The present invention generally relates to the field of watercrafts, in particular marine crafts. More particularly, it relates to a floating marine craft provided with a removable keel. It applies in particular to marine exploration with measuring crafts, and in particular a craft that is an unmanned or crewless drone.
For marine exploration, measuring devices are used, generally sonars, which are located underwater. These measuring devices can be towed behind a ship, but it has also been proposed to use crafts or drones including such measuring devices and having autonomous and/or remote-controlled propulsion and navigation means. These crafts or drones are of relatively small size and, in case of drones, have no crew.
The floating crafts or drones can have appendices under their hull to perform various functions, sometimes combined with each other: anti-drift, ballast or equipment support. Hereinafter, these appendices will be generically called “keel”.
In the wind-driven floating crafts or drones, the keel is used for these anti-drift and ballast functions, in order to counter the capsizing torque exerted by the sails.
In the power-driven floating crafts or drones, the keel is used for these anti-drift functions but not for the ballast. Indeed, the transverse stability of the power-driven floating crafts or drones is above all provided by the hull shape itself and more specifically the large width thereof. For this reason, the keels, generally called “bilge keels”, present on the power-driven crafts are shallow.
The exploration drone is generally brought on the exploration site by a ship that takes it back at the end of the exploration. Between the exploration periods in which it is on the sea, the drone is brought-back on the ship. The keel may be troublesome during recovery and launch operations and, also, for its storage on the ship.
Moreover, these keels, which are located under the craft or drone underwater hull, by increasing its vertical depth or draught. It may be useful to be able to reduce this draught in certain circumstances and one of the solutions commonly adopted consists in that these keels are liftable, that is to say that, thanks to a mechanical means and a guiding system, the keel can be fully or partially retracted inside the craft or drone hull.
In certain cases, these keels are of so great-size that, once lifted, they protrude upward from the upper surface of the deck. In this case, they create a wind resistance and they clutter the decks.
Moreover, certain crafts or drones comprise an appendix or a series of appendices arranged in elevation above the deck and/or the superstructures. These elevated appendices, which may be called “masting” or wheelhouse, these terms being equivalent in the context of the invention, serve in functions that are necessary to crafts or drones, such as supporting different pieces of equipment: navigation lights, communication antennas, radars, flags . . . , motor exhausts, ventilation input/output, tank vents . . . .
Documents SU-1.154.142A1 relating to a sailboat with a centre-board able to be lifted through the hull, WO-2016/144124A1 relating to a ship with “airbag” and mobile weights intended to prevent that a distressed ship lists too much and sinks, and U.S. Pat. No. 4,538,539A relating to a ship with a deformable keel for hydrodynamic modifications are known. Following documents are also known: US 2014/261126 A1 that is related to a sailing boat with a rigid wing; US 2010/279563 A1 that discloses a fin attachment magnetic system; JP S61 253289 A that is related to a sailing boat with an improved keel and DE 84 11 433 U1 that discloses a sailing boat with a rocking keel. Generally, the power-driven ships have hulls of different shapes than those of the sailboats and these power-driven ships have no ballasted keel due to the fact they do not have to counter a torque created by the wind on a sail of a mast.
In order to remedy the above-mentioned drawbacks or even others, the present invention proposes a marine craft that comprises a removable keel facilitating the launch and recovery operations as well as the storage, but also providing the craft with several navigation modes as a function of the keel position. Moreover, in operation, the keel in lifted position has no longer impact on the wind resistance and does no longer clutter the deck thanks to the fact that it is lifted within the wheelhouse or masting, which internally contains a keel-storage space that receives the part of the lifted keel that would otherwise protrude from the deck or the superstructures. Due to their immersed position, the keels may advantageously be equipped with measuring devices.
More particularly, it is proposed according to the invention a floating marine craft comprising at least one hull topped with a deck, the hull extending between a bow and a stern along a longitudinal direction of the craft, the craft comprising, in its lower part, a removable keel, and in its upper part, a wheelhouse erected above the deck, the keel being able to be lowered under the hull and lifted through the hull, the keel having a lower end and an upper end, the upper end of the keel being connected to the hull when the keel is in lowered position.
According to the invention, the wheelhouse internally contains a keel-storage space, and the keel and the keel-storage space are arranged in alignment with each other so that the keel can be lifted by upward translation at least partly into the keel-storage space of the wheelhouse.
The term “marine” in marine craft must be considered in a broad sense, which can relate both a craft adapted to sea or ocean and a craft for lakes, rivers or other stretches of water.
Other non-limitative and advantageous features of the craft according to the invention, taken individually or according to all the technically possible combinations, are the following:
The following description in relation with the appended drawings, given by way of non-limitative example, will allow a good understanding of what the invention consists of and of how it can be implemented.
