FR2963924A1 - DEVICE FOR RECOVERING A MARINE OR SUBMARINE DEVICE - Google Patents

Abstract

Device for the recovery of a marine or underwater vehicle, this device comprising: a flexible link (20) having a first end (21) intended to be connected to the machine (80), a coil (30) to which is connected a second end (22) of the flexible link (20), the flexible link being adapted to be wound around the coil, and a ballast load (50) adapted to be associated with the coil (30). The coil (30) and the ballast load (50) are such that the coil associated with the load flows, while the coil released from the load floats; and the flexible link (20) and the coil (30) cooperate such that the coil is released from the load (50) by unwinding the flexible link (20) wound around the coil (30). Marine or underwater craft equipped with such a device.

Description

FIELD OF THE INVENTION The present disclosure relates to a device for the recovery of a marine or submarine device, and a marine or underwater device equipped with such a device.

In particular, said craft may be an autonomous underwater vehicle or AUV (for "Autonomous Underwater Vehicle"). STATE OF THE PRIOR ART Installations are already known for recovering AUVs in water from a boat. These facilities typically include a traction system for pulling the AUV via a cable connecting the traction system and the AUV. Examples of installations of this type are described in published PCT patent applications No. WO 2008012472 and No. WO 2008012473. In this type of installation, the cable is initially embedded on the AUV. The first steps in recovering the AUV are to drop the cable and wait for it to deploy in the water. Once the cable is deployed, it can be caught from the boat, for example using a harpoon or grapple, and the free end of the cable (ie the end not tied to the AUV) can to be boarded again. The cable can then be attached to the traction system. However, these first steps and, in particular, the deployment of the cable in the water, can pose a problem. Indeed, it happens that the cable does not deploy properly and, in particular, it remains in the vicinity of the AUV. In this case, it may be necessary to approach the boat very close to the AUV to be able to catch the cable, which increases the risk of collisions between the boat and the AUV and, therefore, the risk of damaging the boat. AUV. It also happens that the cable wraps around some parts (fins, propeller, etc.) of the AUV, which increases, again, the risk of damaging the AUV. There is therefore a need for a safe and simple solution that allows to correctly deploy the cable linked to the AUV. PRESENTATION OF THE INVENTION The present disclosure relates to a device for the recovery of a marine or submarine machine, this device comprising: a flexible link having a first end intended to be linked to said machine; a spool to which is bonded a second end of the flexible link, the flexible link being adapted to be wrapped around the spool; and a ballast load adapted to be associated with the coil. In this device, the coil and the ballast load are such that the coil associated with said load flows, while the coil released from said load floats, and the flexible link and the coil cooperate so that the coil is released from said charge by the unwinding of the flexible link wrapped around the coil. The modes of use and the advantages of such a device are as follows. The coil, surrounded by the flexible link and weighted by the weighting load, is previously embarked on the marine or underwater vehicle. The type of gear concerned is not limited. It may be a floating or controlled immersion craft, including an AUV, a torpedo, a surface drone or other similar architectural craft. When it is desired to retrieve the craft from a recovery base (e.g. a boat, a wharf, an off-shore platform, etc.), the spool is first released from the craft. The coil then flows due to the ballast load. By flowing, the coil carries with it the flexible link that unfolds as the coil descends to the bottom of the water. The course of the flexible link then causes the release of the load and, thus, the shedding of the coil. Advantageously, the release of the load takes place at the end of the course of the flexible link, i.e. this release is caused by the unfolding of the last turns of the flexible link. Once released from its weighting charge, the coil becomes floating (i.e. its density becomes lower than that of water) so that it no longer flows but, on the contrary, rises to the surface. During the ascent of the spool, the machine and the spool do not drift in the same way because they are not subject to the same wind and current conditions. As a result, the coil moves horizontally away from the machine as it ascends and surfaces at a significant distance from the machine. Due to the descent of the spool and the relative spacing of the spool, the flexible link is correctly deployed and removed from the machine, which facilitates its subsequent recovery. In addition, the risks of winding the flexible link around the machine are limited. In the end, compared to the prior art, the recovery of the link, and therefore of the machine, is easier and the risk of damage to the machine is reduced. By flexible link is meant any type of link sufficiently flexible to be wound around the coil. This flexible link must, in addition, be strong enough to withstand the tensile forces exerted on it. The flexible link is, for example, a cable or a rope. Advantageously, the flexible link is non-floating but light enough so that the behavior of the flexible link in the water is mainly controlled by s the movement of the coil and the possible first ballast element described below. According to one embodiment, the flexible link carries a first stop between the first and the second end, and the device further comprises at