RU135613U1 - SIGNAL BUOY AND DEVICE FOR PLACING AND WITHDRAWING A SIGNAL BUOY OUTBOARD - Google Patents

Abstract

1. A signal buoy with a shell made of an elastic gas-tight material with a grass-safety valve, with a radio signal device with an antenna, characterized in that the shell of the signal buoy is made with two nozzles located diametrically opposite, in which a normally closed and a normal open spring-loaded valves, and the spring of the normally closed valve is made more rigid, the valve stems are connected inside the shell by a flexible cable, the length of which is sponds to size obolochki.2. A signal buoy with a shell made of an elastic gas-impermeable material with a grass-safety valve, with a radio signal device with an antenna, characterized in that the shell of the signal buoy is made with two nozzles located diametrically opposite, in which the normally closed and normally open spring-loaded valves, moreover, the spring of the normally closed valve is made more rigid, the valve stems are connected inside the shell with a flexible cable, and the shell is signal the buoy and the flexible cable are made of flexible elastic material, while the length of the cable in unstretched condition corresponds to the minimum shell size, with a cable stretch less than the specified shell size, its rigidity is greater than the spring stiffness of a normally open valve and less than the spring stiffness of a normally closed valve , with a cable extension length greater than the specified sheath size, its rigidity is greater than the norm of the spring norm

Description

A group of utility models relates to means for designating underwater objects, namely to signal buoys discharged from an underwater object.

A means of designating a submarine (PL) in the form of a signal buoy representing a hollow float, the strength of the hull of which is designed for the maximum depth of submarine submersion (Prasolov S.N., Amitin MB, The construction of submarines, M. MO, 1973, p. .207-208). The buoy is fixed outside the solid submarine case in a special baffle of the light case, connected to the submarine by a cable-cable and is transmitted by a mechanical drive from the submarine compartment.

The disadvantage of such a device is its cumbersomeness, due to the increase in the wall thickness of the float body with an increase in the calculated maximum depth, the inability to use the cable breakage, the mechanical drive failure, and the need for time to manipulate the submarine crew to release the buoy overboard.

A known buoy system (patent RU 20229708 C1, 1995), containing a buoy float having positive buoyancy, the body of which is made in the form of a coil with a flexible connection wound around it, also having positive buoyancy. One end of the flexible connection is fixed to the coil, and the other end of the connection is fixed to the underwater object. The coil is fixed on the object with the possibility of separation by means of an actuator.

The disadvantage of such a buoy system is also cumbersome, the possibility of failure of the actuator and obfuscation of the flexible connection when surfacing the coil, as well as the need for the participation of the crew of the submarine to release the buoy overboard.

The closest to the achieved result is a means of designating underwater objects in the form of a signal buoy (patent RU 2155699 C2, 2000), which contains a hollow float made of elastic fabric with a radio signal device and antenna located in it; a device for filling a hollow float with gas through a submarine lock device in the form of a cylinder with compressed air, a hose with a connector, and a lung machine; a device for placing a folded buoy in the form of a submarine gateway device; a device for withdrawing a buoy overboard in the form of a cover for a lock device; a device for maintaining a given volume of the elastic shell of the buoy in the form of a grass safety valve. In an emergency, the buoy is prepared for operation and put into the lock device of the submarine, which is filled with sea water. Then the valve of the cylinder with compressed air is opened and the pulmonary automatic machine fills the inner cavity of the elastic shell of the buoy with air, the pressure in the airlock device is aligned with the outboard pressure, after which the outer lid of the airlock is opened and the signal buoy is discharged overboard due to positive buoyancy. As it emerges to the surface, excess air is vented from the elastic shell through the grass-safety valve.

The disadvantage of such a means of designating underwater objects is the need for personnel to prepare for operation and install a signal buoy in the submarine’s gateway, turn on the radio signal device, fill the airlock with seawater, open the cylinder valve and fill the elastic shell with air and open the outer lid of the airlock to release board. The disadvantage of this means of designating underwater objects is also the possibility of failure of the mechanism of the gateway device and the need to fill with high pressure gas the entire volume of the elastic shell.

