FR2813579A1 - Submersible mooring device with deflation means comprises mooring line, submersible body and compressed air generator; when filled with gas body rises to surface and after time lapse valve opens and gas expelled - Google Patents

Abstract

The mooring device comprises a mooring line, a body (31) able to be submerged or raised to the surface and a compressed air generator. The submersible body is provided with its own means of deflation. When it is filled with gas the body is raised to the surface. After a certain time lapse a valve opens and puts the body interior in contact with the outside air. The gas under the effect of forces exerted by the deflating means is expelled from the body through the compressed air conduit (33) and the valve but it is not put in the water previously. The opening of the valve can be controlled by a chronometer. The deflation means can consist of a longitudinal support (35) passing right through the body and on which the body is prestressed longitudinally.

Description

Description

  The invention relates to a mooring device comprising a mooring line fixed by means suitable for a fixed mooring point, a submersible body to facilitate the gripping of the portion of the mooring line intended to be fixed to the boat, said submersible body being able to be immersed or brought up to the surface in response to a signal, a compressed gas generator, preferably compressed air, intended to fill said submersible body with said gas in order to bring it up to the surface as well as means to get the gas out of the submersible body in order to cause the deep immersion of said

submersible body.

  Conventional wetting devices generally consist of a chain fixed by one end to the bottom of the water, for example to a concrete slab and by the other end either directly to a chest or to a mooring by means of 'a rope, rope connecting the chain to the mooring. The function of the chest or mooring is to indicate the

  position of the free end of the mooring chain and to facilitate its reboarding.

  When a boat wants to moor on the chain indicated by a mooring, the crew seizes the mooring, brings it back on board and shoots the rope until the chain appears. This is then fixed to the mooring bollard and the rope is struck, for example around the mast. If the mooring is done on a trunk, it must be moored under the trunk with a

  chain attached to the boat and the free end of which is meshed on the boot chain.

  These conventional devices are found either individually to allow anchorage in a cove for example, or in ports as a second mooring point when

  boats must moor perpendicular to the wharf or a pontoon.

  These devices have many drawbacks. In the case of chests for example, the buoyancy of the float must be sufficient to pull the chain towards the surface whatever the level of the tide. In practice, it must correspond to twice the weight of the chain suspended at high tide. This implies that the trunk has a large volume which can make docking maneuver difficult and its inertia can cause damage in the event of accidental collision. In addition, the chain is always in movement and wears out due to the friction of the meshes one on the

  others even if no boat is moored there.

  The mooring does not have this drawback since the chain rests on the bottom when no boat is moored there. However, the rope which connects the end of the chain to the mooring must be long enough for the mooring to float even at high tide. In practice, a length equal to one and a half times the maximum expected water height is chosen. The orin then risks being cut by a propeller. Whether it is a trunk or a mooring, the float always remains on the surface of the water when no boat is moored there. However, the free space in marinas is more and more limited. When a boat wants, for example, to dock at a pontoon, it approaches the pontoon in reverse, moor at the pontoon, then a member of the crew, placed at the front of the boat, takes hold of the float using a gaff to moor the bow of the boat to the mooring chain thus caught. This same float usually has

hindered the approach maneuver.

  In particularly congested ports, where the possibilities for maneuvering are particularly reduced, this problem has been circumvented by lengthening the mooring chain so as to be able to fix its free end to the pontoon or the quay. When the boat is moored to the quay or to the pontoon, the crew grabs this end and lifts the chain by going up towards the front of the boat in order to be able to moor conventionally to this chain. However, this solution has the disadvantage of being inconvenient or even

  dangerous when weather conditions are unfavorable.

  Document DE 34 32 868 A1 discloses a mooring buoy with an inflatable float fixed to a mooring chain and connected by a pipe to a compressor placed on the quay. When no boat is moored on the mooring chain, the buoy is deflated and lies on the bottom of the water with the end of the chain. If a boat wishes to moor on the buoy, a signal is emitted from the boat causing the compressor to start and the mooring buoy to swell, which goes back to the

  surface, carrying with it the end of the mooring chain to which it is fixed.

  The crew can then moor the boat conventionally. At the end of the operation, a second signal is sent to cause the compressor to draw in the air contained in the buoy. During the fitting, the deflated buoy is returned to the water and, its buoyancy no longer being sufficient to pull the chain, it falls back to the bottom of the water. Thanks to this device, it is possible to retract the float as long as it is not used. Premature wear of the chain by rubbing the links against each other is also avoided as well as a risk of shearing of the rope. However, this system has the drawback of requiring either a compressor making it possible both to compress and suck the gas into the float, or a deflection device making it possible to connect the pipe either to the inlet or to the outlet of a simple one-way pump. In all cases, the device is expensive and relatively fragile. In addition, a signal must be sent to cause deflation of the float and therefore remove the stresses exerted on it. If the crew forgets to transmit this signal, the float may remain inflated during the whole mooring, which can in the long run have a negative influence on its tightness and its lifespan. In addition, to prevent the pump from sucking too much water in the event of a system leak, it is necessary to provide the system with a water detector to stop it.