least one first weight element configured to slide along the flexible link between the first end and the second end. the first stop. When the spool sinks, dragging with it the link, the first weight element slides along the link until it comes up against the first stop. Thus, the first weighting element exerts on the first link portion located between the first end and the first stop a pulling force 15 directed downwards, which tends to maintain this first substantially vertical link portion. The first ballast element and the abutment form, moreover, a hinge area around which the second link portion, located between the first abutment and the second end of the link, pivots when the coil rises to the surface. The fact that this articulation zone exists and is located at a certain distance below the machine, makes it possible to further limit the risks of winding the link around the machine. In particular, these risks remain limited even if the craft navigates after the deployment of the link. According to one embodiment, the coil has a winding surface around which the flexible link can be wound, and the coil 25 has a housing for receiving the ballast load, this housing having a first opening through which the ballast load can pass, this first outlet opening being located on the winding surface. According to one embodiment, the first opening is plugged by a first cover whose outer face defines a part of the winding surface. According to one embodiment, the second end of the flexible link is connected to an attachment point located inside the housing, the flexible link passes through the first cover, and the flexible link carries a second stop between its second end and lid. This second stop causes the cover to open the first opening during the course of the flexible link. Unclogging the first opening then allows the ballast load out of the housing and, thus, to unload the coil which will then go back to the surface. According to one embodiment, the housing has a second opening through which the ballast load can pass, this second opening being located outside the winding surface and plugged by a second cover. The ballast load can be introduced inside the housing through this second opening. Since the cover is located outside the winding surface, the positioning and removal of the lid can be done independently of the winding of the flexible link around the coil. This allows, for example, to introduce the ballast load in the coil while the flexible link is already wrapped around it. According to one embodiment, the spool carries at least one second ballast element, this weighting element being disposed on the spool so as to orient the first opening downwards when the spool is under water. This makes it easier and easier to empty the housing of the ballast load. The present disclosure also relates to a marine or underwater vehicle equipped with a device as described above, the first end of the flexible link 20 being connected to said machine. According to one embodiment, said machine is configured to be able to embark the coil surrounded by the flexible link, the machine comprising a release system to release the coil. According to one embodiment, the delivery system is remotely controllable. It can thus be remotely controlled from the machine recovery base, this recovery base can be a boat, a dock, an off-shore platform, etc. Several modes or examples of embodiments are described in this presentation. However, it is specified that, except in the case of major incompatibility, the characteristics described in connection with one embodiment or embodiment can be applied to another embodiment or embodiment. BRIEF DESCRIPTION OF THE DRAWINGS The accompanying drawings are diagrammatic and are not necessarily to scale, they are primarily intended to illustrate the principles of the invention. In these drawings, from one figure (FIG) to another, identical elements (or parts of element) are identified by the same reference signs. In addition, elements (or parts of elements) belonging to different exemplary embodiments but having an analogous function are identified by reference numerals spaced 100, 200, etc. FIG 1 shows, in perspective, an exemplary device according to the present invention, comprising a coil and a flexible link wound around this coil. FIG 2 is a sectional view of the device of FIG 1, along the section plane II-II. FIG. 3 is a sectional view, similar to that of FIG. 2, showing the reel before the ballast load is introduced therein. FIG 4 is a perspective view, showing the coil of FIG 1 during the release of the ballast load. FIG. 5 is a sectional view of another example of a device according to the present disclosure, comprising a spool and a flexible link wrapped around this spool. FIG 6 is a sectional view of the device of FIG 5, along the section plane VI-VI, after unfolding the flexible link. FIGS. 7 to 10 represent an example of a machine according to the present disclosure. These figures illustrate the successive stages of the deployment of the flexible link equipping this machine. FIG 11 is a detailed view of the front part of the machine marked by the circle XI in FIG 7. DETAILED DESCRIPTION OF EXEMPLARY EMBODIMENTS 25 Embodiments of the proposed device are described in detail below, in reference to the accompanying drawings. These examples illustrate the features and advantages of the invention. However, it is recalled that the invention is not limited to these examples. FIG. 1 shows an exemplary device 10 for the recovery of a marine or underwater vehicle 80. This machine 80 is shown in FIGS. 7 to 10. The device 10 comprises a flexible link 20 and a coil 30. The flexible link 20 has two ends 21, 22. The first end 21 is connected to the machine 80, and the second end 22 is connected to the coil 30. In the example, the flexible link 20 is a rope.

