FR3033313A1 - SYSTEM FOR STABILIZING AND BRAKING THE DIVE OF A SUBURBING OBJECT - Google Patents

Abstract

This system for stabilizing and braking the diving of an object (2) sinking, is characterized in that it comprises at least one capsule (1) attached to the object (2) and in which is disposed at least an O-balloon (3) in the deflated state and means for deploying the system by opening the capsule (1) and inflating the balloon (3).

Description

The present invention relates to a system for stabilizing and braking the diving of a wrecked object.

Different types of objects are likely to be wrecked one way or another. These objects may for example consist of submarine modules for the production of electrical energy, submarines themselves, dangerous goods transport vessels, drones, aircraft after a landing, offshore platforms and machines. EMR (for "Marine Renewable Energy") etc. Such objects must for one reason or another, be able to be recovered in more or less good condition or at least the least degraded possible and in a position such that access to this object is as easy as possible.

In addition, it is in some cases important to protect the cargo or the contents or a part of such objects. For example, it may be desirable to protect the nuclear boiler in a production module, for ships, to prevent hazardous materials from spreading, and for a platform for example ETM (for "Thermal Energy of the Seas") that the working fluid used as ammonia, does not spread. It has already been proposed in the state of the art, in an attempt to solve a number of these problems, to use balloons or releasable buoys. But the various solutions proposed did not give full satisfaction to control and stabilize the diving of the object during the sinking, and especially to reduce the shock of the impact during the landing and the contact with the aircraft. object with the background. The object of the invention is therefore to solve these problems. To this end, the subject of the invention is a system for stabilizing and braking the diving of a wrecked object, characterized in that it comprises at least one capsule attached to the object and in which is disposed at least an O-balloon in the deflated state and means for deploying the system by opening the capsule and inflating the balloon. According to other features of the system according to the invention, taken alone or in combination: the upper part of the balloon is provided with stiffening ribs; The cap comprises two detachable parts from each other, a lower part connected to the object and a top releasable to allow the deployment of the balloon; the balloon is connected to an inflation gas source during its deployment; the deployment means comprise an immersion pressure sensor in order to trigger the deployment of this system; - The capsule is annular. The invention will be better understood with the aid of the description which will follow, given solely by way of example and with reference to the appended drawings, in which: FIG. 1 represents a sectional view of a system according to the invention in storage position that is to say not deployed, - Figure 2 shows a top view of a portion of a system according to the invention, and - Figures 3, 4 and 5 illustrate the operation of it during a dive of an object. It is illustrated in these figures and in particular in Figure 1, a stabilization system and braking of the dive of an object sinking. As previously indicated, different natures and different types of objects can be envisaged. The system according to the invention comprises in fact at least one capsulecrochaged to the object and designated by the general reference 1 in this Figure 1. In this embodiment, the illustrated capsule is annular. It goes without saying of course that other modes and embodiments can be envisaged. The object is represented schematically and designated by the general reference 2 in the figures. In fact, at least one inflatable inflatable balloon is disposed in this capsule, in the deflated state in this FIG.

This balloon is designated by the general reference 3 in these figures, and the capsule also comprises deployment means of the system by opening the capsule and inflating the balloon to allow its deployment. Thus, for example, the deployment means comprise an immersion pressure sensor or the like, in order to trigger the deployment of this system when the object is at a determined depth.

Of course other types of sensors such as inclination, acceleration, etc. can also be used. These sensor means are designated by the general reference 4 in these Figures 1 and 2.

In fact, and as illustrated, the capsule 1 comprises for example two parts detachable from each other. These capsule parts are formed for example by two half-shells, placed one above the other and designated by the general references 5 and 6 in this figure 1, a lower portion 6 is connected to the object 2 and an upper part 5 is releasable during deployment of the system, to allow the inflation and therefore the deployment of the balloon. As shown in FIG. 2, this deployment is in fact obtained for example by releasing the upper part of the capsule and triggering the inflation of the balloon 3 under the control of the immersion pressure sensor 4, by means of such as, for example, a source of gas under inflation pressure of the balloon and designated by the general reference 7. It will also be noted with regard to this FIG. 2 that the part or upper face designated by the general reference 8 of the balloon 3, is provided with stiffening ribs such as for example the stiffening ribs designated by references 9 and 10 in this figure.

The balloon is of course hooked for example on the object through the lower part of the capsule. Of course other embodiments can be envisaged. It is thus conceivable that, at the beginning of the dive of the object, the immersion pressure sensor monitors the flow thereof.

Once the determined deployment pressure has been reached, that is to say the trigger immersion depth of the system, the pressure sensor 4 triggers the release of the upper part of the capsule 1 and the inflation of the toroidal balloon. 3. This is for example illustrated in FIG. 3, where it can be seen that the balloon 3 is inflated and that the displaced volume of water exerts an upward buoyancy, which is the main braking factor. of the diving of the object 2. It is conceivable then that such a structure has a number of advantages insofar as for example during a sinking of an object, from the first meters under water, the braking system activates. As the object is dipped, and thus the balloon is lowered, the increase in external pressure results in a decrease in the volume of the balloon.

3033313 4 The upper part or face 8 of the balloon being stiffened for example by means of the stiffening ribs 9 and 10, this volume reduction can only intervene on the lower part of this balloon, as is illustrated in FIGS. and 5. Thus, the toric balloon 3 is progressively deformed on its non-stiffened face by the whales, to take the form of a parachute which brakes the descent of the object, until the arrival of the one at the level of the bottom and the landing thereof on this bottom as shown in Figures 4 and 5. The structure of the invention thus allows for example to avoid any reversal of the object during its dive, to limit the consequences of the impact with the bottom and to avoid subjecting the object to very large speed variations acceleration or deceleration. It is thus conceivable that such a structure has a certain number of advantages, particularly in the control and stabilization of the diving of a craft during its sinking.

Of course, still other embodiments can be envisaged.

Claims (6)

CLAIMS1.- System for stabilizing and braking the dive of an object (2) sinking, characterized in that it comprises at least one capsule (1) attached to the object (2) and in which is disposed at at least one deflated balloon (3) and means for deploying the system by opening the capsule (1) and inflating the balloon. 2.- System according to claim 1, characterized in that the upper part (8) of the balloon (3) is provided with stiffening ribs (9, 10). 3.- System according to any one of the preceding claims, characterized in that the capsule (1) comprises two parts (5, 6) detachable from each other, a lower part (6) connected to the object and an upper releasable portion (5) to allow the deployment of the balloon. 4.- System according to any one of the preceding claims, characterized in that the balloon (3) is connected to a source (7) of inflation gas during its deployment. 5. System according to any one of the preceding claims, characterized in that the deployment means comprise a dip pressure sensor (4) to trigger the deployment of this system. 6. System according to any one of the preceding claims, characterized in that the capsule is annular.