In the appended drawings:
By way of exemplary embodiment, it is considered a drone intended to perform marine explorations with measurements performed by measuring devices installed in the keel bulb.
In
Towards the bottom of the hull 2, at the lower part of the underwater hull 10, is installed a keel 3 with a bulb 6. The bulb 6 being at the lower end of the keel 3, it is connected to the hull by a connecting part 5 of the keel 3. The keel 3 with a bulb 6 comprises, preferably in the bulb 6, a ballast that provides the transverse stability to the craft 1. This ballast is a specific heavy material, for example lead or tungsten, and/or corresponds to pieces of equipment, in particular measuring devices, installed in the bulb 6.
The craft 1 also comprises, in this example, a rudder 7.
Thanks to the very narrow shape of the hull 2 also visible in
The craft 1, whose total length is lower than 20 metres and with a minimum length of at least 2.5 metres, has a total width to total length ratio lower than 0.2. Preferably, the drone of the shown example has a length comprised between 2.5 m and 20 m.
The surface craft 1 of the invention, with its fusiform hull, is hence different from the traditional power-driven ships, which have a geometry that provides them with a shape stability aiming at maintaining the horizontal trim of the ship during the displacement of the masses taken onboard and during the movements generated by the sea or the ocean.
The elements of the craft 1 located above the waterline and in particular those located on the deck 4 have a relatively reduced height, or at least a reduced proper weight, so that the centre of gravity of the craft with its keel lowered down is very low and so that it offers a small wind resistance. The craft has no sail, mast or rigging, or any other equipment intended to use the wind force. It has hence a low radar echo due to its shape, size and to the small height of the emerged parts.
Although the craft does not use the wind for its propulsion and hence has no mast or another elevated appendix dedicated to the use of wind for propulsion, the craft can however comprise a wheelhouse 9 or a masting serving in particular to carry the radio and/or optical and/or wind generator and/or sensor pieces of equipment, as well as to place as high as possible the potential air intakes useful for certain operating modes of the drone.
The outer walls of the hull 2 and of the wheelhouse 9, preferably in their non-immersed parts, comprise access doors permitting access to the inside of some compartments of the craft 1.
The materials constituting the craft, in particular its hull 2 and its wheelhouse 9, may be chosen as a function of the needs. For example, metals can be used for the hull 2 and/or the wheelhouse 9 to keep a radar echo, or composite materials, in particular glass fibre, can be used in the opposite case.
The craft 1, which is not a reduced model of an existing ship, is herein a drone intended to perform sonar acoustic measurements, wherein the acoustic measuring systems, in particular the acoustic wave transmitting and receiving transducers, are arranged in the bulb of the keel 3. Moreover, the keel 3, in particular its bulb 6, also comprises an attitude unit that allows accurate corrections of the acoustic measurements due to the fact that this attitude unit is positioned as close as possible to the acoustic transducers.
This craft 1 is autonomous in that it comprises power-driven propulsion means 8 and an internal source of energy. It is hence not a towed device and/or a device connected by a cable to a ship or another equipment, floating or not. In a variant implementation, it can be towed.
Thanks to the shape of the hull 2 of the craft 1, the resistance to forward motion is reduced both in calm water and in rough water, and a reduction of the movements generated on the craft 1 by the agitation of the waves is obtained. The shape of the craft 1 and of its keel 3 allows improving the flow about its acoustic transducers and avoids the formation of bubbles having a masking effect at the acoustic transducers. It results therefrom a diminution of the “noises” that, in the traditional ships, cause interference to the acoustic measurements.
The drone is hence power-driven and at least one electric motor or internal combustion/chemical reaction engine or even mixed engine is used, which can operate a propeller 8 or, in variants, several propellers or one or several turbines.
The keel 3 can be lowered and lifted, preferably more or less highly lifted, so as to be able, in particular, to choose the draught of the craft. In
The wheelhouse 9 or masting hence comprises at least a hollow part that is voluminous enough to contain the part of the keel protruding from the deck or from the superstructures when the keel 3 is in lifted/upper position.
The wheelhouse 9 may have an aerodynamic shape and other functions than the only function of storing at least an upper part of the lifted keel.
In a preferred embodiment, the keel 3 is moreover dismountable and interchangeable. It is also preferred that the bulb 6 of the keel 3 is interchangeable from the keel so that the drone can be used with different configurations of acoustic transducers of various bulbs.
The hull comprises a keel well through which the keel is lowered down to the lower/exit position of the keel.
This keel well may be materialized by a hollow column adjusted to the size and shape of the keel or may correspond to a wider area for the passage of the keel, or even correspond to a wide internal compartment of the craft. In the case where the keel well is not a column adjusted to the keel, as in the example shown in the figures, it is provided that the keel passes through at least two adjusted passages arranged at different heights so as to allow an effective lifting and lowering guiding of the keel and to stabilize it along a stable vertical (or near vertical) axis, once in place and locked at the desired height. In
Guiding means are hence provided between the keel and the keel well and, possibly, the keel-storage space of the wheelhouse. The craft hence comprises keel guiding means that may be a sleeve, rails, bearings, slides . . . .