The coil 30 comprises a central core 31 defining a winding surface 33 for the link 20. This winding surface 33 is bordered by two flanges 34, 35 which hold the link 20 between them. In this example, the central core 31 and one of the flanges 34 form a one-piece assembly. The other flange 35 is fixed on the central core, for example by screwing (screw 36). It will be noted that such a configuration has been retained to allow adjusting the buoyancy of the coil, the flange 35 made of floating material (s) is machined for example with variable dimensions to vary the buoyancy of Archimedean . The central core 31 has a general shape of hollow cylinder of axis A, and has at its axial ends two openings respectively closed by two covers 37, 38. The cover 37 is mounted, for example by screwing, on the flange 34 and is not meant to be dismantled. The cover 38 located on the side of the flange 35 blocks the opening 42 and is removable. The central core 31 and the covers 37, 38 define between them a housing 40. This housing 40 makes it possible to receive a ballast load 50. This weighting load 50 is formed by a set of elementary fillers of limited size, such as for example, metal balls, grains of sand, etc. In particular, the size of these elementary charges is much smaller than that of the openings 41, 42 of the housing 40. This weighting load 50 is introduced inside the housing 40 via the opening 42, called the inlet opening, as symbolized by the arrow F1 of FIG. 3. This is possible because the cover 38 is removable. Moreover, since the inlet opening 42 and its cover 38 are located outside the winding surface 33 of the link 20, it is possible to put / remove the cover 38 even when the cable 20 is wound around the coil 30. The weighting load 50 can thus be introduced into the housing 40, through the inlet opening 42, after the winding of the cable 20. The housing 40 has, in addition, another opening 41, so-called Outlet opening, through which the weighting charge 50 can exit the housing 40. This outlet opening 41 (see FIG. 4) is located on the winding surface 33 and, in this example, it is plugged by another cover 39 whose outer face 39A defines a portion of the winding surface 33. The flexible link 20 and the coil 30 cooperate so that the coil 30 is released from the load 50 by the unwinding of the flexible link 20 wound around the coil 30. More particularly, in this example, the unwinding of the flexible link 20 will cause the displacement of the cover 39 and, thus, the unblocking of the outlet opening 41. More specifically, the second end 22 of the link 20 is linked to an attachment point 44 located inside. In addition, the flexible link 20 passes through the cover 39 and carries a stop 45 between its second end 22 and the cover 39. The stop 45 is, for example, a node obtained by interlacing the link 20. The length of the Link 20 between its end 22 and the stop 45 is greater than the distance between the attachment point 44 and the lid 39 in its closed position. Thus, when the last turn of the link 20 takes place and the link 20 is stretched, the second stop 45 causes the cover 39, which opens the outlet opening 41. The weighting load 50 can then exit through this opening 41 As symbolized by the arrow F2 of FIG. 4, since the weighting load 50 exits the housing 40 by gravity via the opening 41, it is preferable that this opening 41 be oriented as far as possible downwards. For this purpose, several solutions, used alone or in combination, are proposed. One solution consists in providing an exit opening 41 which is very circumferentially extended (for example, over more than 180 °). Another solution is not to position the attachment point 44 of the flexible link 20 in a position diametrically opposed to the outlet opening 42 but, instead, to position the attachment point 44 near the opening 41 and, in particular, on the same side of the axis A as the opening 41. Another solution is to mount on the spool 30 one or more weighting elements 51, these weighting elements 51 being disposed on the spool 30 in such a way as to orient the opening 41 downwards when the coil is under water. In the example of FIGS. 1 to 4, five stud-shaped weighting elements 51 are fixed on the flange 34 of the coil 30 on the same side of the axis A as the outlet opening 41. Another example of Device 110 is shown in FIGS. 5 and 6. Like the device 10, the device 110 comprises a flexible link 120 and a coil 130. The flexible link 120 has two ends. The first end is connected to an underwater or marine craft, and the second end 122 is connected to the spool 130, at a point of attachment 144. The spool 130 comprises a central core 131 defining a surface 35 winding 133 for the link 120. This winding surface 133 is bordered by two flanges 134, 135 which maintain the link 120 between them. In this example, the central core 131 and the two flanges 134, 135 form a one-piece assembly. In this example, the central core 131 is not hollow. It could be, however, especially for buoyancy reasons.