0 of the pump.

  The objective of the invention is therefore to develop a mooring device of the type of

  the one described above which does not have the drawbacks presented above.

  This objective is achieved by the device according to the invention in which the means for removing the gas from the submersible body include a communication device which, when actuated, makes the interior of the submersible body communicate with the air exterior and means for exerting a positive pressure force on the gas contained in the submersible body so that it escapes. By actuating the communication device, the overpressure inside the submersible body disappears and the positive pressure forces exerted on the gas contained in the submersible body force the gas to exit from the device. As the buoyancy of the submersible body is no longer sufficient, it submerges when it is returned to the water. It is no longer necessary to pump the gas contained in the submersible body at the risk of pumping water in the event of rupture of the device; just let it escape. The function of the compressed gas generator is only to pressurize a submersible body. This generator is preferably an air compressor. In a preferred embodiment of the invention, the communication device comprises a valve which is preferably placed on the submersible body or on a pipe connecting the submersible body to the generator of pressurized gas. We will choose for example an electromagnetic valve or a manual valve

  that the crew or a third person can operate.

  In a first alternative embodiment, the means for exerting a positive pressure force on the gas contained in the submersible body are constituted by the material forming the submersible body which is flexible so that the submersible body is inflatable and by the fact that the submersible body forms with the compressed gas generator a waterproof unit. When the communication device is activated, the inherent elasticity of the material constituting the submersible body and later the hydrostatic pressure exerted by water on the flexible submersible body associated with the tension exerted downwards by the mooring line and / or the dead weight of the submersible body cause the expulsion of the gas contained in the submersible body which

  deflates and immerses for lack of sufficient buoyancy.

  To increase the rapidity of deflation of the flexible submersible body, it is preferable to provide it with clean deflation means which tend to cause it to deflate. The pressure force exerted by these deflation means is added to the inherent elasticity of the material constituting the submersible body and to the hydrostatic pressure exerted by water. In a preferred embodiment of the invention, the means for deflating the submersible body consist in particular of a longitudinal support passing right through the submersible body and on which said submersible body is fixed prestressed in longitudinal extension. The mooring line is for example fixed to one end of the longitudinal support and a ring is placed on the other end to facilitate its gripping. The submersible body generally has a spherical or oval shape. The longitudinal support passes through its axis of rotation. It is fixed on this longitudinal support beyond the positions it would have in the normal inflated position. In the absence of overpressure, the pre-stressed submersible body tends to flatten along

  of the longitudinal support causing the expulsion of the gas it contains.

  In another embodiment which may be complementary to the previous one, the means for deflating the submersible body consist of rods or elastic elements surrounding the submersible body on which they are placed in tension when the submersible body is under pressure. When the pressure disappears, these rods or these elastic elements tend to return to their initial shape by straightening or

  shrinking, thereby causing gas to be expelled from the submersible body.

  In a second embodiment, the submersible body is rigid and has a cavity and the means for exerting a positive pressure force on the gas contained in the submersible body allow the cavity to be filled with water by expelling the gas from it. . Thus, when the submersible body is returned to the water, the communication device being actuated, the gas is replaced by water and the submersible body

  no longer having enough buoyancy immerses itself.

  It is in accordance with the invention that the means for exerting a positive pressure force on the gas contained in the submersible body consist of an opening formed on the lower part of the submersible body to bring the cavity into contact with water, while the communication device is preferably placed on the top of the submersible body. Thus, when the communication device is actuated, the gas contained in the cavity is expelled by the water penetrating from the bottom of the

  cavity from which it escapes through the communication device.

  In general, it is preferable to provide a non-return valve between the compressed gas generator and the communication device. Thus, when the pressure necessary to maintain the surface of the submersible body is reached or a certain period of time necessary for the expulsion of the water contained in the rigid float has passed, the compressed gas generator can be turned off, The unit formed by the conduct and

  submersible body being sealed by the non-return valve.

  In order to prevent the overpressure applied to the submersible body and to the pipe from damaging the installation, it is in accordance with the invention that the communication device is controlled by a time measurement instrument which emits a signal when 'A predetermined period of time has elapsed since the admission into the submersible body of the gas under pressure for the ascent of said submersible body. Said signal causes actuation of the communication device as soon as the time

  normally required for the approach maneuver is completed.