Preferably, the connection part 5 of the keel 3 that is located between, at the bottom, the bulb 6 and, at the top, the upper end of the keel, has a uniform cross-section over its height and the keel well of the hull and, possibly, the keel-storage space 13 of the wheelhouse, has/have also a uniform cross-section over its/their height and that, in addition, is adjusted to that of the keel connection part 5 to allow the guiding of the keel. This adjustment between the keel, in particular the keel connection part, and the keel well and, potentially, the keel-storage space of the wheelhouse, participates to the stable fastening between both and avoids that the keel “beats” with respect to the hull. As a variant, this guiding may, as in the example shown in the figures, be limited to two guiding passages 14, 15 or more, in which are located adjustments with the keel 3.
The liftable keel is hence mechanically guided in the keel well and, potentially, in the keel-storage space of the wheelhouse, in order to recover all the efforts other than those directed parallel to the keel lifting and lowering movement, so that a link of the “sliding” type is formed between the keel and the ship.
As can be seen in
In upper position of the keel, at least partly lifted within the wheelhouse, the keel may be locked in place using magnetic locking means (not shown for the upper position). Potentially, intermediate-height positions of the keel may also be locked using magnetic locking means (not shown).
The last degree of freedom remaining, in lifting and lowering of the keel, is hence locked by magnetic locking means allowing the keel to be locked at determined heights with respect to the hull. These determined heights are at least the lowered position of the keel and the lifted position of the keel corresponding to the amplitude of maximum vertical displacement of the keel.
The magnetic locking means are consisted of functional pairs, each comprising two magnetically complementary parts able to attract each other and/or repel each other and/or become magnetically inactive as a function of commands. One of the two parts is an electromagnet and the commands are performed using electrical currents.
To simplify the figures, the magnetic locking means have been fully shown only for the locking in lowered position of the keel 3. Hence, in
It is understood that a similar magnetic locking means (not shown) is implemented between the upper end of the connection part 5 of the keel 3 and the wheelhouse 9 in order to be able to lock the keel in lifted/upper position and that, for that purpose, the same part 11b can be used for locking the lowered position and the lifted position.
In variants, by way of security, manually activatable and deactivatable mechanical locking means may be additionally provided, and in particular for the upper/lifted position of the keel, these locking means being for example a pin fastening the walls of the connection part 5 and the wheelhouse 9 to each other.
The keel can also possibly be locked at intermediate heights between the two previous extreme positions, either at predetermined heights, wherein punctual locking means are installed at these predetermined heights, or at any heights. In this latter case, a vertical ferromagnetic plate is arranged along the keel well and an electromagnet arranged in the keel can circulate opposite the plate during the keel lifting and lowering operations, wherein the activation of the electromagnet causes an attraction with the plate that blocks the displacement of the keel at any desired position in height.
The locking with electromagnets may be of the “free under tension” or “closed under tension” mode, according to the embodiments.
In a simplified embodiment, the bulb remains under the hull, potentially protected within a recess of the hull, and does not pass through the keel well. In a more sophisticated embodiment, the bulb may also be lifted through the well, wherein the well is either configured to leave the passage to the bulb, or able to come in alignment with the keel connection part, for example by tilting, and to enter the projected volume of this connection part, the keel well having a shape adjusted to the volume of the keel connection part.
The lifting and the lowering of the keel through the hull and the keel well, and toward and from the keel-storage space of the wheelhouse, implements a motorization with a mechanical means (not shown) for the forced lifting: winch, hydraulic jack, rack, endless screw . . . and, possibly also for the forced lowering, and in this latter case, the height-position locking of the keel may be ensured by the mechanical means.
Preferably, by way of security, a descent stop is provided, preventing the keel from going down beyond the determined limit. This descent stop may be a wider part of the upper end of the keel, which comes into abutment against a stop placed at the lower end of the keel well or, as in the figures, arranged in relation with the passage 15 through the tween deck 12. This keel stop may be an element added at the upper end of the keel. The stop can also serve as an upper fitting bearing in lower position of the keel. The stop can support either the electromagnet(s), or magnetic parts on which the electromagnets can magnetically act by magnetic attraction or repulsion according to the embodiments. The mechanical guiding and the stops and abutments are designed in such a manner that the only forces to which the electromagnets are subjected are directed in the axis of lifting/lowering displacement of the keel.
Number | Date | Country | Kind |
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1761547 | Dec 2017 | FR | national |
Filing Document | Filing Date | Country | Kind |
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PCT/FR2018/053056 | 11/30/2018 | WO | 00 |