The spool 130 has a housing 140 for receiving a ballast load 150. This weighting load 150 is a single piece such as, for example, a metal bar. The housing 140 has the shape of a groove formed in the winding surface 133 and, in the example, oriented along the axis of the coil. The weighting load 150 is introduced into the housing 140 through the upper opening 141 of the groove. The "opening superior" is the opening located opposite the bottom of the groove. This upper opening 141 is located on the winding surface 133. The weighting load 150 is introduced into the housing 140 prior to the winding of the link 120 around the spool 130. The flexible link 120 and the spool 130 cooperate with each other. such that the coil 130 is released from the load 150 by the unwinding of the link 120. More particularly, in this example, it is the turns of the link 120 which maintain the weighting load 150 in the housing 140 and, consequently, the unwinding of the last turns releases the ballast load 150 which can then escape from the housing 140, as symbolized by the arrow F3 in FIG. 6. As the weighting load 150 leaves the housing 140 by gravity, via the opening 141, it is preferable that this opening 141 is oriented as far as possible downwards. For this purpose, several solutions, used alone or in combination, are proposed. One solution is to position the attachment point 144 of the flexible link 120 in a position diametrically opposed to the opening 141, as shown in FIG 6. Another solution is to mount on the coil 130 one or more ballast elements, these ballasting elements being disposed on the spool 130 so as to orient the opening 141 downwards when the spool is under water. FIGS. 7 to 10 represent an example of machine 80 according to the present disclosure. These figures illustrate the successive stages of deployment of the flexible link 20 equipping this machine 80. 35 In the example, the machine 80 is an autonomous underwater vehicle or AUV. It is equipped with a device 10 of the type of that of FIGS 1 to 4. Of course, it could be equipped with another type of device and, in particular, with the device 110 of FIGS 5 and 6. The machine 80 is configured to be able to embark the coil 30 surrounded by the flexible link 20. For example, the machine 80 has in its front part, or "nose" 80A, a housing 82 to receive the coil 30, the link 20 and a ballast element 70 which is also part of the device 10. The first end 21 of the link 20 is connected to the nose 80A of the machine 80, at a point of attachment located in or near the housing 82. The weighting element 70 It is slidably mounted on the link 20. The machine 80 further comprises a delivery system for dropping the coil 30. This delivery system can have different structures and different modes of operation which depend, in particular, in the manner whose coil 30 is initially connected to the machine 80 and In the example, the housing 82 is closed by a hatch 85 (see FIG. 11) which can be opened by means of pushing means such as springs or cylinders. In another example, the release system comprises an electromagnet which, when it is active, blocks the coil 30 inside its housing and which, when it is deactivated, releases the coil 30. Advantageously, the release system release is remotely controllable. At the end of the mission, the machine 80 returns to the surface and is stopped (i.e. its propulsion means are stopped) or in motion. To recover the AUV, one begins by jettisoning the coil 30 using the remotely controlled remote release system, for example from a boat (not shown). The coil 30 then dives under the effect of gravity and the link 20 takes place in the water column located under the nose 80A of the machine 80, as symbolized by the arrow F4 in FIG. time, the ballast element 70 slides along the link 20 to abut against a stop 71 symbolized by the arrow F5 in FIG 8. This stop 71 is located at a significant distance from the first end 21 of the link. For example, this abutment is a node obtained by interleaving the link 20. After unfolding the last turn of the cable 20, the cover 39 of the coil 30 opens and the weighting load 50 is released, as shown in FIG. 8. The spool 30 then becomes floating and rises to the surface by driving with it the link 20 as shown in FIG. 9. At the surface, the spool 30 behaves like a drifting buoy. The spool 30 can then be caught and brought aboard the boat using different methods.