The objective of this group of utility models is to create a signal buoy and a device for placing and outputting a signal buoy overboard, ensuring the reliability of automatic departure overboard and the operation of a signal buoy.

The technical result of this group of utility models is to increase reliability and reduce the time for signal buoys to be taken overboard by eliminating personnel manipulations, automatically turn on the radio signal device, and also reduce the volume of high-pressure gas needed to fill the elastic shell of the signal buoy.

The specified technical result is achieved by the fact that in the known signal buoy and device for placing and outputting the signal buoy overboard, containing the signal buoy with a sheath made of elastic gas-waterproof material, a grass safety valve and a radio signal device with an antenna, and a device for placing and signal buoy overboard,

the signal buoy shell is made with two nozzles located diametrically opposite, in which the normally-closed and normally-open spring-loaded valves are sealed, the spring of the normally-closed valve is made more rigid, the valve stems are connected inside the shell by a flexible cable, the length of which corresponds to the specified shell size ,

according to the second embodiment, the signal buoy sheath and flexible cable are made of elastic, elastic material, while the length of the cable in an unstretched state corresponds to the minimum specified sheath size, with a cable extension less than the specified sheath size, its rigidity is greater than the spring stiffness of the normally open valve and less than the spring stiffness of the normally-closed shell valve, with a cable extension length greater than the specified shell size, its stiffness is greater than the gesture normally closed valve spring bones,

a cable connecting the rods of a normally-closed valve and a normally-open valve of the sheath is made in the form of an antenna of a radio signal device that contains means for turning it on under the influence of a cable tension,

a device for placing and outputting a signal buoy overboard, including a cylindrical cup, the open side of which is in communication with the outboard space, a hollow piston with axial movement is installed in the cup, at the end of which a shell composed of segments is located in which is located in the folded in the form of a signal buoy, in the piston cavity with the possibility of its overlap, a normally open valve of the signal buoy shell is installed, which is equipped with a shutter for connecting with the piston A normally closed spring-loaded valve is installed in the form of a valve stem in the form of a valve stem, on the side of the bottom of the cup in the piston cavity with the possibility of its closure, the valve stem and the cup being connected by a flexible cable, the length of which is sufficient for axial movement of the piston, which allows the shell to exit the cup and compress springs of a normally-closed valve, while the space between the bottom of the glass and the piston is connected through the valve to the gas supply means from the underwater object system,

the shutter for connecting to the piston of the normally open valve body is made in the form of a collet shutter.

The set of essential features of the group of utility models allows providing a signal buoy and a device for placing and outputting a signal buoy overboard, increasing reliability and reducing the time for a signal buoy to go overboard, automatically turning on the radio signal device, and also reducing the volume of high-pressure gas needed to fill elastic shell of a signal buoy.

The essence of the group of utility models is illustrated by drawings.

Figure 1 shows the initial state of the signal buoy and a device for placing and outputting the signal buoy overboard.

The signal buoy 1 includes a folded (not inflated) form of the shell 2, with a pipe 3, in which a normally-closed valve 4 is sealed, closed under the action of a spring 5, and with a diametrically located pipe 6, in which a normally-open valve 7 is sealed opened by a less rigid spring 8. To the stem 9 of the normally closed valve 4 and the stem 10 of the normally open valve 7 are attached the ends of the cable 11, the length of which corresponds to the specified dimensions of the sheath 2. The cable 11 is made in the form of an antenna of a radio signal device 12, to otoroe contains a means for inclusion under the influence of the tension of the cable 11.