  An exemplary embodiment of the invention is described below using the following figures: Figure 1: Submersible body fulfilling the function of a dead body as a second mooring point on a pontoon, having the form of an inflatable balloon, in the high position; Figure 2: Submersible body performing the function of a dead body as a second mooring point on a pontoon, in the form of an inflatable balloon, in the low position; Figure 3: Submersible body fulfilling the trunk function, having the shape of an inflatable balloon prestressed longitudinally, seen in section in the inflated position; Figure 4: Submersible body fulfilling the function of trunk, having the shape of an inflatable balloon prestressed longitudinally, in the deflated position Figure 5: Submersible body fulfilling the function of a trunk, having a rigid shape during gas filling; Figure 6: Submersible body fulfilling the function of a trunk, having a rigid shape during the expulsion of gas by water;

  Figure 7: Detail of an embodiment of the compressed gas generator.

  In a first embodiment presented in Figures 1, 2, 3 and 4, the submersible body is an inflatable buoy (1, 31) connected to a compressed air generator (2)

  (compressor) via a line (3, 33). When inflated, the buoy (1, 31) acts as a body-

  dead or chest. A rope (5) connects it to the mooring chain (4) which is itself fixed to the bottom, for example by a concrete pad (6). The pipe (3, 33) is tightly fixed to the buoy (1, 31) so that water cannot enter either the balloon (1, 31) or the pipe (3, 33). When the buoy (1, 31) is inflated with air, as shown in Figures 1 and 3, it floats on the surface of the water from where it can be caught using a hook to be mounted on board. You then access the mooring chain (4) by pulling on

the orin (5) in a conventional manner.

  A valve (24), acting as a communication device, is placed in the compressor housing (21) on a branch of the pipe (3). This valve (24) is controlled by a chronometer (23), the start of which has been started automatically at the start of the pressurization of the buoy (1, 31). After a

  predetermined period of time, the chronometer causes the valve (24) to open.

  The inside of the buoy is therefore brought into contact with the outside air. The valve remains open until the next compressor start. Under the effect of its own elasticity and possible deflation means placed on the buoy (1, 31), the tensions due to the overpressure decrease and the buoy tends to deflate at least partially. The life of the buoy (1, 31) and the pipe (3, 33) is thus greatly improved. Since the pressure is removed automatically after a certain period of time, the crew is not likely to forget to relax the device. Furthermore, if the pressurization of the device was triggered inadvertently, the buoy will submerge

  automatically after the preset time, freeing up the maneuvering area.

  At the time of fitting, the chain is returned to the water where it falls under the effect of its weight. Under the combined effect of the weight of the buoy (1, 31) and the rope (5) or the chain (34) as well as the hydrostatic pressure of the water, the residual air is expelled from the buoy (1, 31) in the line (3, 33) from which it escapes through the valve (24). The buoyancy reserve is no longer sufficient, the curled buoy falls to the bottom of the water,

as shown in figure 2.

  When the submersible body fulfills the function of trunk, it is possible to fix two mooring ends on its lower ring, to make them go up each on one side of the trunk towards the top of this one to make them pass by the upper ring of the boot and fix them in the classic way to the boat. By avoiding, the boat pulls on the mooring ends which causes the submersible body to crush and the air it contains to be expelled via the open valve (24). The submersible body is therefore deflated and it will fall to the bottom of the water as soon as the mooring chain is released, where it will eventually deflate. It is possible to fix the flexible buoy (31) on a longitudinal support (35) in an extended position along the main axis (for example the axis of rotation if the buoy is spherical or oval). Thus the two ends (36, 37) of the buoy (31) through which the longitudinal support (35) passes are stretched outwards before being fixed. The normal position of the unconstrained buoy is shown in dotted lines in Figure 3. In the absence of pressure, the buoy (31), stretched longitudinally tends to approach the longitudinal support by expelling the gas it contains as shown in the figure 4. When the gas is introduced, the pressure applied is higher than the extension voltages and the buoy inflates normally. The chain (34) or the rope can be fixed either at the lower end of the longitudinal support or cross it so that it is possible to moor directly on the top of the buoy (31). The compressed gas line (33) can be fixed for example directly to the buoy as is

  shown in Figures 3 and 4. It can also pass through the longitudinal support.

  In order to prevent the compressed gas line from being damaged, it is preferably ballasted. In ports where the free end of the mooring chain (4) is fixed to the pontoon, it is possible to fix the compressed air line (3) at this end of the chain (4). This is the solution chosen in Figures 1 and 2. Another solution consists in

  provide weights regularly distributed to force it to stay at the bottom of the water.