For example, one method is to use a floating harpoon that is towed by the boat through a cable. At the same time, the machine 80 moves so that the trajectory of the link 20 intersects that of said cable. After intersection, the spool 30 is brought aboard the boat using the cable s and harpoon. Another method is to get closer to the machine 80 with the boat, the machine 80 remaining stopped. When the boat is at a suitable distance, a spear is thrown from the deck of the boat to catch the spool 30.

With regard to the behavior of the assembly formed by the machine 80, the coil 30 and the link 20 in the water, after the release of the coil, it will be noted that, in a first step, the device operates in a column of 'water. Then, once the ballast load 50 dropped, the coil goes back to the surface. The coil 30 then drifts under the action of deep sea currents, while the apparatus 80 drifts under the action of the wind and the surface marine current. As a result, the coil 30 comes to the surface at a significant distance from the machine 80, which is consistent with the purpose. When the coil 30 rises to the surface, the flexible non-floating link naturally tends to assume the shape of a chain. The curvature of this chain is deformed by the ballast element 70. This ballast element creates a point of inflection between a first portion 20A of the link 20, extending between the first end 21 of the link and the stop 71, and a second portion 20B of the link extending between the stop 71 and the second end 22. The ballast element 70 tends to orient the first portion 20A as vertically as possible. This prevents the first portion 20A of the link back to the surface near the body of the machine 80, especially when the machine 80 moves, as shown in FIG 10. The presence of the ballast element 70 and its abutment 71 therefore makes it possible to very clearly reduce the risk of the link being caught in the fins or in the propeller of the machine 80.

Claims (10)

REVENDICATIONS1. Device for the recovery of a marine or underwater vehicle, this device comprising: - a flexible link (20) having a first end (21) intended to be connected to said machine (80), - a coil (30) to which is connected a second end (22) of the flexible link (20), the flexible link being adapted to be wound around the coil, and - a ballast load (50) adapted to be associated with the coil (30); wherein the coil (30) and the ballast load (50) are such that the coil associated with said load flows, while the coil released from said load floats; and wherein the flexible link (20) and the coil (30) cooperate such that the coil is released from said load (50) by unwinding the flexible link (20) wound around the coil (30). 2. Device according to claim 1, wherein the flexible link (20) carries a first stop (71) between its first and second ends (21, 22), and wherein the device (10) comprises, in addition, at least a first ballast member (70) configured to slide along the flexible link (20) between the first end (21) and the first stop (71). 3. Device according to claim 1 or 2, wherein the coil (30) has a winding surface (33) around which the flexible link (20) can be wound, and wherein the coil (30) has a housing (40) for receiving the ballast load (50), said housing having a first opening (41) through which the ballast load (50) can pass, said first opening (41) being located on the winding surface (33). ). 4. Device according to claim 3, wherein the first opening (41) is plugged by a first cover (39), the outer face (39A) defines a portion of the winding surface (33). 5. Device according to claim 4, wherein the second end (22) of the flexible link (20) is connected to an attachment point (44) located inside the housing (40), wherein the flexible link passes through the first cover (39), and wherein the flexible link (20) carries a second stop (45) between its second end (22) and the cover (39), so that the second stop (45) drives the cover (39). ), so as to unclog the first opening (41) during the course of the flexible link (20). 6. Device according to any one of claims 3 to 5, wherein the housing (40) has a second opening (42) through which the ballast load (50) can pass, the second opening (42) being located io outside the winding surface (33) and being closed by a second cover (38). 7. Device according to any one of claims 3 to 6, wherein the coil (30) carries at least one second ballast element (51), this ballast element (51) being arranged on the coil so as to orientate the first opening (41) down, when the coil (30) is under water. 8. marine or underwater vehicle equipped with a device according to any one of claims 1 to 7, the first end (21) of the flexible link 20 (20) being connected to said machine (80). 9. marine or submarine engine according to claim 8, wherein the machine (80) is configured to be able to embark the coil (30) surrounded by the flexible link (20), the machine (80) comprising a system of release to release the coil (30). 10. A marine or submarine engine according to claim 9, wherein the release system is remotely controllable.