A device for placing and outputting a signal buoy overboard consists of a cylindrical cup 13 with a bottom 14, which is mounted on a strong body 15 of the underwater object and is closed by an easily removable cover 16. A piston 17 with an internal cavity 18 is installed in the cup 13. O-rings 19 are mounted on the piston 17 Between the cover 16 of the cup 13 and the end face of the piston 17 in the open side of the cup 13, a shell 20 is made up of individual segments 21, a signal buoy 1 is placed in the folded shell 20, a normally open valve 7 of the shell 2 is installed it is provided in the cavity 18, with the possibility of its overlapping, and is equipped with a collet lock 22 with flexible plates 23, with a locking element in the form of a rod 10 of a normally open valve 7. With the valve 7 open, the outer part of the bulges 24 of the flexible plates 23 is located in the groove 25 in the inner cavity 18 of the piston 17, and the inner part of the bulges 24 is adjacent to the stem 10, which prevents the exit of the bulges 24 from the annular groove 25 and valve 7 from the inner cavity 18 of the piston 17. In the cavity 18 of the piston 17 from the bottom 14 of the glass 13 is a normally closed valve 26 springs a spring 27 with the possibility of overlapping the internal cavity 18. The stem 28 of the normally closed valve 26 is connected to the bottom 14 by a flexible, non-stretching cable 29, the length of which is sufficient for the axial movement of the piston 17 to allow the shell 20 to exit the cup 13 and compress the spring 27 of the normally closed valve 26. The space between the bottom 14 and the piston 17 is connected by a pipe 30 through a valve 31 with a source 32 of high pressure gas of an underwater object.

Figure 2 shows the status of the signal buoy and device for placing and output signal buoy overboard after connecting to a gas source. In this case, the internal cavity 18 of the piston 17 through the pipe 30 and the open valve 31 is connected to the high pressure gas source 32, and the piston 17 is in the position of maximum axial displacement from the bottom 14 of the cup 13, the cable 29 is tensioned, the spring 27 is compressed and the normally closed valve 26 opened by rod 28. The signal buoy 1, including the shell 2, the shell segments 21 and the cover 16 are located behind the side of the body of the underwater object 15. The normally closed valve 4 is closed by the rod 5 by the spring 9, the normally open valve 7 is open, which ensures gas from the inner cavity 18 of the piston 17 into the shell 2. The collet shutter 22 is closed, since the thickenings 24 of the flexible plates 23 are adjacent to the stem 10 of the normally open valve 7 and are in the groove 25. This prevents the valve 7 from leaving the inner cavity 18 of the piston 17 , cable 11 is in a loose state.

Figure 3 shows the state of the signal buoy and the device for placing and outputting the signal buoy overboard after filling the elastic shell 2 with gas. The size of the shell 2 is determined by the length of the cable 11, which is in tension, providing compression of the spring 8, closing a normally open valve 7 by the stem 10 and the cessation of gas supply to the shell 2. The predetermined difference in the gas pressure in the shell 2 and the seawater is provided by the stiffness of the spring 5, which holds the stem 9 of the normally-closed valve 4 in the closed position. The radio signal device 12 is turned on by the tension of the cable 11. The thickenings 24 of the flexible plates 23 are brought out of contact with the rod 10, which makes it possible to bend the plates 23, exit the outer part of the thickenings 24 from the groove 25, open the collet shutter of the normally-open valve 7 and float the signal buoy 1 under the influence of Archimedean force. The valve 31 for supplying gas to the glass 13 is closed.

In the second embodiment, the length of the cable 11 in the unstretched state corresponds to the minimum specified size of the shell 2, and its rigidity is sufficient to compress the spring 8 and close the normally open valve 7 after filling the shell 2 with gas to the minimum specified size. The advantage of the second option is to reduce the volume of high-pressure gas required to fill the shell 2 to a predetermined size.

So, for example, with the possibility of a three-fold increase in the length of the elastic cable 11 under tension, it is possible to reduce the volume of high-pressure gas when filling the shell 2 twenty-seven times. The advantage of the second option is especially useful for small objects (for example, bathyscaphe) with a limited supply of high-pressure gas.

