EP4405249A1 - Improved system and method for docking an airship, and airship and receiving structures including same - Google Patents

Abstract

A system (1) for docking an airship (2) on a receiving structure (3) comprising at least one unmanned aerial vehicle (4) that can be controlled so as to move between the airship (2) and the receiving structure (3), carrying a first end (51) of a docking cable (5) that has a second end attached to the receiving structure (3), and to attach the first end (51) to the airship (2), such that said cable (5) mechanically connects the airship (2) to the receiving structure (3), wherein the unmanned aerial vehicle (4) is mechanically attached to the docking cable and is supplied with power through the docking cable via the first end (51) of the docking cable (5).

Description

SYSTEM AND METHOD FOR IMPROVED STOWAGE OF AN AIRSHIP AND

AIRSHIP AND RECEIVING STRUCTURES SO EQUIPPED

Technical area

The present invention relates to a system for securing an airship to a mobile or fixed receiving structure. It also relates to a stowage method implemented in this system, as well as an airship equipped with this system and a suitable receiving structure.

The field of the invention is more particularly, but not limited to, that of dirigible balloons.

State of the prior art

Securing large airships to parking masts has always been a delicate maneuver which required the intervention of a large number of people on the ground, sometimes more than a hundred, and which proved to be long and presenting risks both for the crews of these airships and for those on the ground. This maneuver also represented significant operational costs.

Furthermore, the piloting of these airships when approaching receiving structures on the ground is generally complex due to the sometimes unfavorable aerodynamic conditions when approaching the ground and the high intrinsic inertia of these aircraft.

The applicant has filed application W02018/099870 A1 which describes a stowage system which facilitates the approach of an airship to a receiving structure and allows its stowage more easily and more securely than under previous conditions.

To this end, a system has been proposed for attaching an airship to a receiving structure, comprising a controllable aerial drone for moving between this airship and this receiving structure by carrying a first end of a cable whose second end is fixed to the airship or to the receiving structure and to attach this first end to the receiving structure or to the airship, so that this cable connects the airship to the receiving structure.

When the aerial drone moves from the receiving structure to the airship, the drone has to exert a lot of work to take the first end of the cable and move it against the force of gravity. The Applicant has continued its research with the aim of proposing a system which always aims to facilitate the approach of an airship towards a receiving structure and allows its stowage more easily and more surely than under current conditions, while simplifying the solution previously proposed.

Disclosure of Invention

An object of the invention is in particular to remedy all or part of the aforementioned drawbacks.

According to a first aspect of the invention, there is proposed a system for securing an airship to a receiving structure, comprising at least one controllable aerial drone to move between the receiving structure and the airship, carrying a first end of a cable stowage whose second end is fixed to I receiving structure, and to fix the first end to said airship, so that this cable mechanically connects the airship to the receiving structure.

According to the invention, the aerial drone is mechanically fixed to the lashing cable and is supplied with electrical energy by the lashing cable, on the side of its first end of the lashing cable.

The power supply of the drone by the cable makes it possible to avoid increasing the weight of the aerial drone. It is no longer necessary for the aerial drone to carry batteries of substantial size and weight.

The system may further comprise means for winding up the cable connecting the airship to the receiving structure, so as to bring the airship closer to the receiving structure. Preferably, the winding means comprise a winding device housed at the level of the receiving structure.

Advantageously, the aerial drone can be arranged to start from the receiving structure, the aerial drone being controllable to take the first end of the securing cable to the airship, the second end of which is fixed to the receiving structure and fix the first end to the airship .

According to a second aspect of the invention, there is proposed a method for securing an airship to a receiving structure, implemented in a securing system according to the first aspect of the invention, or one or more of its improvements , comprising the steps of: To. control of at least one aerial drone carrying a first end of a securing cable, the second end of which is fixed to the receiving structure, along a trajectory leading it towards the airship, and b. attaching the first end of the lashing cable to a part of the airship.

The aerial drone is mechanically fixed on the tie-down cable and is powered by the tie-down cable, on the side of the first end of the tie-down cable.

Preferably, the method further comprises a step of winding the securing cable after fixing its first end to the airship, until a part of the airship substantially joins a part of the receiving structure.

Advantageously, the successive steps are at least controlled from the ground.

Advantageously, the successive steps are at least controlled from the airship.

Preferably, the aerial drone is programmed to join the airship in autonomous mode from the receiving structure.

According to a third aspect of the invention, there is proposed an airship equipped with a stowage system according to the first aspect of the invention, or one or more of its improvements.

According to another aspect of the invention, a structure is proposed for receiving a securing system according to the first aspect of the invention, or one or more of its improvements.

Description of figures

Other advantages and particularities of the invention will appear on reading the detailed description of implementations and in no way limiting embodiments, with regard to the appended drawings in which:

[Fig. 1] schematically illustrates a first example of implementation of a securing system according to the invention,

[Fig. 2] schematically illustrates an embodiment of a possible mechanical interface and energy supply between the cable and the drone.

[Fig. 3] schematically illustrates a first embodiment of a possible mechanical interface between the drone and the airship. [Fig. 4] schematically illustrates a second embodiment of a possible mechanical interface between the drone and the airship.

Description of embodiment

The embodiments described below being in no way limiting, variants of the invention may in particular be considered comprising only a selection of characteristics described, subsequently isolated from the other characteristics described, if this selection of characteristics is sufficient. to confer a technical advantage or to differentiate the invention from the state of the prior art. This selection includes at least one feature, preferably functional without structural details, or with only part of the structural details if only this part is sufficient to confer a technical advantage or to differentiate the invention from the state of the prior art .