  In another alternative embodiment of the invention, the submersible body (11) is rigid and fills with water when it has to descend deep. For this, the valve (12), instead of being in the compressor housing, can for example be fixed to the top of the buoy (11), an opening (15) being provided at the bottom of the buoy (11), near the anchor attachment point or the passage of the mooring chain (14). To fill the buoy (11) with air, the valve (12) is closed and the compressed air arrives through the line (13). Air flushes

  the water through the opening (15) and the buoy rises to the surface as shown in Figure 5.

  When the valve (12) is open and the submersible body is in water, this penetrating under the effect of the weight of the buoy (11) through the opening (15) causes the expulsion of the air through the valve (12) and the descent of the submersible body (11) as shown in Figure 6. It goes without saying that the compressed gas line can penetrate through the top of the submersible body, for example at the location of the valve (12). Likewise, the valve can be located on the pipe in the compressor housing. In the latter case, it is preferable that the pipe opens onto the top of the submersible body to facilitate the escape of the gas when the valve is open. Water can enter the pipe in application of the principle of communicating vessels, but this water does not

  will go up no further than the valve and will never enter the compressor.

  The triggering of the compressor (21) and the pressurization of the submersible body can be controlled manually or remotely controlled from the boat. A receiver (25), contained for example in the housing (2) of the compressor, receives the signal sent from the boat, closes the valve (12, 24) and starts the compressor (21). A non-return valve (22) prevents gas from escaping from the system so that it is possible to turn off the compressor (21) when a threshold pressure is reached or after

a predefined period of time.

  It does not matter how the mooring line is attached to the bottom of the water.

  It can be a concrete stud as in the examples cited in the document, it can

  also be a transverse chain in a port or any other appropriate means.

  The mooring device according to the invention makes it possible to raise or lower a submersible body without risking water entering the compressed gas generator. By coupling the communication device to a time measurement instrument, such as a stopwatch, which causes the automatic decompression of the system after a certain period of time, it is certain that the system remains under pressure only for the time necessary the process. These advantages make it possible to considerably increase the service life of the compressor which does not come into contact with water, in particular sea water, as well as that of the submersible body and the pipe.

Claims (11)

claims   1. Anchoring device comprising - a mooring line fixed by suitable means to a fixed mooring point, - a submersible body to facilitate the gripping of the portion of the mooring line intended to be fixed to the boat, said submersible body which can be immersed or brought up to the surface in response to a signal, - a compressed gas generator, preferably compressed air, intended to fill said gas with the submersible body to bring it up to the surface, - means for removing the gas from the submersible body in order to bring about the deep immersion of said submersible body, characterized in that the means for removing the gas from the submersible body comprise a communication device which, when actuated, makes communicate the inside of the submersible body with the outside air and means to   exert a positive pressure force on the gas contained in the submersible body so that it escapes.   2. Anchoring device according to the preceding claim, characterized in that   that the device for communicating with the outside comprises a valve.   3. Wetting device according to claim 2, characterized in that the valve is placed on the submersible body or on a pipe connecting the submersible body   to the pressurized gas generator.   4. wetting device according to one of the preceding claims,   characterized in that the submersible body is formed of a flexible material so that said submersible body is inflatable, and in that it forms with the gas generator   compressed a waterproof unit.   5. Wetting device according to claim 4, characterized in that the means for exerting a positive pressure force on the gas contained in the submersible body include in particular deflation means specific to the body   submersible which tend to cause deflation.   6. Wetting device according to claim 5, characterized in that the means for deflating the submersible body consist in particular of a longitudinal support passing right through the submersible body and on which said body   submersible is fixed prestressed in longitudinal extension.   7. A wetting device according to claim 5 or 6, characterized in that the means for deflating the submersible body consist in particular of rods or elastic elements surrounding the submersible body on which they are placed.   tension when the submersible body is under pressure.   8. A wetting device according to claim 1, 2 or 3, characterized in that the submersible body (11) is rigid and has a cavity and in that the means for exerting a positive pressure force on the gas contained in the body submersible   allow the cavity to be filled with water by expelling gas from it.   9. Wetting device according to claim 8, characterized in that the means for exerting a positive pressure force on the gas contained in the submersible body consist of an opening (15) formed on the lower part of the submersible body to put in contact with the cavity with the water, and in that the setting device   in communication is preferably placed on the top of the submersible body.   10. Wetting device according to one of the preceding claims,   characterized in that a non-return valve is placed between the compressed gas generator   and the communication device.   11. Wetting device according to one of the preceding claims,   characterized in that the communication device is controlled by a time measuring instrument which emits a signal when a predetermined period of time has elapsed since the admission into the submersible body of the gas under   pressure for the ascent of said submersible body.