Figure 4 shows the state of the signal buoy and a device for placing and outputting the signal buoy overboard when the signal buoy 1 ascends to the sea surface. The difference between the gas pressure in the shell 2 and the pressure of sea water is greater than a predetermined value. The tensile force of the shell 2 and the tension force of the cable 11 is sufficient to compress the spring 5, move the rod 9, open the normally closed valve 4 and discharge some of the gas from the shell 2 to maintain a given pressure difference.

In the second embodiment, the shell 2 is stretched by internal pressure to a predetermined size, the corresponding tensile length of the elastic cable 11 provides its rigidity sufficient to compress the rod 9 travel spring to open the normally closed valve 4, to discharge part of the gas and maintain the specified size of the shell 2.

The proposed group of utility models works as follows:

In the initial, folded state, the signal buoy 1 is located in the beaker 13 of the device for placing the signal buoy and outputting the signal buoy overboard, which is installed in the robust housing of the object 15, the high-pressure gas supply valve 31 is closed (Fig. 1).

In an emergency, the signal 31 opens the valve 31. The gas from the gas source 32 (for example, a gas cylinder) at a pressure exceeding the pressure of the maximum immersion depth, enters the nozzle 30 through the nozzle 30. The gas 17 moves the piston 17 in the nozzle 13 to tension the flexible cable 29 to its full length, while the piston 17 pushes the cover of the glass 16 and the shell 20, which breaks into segments 21, freeing the shell 2 for expansion when filling with gas from the cup 13 overboard. A cable 29 holds the rod 28, which, when moving the piston 17, causes the spring 27 to be pressed and the normally closed valve 26 to open and gas to enter the internal cavity 18 of the piston 17. Gas leakage in addition to the internal cavity 18 is prevented by the sealing rings 19. The normally closed valve 4 under the action of the spring 5 is closed by the rod 9, the normally open valve 7 is open, which ensures the flow of gas from the internal cavity 18 of the piston 17 through the pipe 6 into the shell 2. The collet lock 22 is closed, since the thickenings 24 of the flexible plates 23 are adjacent to the rod 10 normally open valve 7 and are located in the groove 25. This prevents the valve 7 from leaving the inner cavity 18 of the piston 17. The cable 11 is in an unstretched state (figure 2).

When the shell 2 is filled with gas, the distance between the normally closed valve 4 installed in the nozzle 3 and the normally open valve 7 increases, which leads to the tension of the cable 11. Since the stiffness of the spring 8 of the normally open valve 7 is less than the stiffness of the spring 5 of the normally closed valve 4 then when filling the shell 2 with gas and pulling the cable 11 over the length corresponding to the specified shell size 2, the valve stem 10 moves and closes the normally open valve 7, blocking the gas supply to the shell 2. Hold the spring stiffness 5 AET rod 9 normally-closed valve 4 in the closed position that provides the desired gas pressure differential in the sheath 2 and the seawater. The fixed length of the cable 11 necessitates filling with high pressure gas the entire specified volume of the sheath 2.

In the second embodiment, the stiffness of the cable 11 in an unstretched state is sufficient to compress the spring 8 and close the normally-open valve 7 after filling the shell 2 with gas to the minimum specified size.

The radio signal device 12 is turned on by the tension of the cable 11. The thickenings 24 of the flexible plates 23 are removed from contact with the rod 10, which makes it possible to bend the plates 23, exit the outer part of the thickenings 24 from the groove 25, open the collet shutter 22 and exit the normally open valve 7 from piston 17. Under the influence of the Archimedean force, the signal buoy 1 leaves the glass 13 and floats to the surface of the sea. The valve 31 is closed by a signal of a drop in gas pressure in the glass 13.

When the signal buoy 1 ascends to the sea surface, the pressure of the seawater decreases compared to the gas pressure in the shell 2. Excessive pressure in the shell 2 increases the tension force of the cable 11 and compresses the spring 5, moves the rod 9, opens the normally closed valve 4 and relieves part of the gas from the shell 2, which ensures the maintenance of a given pressure difference of the gas in the shell 2 and sea water.

