of a mast base assembly has been described it will be apparent to those skilled in the art that it has the following advantages:
Those skilled in the art will appreciate that the invention as described herein is susceptible to variations and modifications other than those specifically described. For example, the mast tilt assembly may include a mast tilt gear connected to the mast coupling and operatively meshed to an actuator gear for pivoting of the mast tilt assembly. In this alternative embodiment the actuator gear may be in the form of an actuator worm driven for rotation in both directions via a drive motor to effect pivoting of the mast tilt assembly and the associated sail between the stowed an operative positions. The deck of the marine vessel may in part be completed by the sail in its lowered or horizontal orientation where in effect the sail forms part of the deck of the vessel. All such variations and modifications are to be considered within the scope of the present invention the nature of which is to be determined from the foregoing description.
Number | Date | Country | Kind |
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2016903440 | Aug 2016 | AU | national |
Filing Document | Filing Date | Country | Kind |
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PCT/AU2017/050747 | 7/20/2017 | WO | 00 |