In the figures, an element appearing in several figures retains the same reference.

A description will be given, with reference to FIG. 1, of a first embodiment of a securing system 1 according to the invention, at the same time as the method implemented in this system.

The securing system 1 comprises an aerial drone 4 controlled to carry a securing cable 5 unwinding from a drum 31 of a receiving structure s, towards the front of an airship 2 equipped with propulsion units 21, 22 and of a hooking device 23. The device 23 can for example receive a looped end of the securing cable 5.

This receiving structure 3 comprises a base 32, possibly self-propelled, resting on a ground or a track S, and a pylon 33 at the top of which is arranged the winding drum 31 .

In the example shown, the receiving structure also comprises a curved part 34 designed to receive the nose of the airship 2.

Drum 31 may have a horizontal axis driven by a motor (not shown). The drum 31 may be provided with a slot arranged to receive one end of the securing cable 5.

The aerial drone 4 is for example of the four-engine type with four propellers. The drone is supplied with energy by means of a power supply cable 41 coupled mechanically to the securing cable 5, as shown in FIG. 2. The drone 4 has a power supply interface 42 able to be powered by the power supply cable 41. The power supply interface 42 in energy can also be a mechanical locking interface of the securing cable 5 on the drone 4.

When the airship 2 is approaching the receiving structure 3, the pilot or an operator on the ground triggers a docking procedure with the takeoff of the aerial drone 4 from the receiving structure 3 by carrying the end 51 of the cable lashing 5 locked and supplying the drone 4. The winding drum 31 is controlled in freewheel mode in order to release the unwinding lashing and supply cables and allow the drone 4 to pull the lashing cable by limiting tensile stresses. Drone 4 follows an optimized trajectory towards airship 2.

The first end 51 can be fixed to the airship, for example by means of a loop of the cable 5 on the attachment device 23.

The drum 31 is then driven by the motor to wind the cable 5, the second end of which is now held fixed relative to the airship 2.

The winding drum 31 located on the receiving structure 3 is driven until the nose of the airship 2 is in the immediate vicinity of the receiving area 3.

The winding control of the cable 5 can be stopped when the nose of the airship 2 substantially comes into contact with the curved receiving device 34.

We will now describe with reference to Figure 3 another embodiment of a securing system according to the invention, together with the securing method implemented in this system.

Unlike the system 1 which has just been described, the end 51 of the cable 5 is not directly fixed to the airship 2. It is the drone 4 which is fixed to the airship 2 by means of an interface mechanical. The drone 4 can for example have a loop 43 able to be fixed on the attachment device 23.

The body of the drone 4 can for example be captured by a capture device 24, as shown in Figure 4.

Of course, the invention is not limited to the examples which have just been described and many adjustments can be made to these examples without departing from the scope of the invention. In addition, the different characteristics, shapes, variants and embodiments of the invention may be associated with each other in various combinations insofar as they are not incompatible or exclusive of each other.

Claims

Claims

1. System (1) for securing an airship (2) to a receiving structure (3), comprising at least one aerial drone (4) controllable to move between said airship (2) and said receiving structure (3), carrying a first end (51) of a lashing cable (5) the second end of which is fixed to said receiving structure (3), and for fixing said first end (51) to said dirigible (2), so that this cable (5) mechanically connects said dirigible (2) to said receiving structure (3), characterized in that said aerial drone (4) is mechanically fixed to the lashing cable and is supplied with energy by the lashing cable, on the side of the first end (51) of the securing cable (5).

2. Securement system (1) according to claim 1, further comprising means (31) for winding said cable (5) connecting the airship (2) to the receiving structure (3), so as to bring said airship ( 2) of said receiving structure (3).

3. Securement system (1) according to the preceding claim, wherein the winding means comprise a winding device (61) housed at the receiving structure (3).

4. Docking system (1) according to any one of the preceding claims, wherein the aerial drone (4) is arranged to start from the receiving structure (3), said aerial drone (4) being controllable for (i) take to the airship (2) the first end (51) of the securing cable (5) whose second end is fixed to said receiving structure (3) and (ii) fix said first end to said airship (2).

5. A method for securing an airship (2) to a receiving structure (3), implemented in a securing system (1) according to any one of the preceding claims, comprising the steps of: a. control of at least one aerial drone (4) carrying a first end (51) of a securing cable (5), the second end of which is fixed to said receiving structure (3), along a trajectory leading it towards said airship (2), and b. fixing said first end (51) of said lashing cable (5) to a part of said dirigible (2) said aerial drone (4) is mechanically fixed on the lashing cable and is powered by the lashing cable (5 ), on the side of the first end (51) of the securing cable (5).

6. Securing method according to the preceding claim, further comprising a step of winding the securing cable (5) after fixing its first end (51) to the airship (2), until a part said airship (2) substantially joins a part of said receiving structure (3).

7. Securing method according to one of the two preceding claims, in which the successive steps are at least controlled from the ground.

8. Stowage method according to one of the three preceding claims, in which the successive steps are at least controlled from the airship.

9. Docking method according to any one of the four preceding claims, in which the aerial drone (4) is programmed to join the airship (2) in autonomous mode from the receiving structure (3).

10. Airship (2) equipped with a securing system (1) according to any one of claims 1 to 4.

11. Structure (3) for receiving a securing system according to any one of claims 1 to 4.