The present invention relates to a system for docking an aerostat on a mobile or fixed receiving structure. It also relates to a docking method implemented in this system, as well as an aerostat equipped with this system and a suitable receiving structure.
The field of the invention is more particularly, but non-limitatively, that of dirigible balloons.
Docking large dirigible aerostats on mooring masts has always been a tricky manoeuvre that required the involvement of a large number of persons on the ground, sometimes over one hundred, which proved time-consuming and presented risks both for the crews of these aerostats and for the persons on the ground.
Furthermore, piloting these dirigibles on the approach to receiving structures on the ground is generally complex due to aerodynamic conditions that are sometimes unfavourable on the approach to the ground and to the high intrinsic inertia of these aircraft.
The aim of the present invention is to overcome these drawbacks by proposing a docking system that can facilitate the approach of an aerostat to a receiving structure and allow it to dock more easily and more safely than under the current conditions.
This objective is achieved with a system for docking an aerostat on a receiving structure, characterized in that it comprises at least one unmanned aerial vehicle that is controllable in order to move between the aerostat and the receiving structure while carrying a first end of a mooring cable, the second end of which is fastened to the aerostat or to the receiving structure and in order to fasten this first end to the receiving structure or to the aerostat, so that this cable connects the aerostat to the receiving structure.
Thus, by creating a mechanical connection by cable between the aerostat and the receiving structure by means of an unmanned aerial vehicle, it becomes much easier to bring the nose of the aerostat closer to the receiving structure, even under disturbed weather conditions.
The docking system according to the invention can also advantageously comprise means for winding the cable connecting the aerostat to the receiving structure, so as to bring the aerostat closer to the receiving structure.
In a particular version of a docking system according to the invention, the winding means comprise a winding device housed within the aerostat.
In another version, the winding means comprise a winding device housed on the receiving structure.
The winding device can advantageously comprise a motorized winch having a substantially vertical axis of rotation, placed at the top of the receiving structure. This motorized winch comprises for example a drum provided with a slot intended to receive the end of the mooring cable.
The docking system according to the invention is preferably arranged in order to release the unmanned aerial vehicle after the first end of the cable has been fastened to the receiving structure or to the aerostat.
In a particular embodiment of a docking system according to the invention, the unmanned aerial vehicle is arranged so that it can be housed within the aerostat, this unmanned aerial vehicle being arranged for being controlled in order to (i) carry to the receiving structure a first end of the mooring cable, the second end of which is fastened to the aerostat and (ii) fasten the first end to the receiving structure.
In another embodiment of a docking system according to the invention, the unmanned aerial vehicle is arranged in order to start from the receiving structure, this unmanned aerial vehicle being arranged for being controlled in order to (i) carry to the aerostat a first end of the mooring cable, the second end of which is fastened to the receiving structure and (ii) fasten the first end to the aerostat.
In a particular version of the invention, the mooring cable comprises a plurality of consecutive sections with successively increasing diameters, a first of these sections having the smallest diameter and being terminated by the first end intended to be carried by the unmanned aerial vehicle.
In another version of the invention, the winding device housed in the receiving structure is coupled to a mechanical connection system comprising a first mechanical connector placed at the nose of the aerostat and a second mechanical connector placed at the top of the receiving structure, these first and second mechanical connectors being intended to be coupled mechanically at the end of a winding sequence of the mooring cable.
According to another aspect of the invention, a method is proposed for docking an aerostat on a receiving structure, implemented in a docking system according to the invention, comprising the steps of:
The docking method according to the invention can also comprise a step of winding the mooring cable after fastening the first end thereof to the receiving structure or to the aerostat, until a part of the aerostat substantially reaches a part of the receiving structure.
When the method according to the invention is implemented in a docking system according to the invention combined with a mechanical coupling system, the step of winding the mooring cable is carried out until achieving a coupling of the first and second mechanical connectors respectively equipping the aerostat and the receiving structure.
The docking method according to the invention can advantageously comprise a step for releasing the unmanned aerial vehicle while maintaining the fastening of the first end of the cable to the receiving structure.
The successive steps of the docking method according e invention can be at east partially controlled from the aerostat and/or from the ground.
The unmanned aerial vehicle can be programmed so that in autonomous mode it reaches the receiving structure from the aerostat or the aerostat from the receiving structure.
According to yet another aspect of the invention, an aerostat is proposed equipped with a docking system according to the invention, as well as a receiving structure suitable for receiving this docking system.