In the second embodiment, during the ascent of the signal buoy 1 to the sea surface, the elastic sheath 2 is stretched by internal pressure to a predetermined size with a corresponding increase in the extension length of the cable 11. With a further ascent of the signal buoy 1, the extension of the sheath 2 and a corresponding increase in the extension length of the elastic cable 11, its rigidity exceeds the stiffness of the spring 5, the tension force of the cable 11 becomes sufficient to compress the spring 5, and move the rod 9, open the normally closed valve 4 and discharge part of the gas to holding a predetermined size shell 2 (Figure 4).

After the signal buoy 1 has ascended to the sea surface, the normally-closed valve 4 is closed by a spring 5, the rigidity of which provides a predetermined excess of gas pressure in the shell 2 compared to atmospheric pressure and a given shell size 2 corresponding to the length of the cable 11.

In the second embodiment, after the signal buoy 1 has surfaced and the pressure difference in the shell 2 and atmospheric pressure have stabilized, the shell 2 is equal to the specified size and, with the corresponding extension length of the cable 11, its stiffness is less than the stiffness of the spring 5. This causes the spring 5 to open, closing normally -closed valve 4 by the stem 9 and ensuring the specified size of the shell 2 on the surface of the sea. The closed state of the normally-open valve 7 is ensured by the stiffness and tension force of the stretched cable 11.

Claims (6)

1. A signal buoy with a shell made of an elastic gas-tight material with a grass-safety valve, with a radio signal device with an antenna, characterized in that the shell of the signal buoy is made with two nozzles located diametrically opposite, in which a normally closed and a normal open spring-loaded valves, and the spring of the normally closed valve is made more rigid, the valve stems are connected inside the shell by a flexible cable, the length of which is sponds to a predetermined size envelope. 2. A signal buoy with a shell made of an elastic gas-tight material with a grass safety valve, with a radio signal device with an antenna, characterized in that the shell of the signal buoy is made with two nozzles located diametrically opposite, in which a normally closed and a normal open spring-loaded valves, and the spring of the normally closed valve is made more rigid, the valve stems are connected inside the shell with a flexible cable, and the shell is a signal A buoy and a flexible cable are made of flexible elastic material, while the length of the cable in unstretched condition corresponds to the minimum shell size, with a cable stretch length less than the specified shell size, its rigidity is greater than the spring stiffness of a normally open valve and less than the spring stiffness of a normally closed valve , with a cable extension length greater than the specified sheath size, its stiffness is greater than the spring stiffness of a normally-closed valve. 3. The signal buoy according to claim 1 or 2, characterized in that the cable connecting the rods of the normally closed valve and the normally open shell valve is made in the form of an antenna of a radio signal device. 4. The signal buoy according to claim 1 or 2, characterized in that the radio signal device comprises means for turning it on under the influence of the cable tension. 5. A device for placing and outputting a signal buoy overboard, including a cylindrical cup, the open side of which is in communication with the outboard space, a hollow piston with axial movement is installed in the cup, at the end of which a shell composed of segments is installed in which the shell is located when the signal buoy is folded, a normally open valve of the signal buoy shell is installed in the piston cavity with the possibility of its overlap, which is equipped with a shutter for connecting to the piston with a normally-closed spring-loaded valve is installed by a pirating element in the form of a valve stem, on the side of the bottom of the cup in the piston cavity with the possibility of its overlap, and the valve stem and the cup are connected by a flexible cable, the length of which is sufficient for axial movement of the piston, providing a shell exit from the cup and compression springs of a normally-closed valve, while the space between the bottom of the glass and the piston is connected through the valve to the gas supply means from the underwater object system. 6. The device according to claim 5, characterized in that the shutter for connecting to the piston of a normally-open valve is made in the form of a collet shutter.

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