Other advantages and features of the invention will become apparent on reading the detailed description of implementations and embodiments that are in no way limitative, and from the following attached drawings:
As these embodiments are in no way limitative, variants of the invention can be considered in particular comprising only a selection of the characteristics described or shown hereinafter in isolation from the other characteristics described or shown (even if this selection is isolated within a phrase comprising these other characteristics), if this selection of characteristics is sufficient to confer a technical advantage or to differentiate the invention with respect to the state of the prior art. This selection comprises at least one, preferably functional, characteristic without structural details, and/or with only a part of the structural details if this part alone is sufficient to confer a technical advantage or to differentiate the invention with respect to the state of the prior art.
Firstly, with reference to
The docking system 1 comprises an unmanned aerial vehicle 10 controlled in order to carry a mooring cable 11 unwinding from a drum 21 placed at the front of an aerostat 2 equipped with propulsion units 22, 23, towards a receiving structure 3.
This receiving structure 3 comprises a base 35, optionally self-propelled, resting on the ground or on a track 4, and a mast 32, at the top of which a winch is placed, comprising a cable drum 31, the vertical shaft of which is driven by a motor 34. The drum 31 is provided with a slot 33 arranged in order to receive the end 13 of the mooring cable.
The unmanned aerial vehicle 10 is for example of the four-engine type with four propellers 101, 102, 103, 104 and comprises a central device 100 for locking/unlocking a mooring cable.
When the aerostat 2 is on the approach to the receiving structure 3, the pilot triggers a docking procedure with the unmanned aerial vehicle 10 taking off from the aerostat, carrying the end 13 of the mooring cable 11 locked in the central device 100 of the unmanned vehicle 10. The cable drum 21 is controlled in free-wheel mode so as to allow the cable to unwind freely and allow the unmanned vehicle 10 to pull this cable, limiting the traction forces. The unmanned vehicle 10 follows an optimized path in the direction of the drum 31 at the top of the receiving structure 3 and is controlled so as to insert the end 13 into the receiving slot 33 of the drum 31. When this insertion has been carried out, the unmanned vehicle 10 then releases the mooring cable 11.
The drum 31 is then driven by the motor 34 in order to wind the cable 11, the second end of which is henceforth maintained fixed with respect to the aerostat 2, either by immobilization of the drum 21 housed in the aerostat 2, or because the cable 2 is fully unwound from this drum 21. As shown in
The cable drum 31 situated on the receiving structure 3 is driven until the nose of the aerostat 2 is located in immediate proximity to the receiving zone 3. With reference to
The docking system according to the invention can also be combined with a mechanical coupling system of the aerostat to the receiving structure, as shown in
When the unmanned vehicle 10, as described with reference to
Now, with reference to
The docking system 110 is intended to carry out docking of an aerostat 200 to a receiving structure 300 such as a mooring mast, with reference to
The docking system 110 comprises an unmanned aerial vehicle 10, for example of the quadcopter type, carrying a free end forming a loop 120 in the mooring cable 11, the other end of which is wound on a winch drum 210 on board the aerostat 200 and driven by a motor 222. The unmanned vehicle 10 is intended to be housed within the aerostat 200 in a housing 220 which can be closed by a hatch device or equivalent (not shown).
When the aerostat 200 is on the approach to the receiving structure 300 under the control of vector thrusters 122, 123, only two of which are shown in
The unmanned aerial vehicle 10 shown in
When the unmanned vehicle 10 has reached the target thereof, it is then controlled in order to insert the loop performing the function of end 120 into the hitch device 310. When the insertion operation has been carried out, the unmanned aerial vehicle 10 is then commanded in order to unlock the device 100 and thus release the mooring cable 11. The unmanned aerial vehicle 10 can then leave the docking zone, as shown in
With reference to
With reference to
When the unmanned aerial vehicle 16 has reached the nose of the aerostat 2″ which is provided with a hitch device 25 shown diagrammatically in
After the mooring cable 111 has been fastened to the hitch device 25 of the aerostat 2″, the motorized winch 61 is then controlled in order to wind the cable 111 and thus to move the aerostat 2″ closer to the receiving structure 6 which is maintained immobilized with respect to the ground 4 or optionally can move under control in order to facilitate the coupling of the aerostat 2″ to the receiving structure. Control of winding of the cable 111 is stopped when the nose of the aerostat 2″ enters substantially into contact with the incurved receiving device 60, as shown in
It is well understood that all or part of the docking systems described above with reference to the aforementioned figures can be combined together.
Of course, the various features, forms, variants and embodiments of the invention can be combined together in various combinations to the extent that they are not incompatible or mutually exclusive. In particular, all the variants and embodiments described above can be combined together.
Number | Date | Country | Kind |
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1661810 | Dec 2016 | FR | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2017/080555 | 11/27/2017 | WO | 00 |