SU954316A1 - Rope disenganger - Google Patents

Description

The invention relates to technical means for providing deep-sea research and can be used for remote separation of anchored objects, such as buoy stations.

Closest to the proposed one is a cable breaker comprising a housing connected to a cable, made of two parts, hermetically connected to each other by a fastener assembly with a weakened element, a control device, an actuator with a power source and a piston installed in the cavity and interacting with the fastener node [1].

A disadvantage of the known device is that, by destroying the fastening assembly, it does not provide a reliable separation of the parts of the body if it is used at great depths due to increased hydrostatic pressure. In addition, the piston is triggered by a pyrotechnic device, which causes additional complexity and leads to a decrease in reliability.

The purpose of the invention is to increase the reliability of operation of the circuit breaker in conditions of deep-sea immersion.

To achieve this goal, the cable disconnector is equipped with a sleeve installed inside the housing, having a groove and interacting with the actuator, and the groove of the sleeve and the piston cavity are in communication with the environment.

In addition, the actuator is made in the form of a heating element mounted on a sleeve made of thermoplastic material.

In FIG. 1 shows the proposed circuit breaker, section; in FIG. 2 - node I in FIG. 1; in FIG. 3 - node II in FIG. 1.

The cable breaker contains a sealed housing made up of two parts I and 2, connected through an o-ring 3 by a coupler 4, which enters the hole of the diaphragm 5, and a nut with a weakened element, which includes a threaded sleeve, 6, coupled to the ring 7 by means of cut pins 8 In the channel of the lower part of the housing 2 there is a piston 9 and a cover 10 with holes for supplying hydrostatic pressure in the cavity of the piston 9. In the upper part of the housing 1 are hydroacoustic receivers 11, control unit 12, power source 13, which are separated from the internal flooded cavity of the disconnector by a cover 14. Electrical contacts 15 are brought out through the cover 14. A destructible sleeve 16 of thermoplastic material with a blind central groove is installed in the upper part 1 of the disconnector, and an actuator representing a heating element is placed on the outer surface of the sleeve 16 ( for example, a nichrome spiral) 17, connected through contacts 15 and a control unit 12 to a power source 13. The sleeve 16 is fixed in the housing of the circuit breaker using the flange 18 and the sealing ring 19.

The station is connected to the disconnector via a cable 20 and an earring 21. The detachable load is fixed with a halyard 22 to the ring 23, and the upper 1 and lower 2 parts of the disconnector are connected by a flexible connection 24 to prevent loss of part 2 after separation of the disconnector.

To evacuate the internal cavity, part 1 of the disconnector is equipped with a pumping line, which includes a pipe 25 and a shut-off valve 26.

In order to facilitate the separation of parts 1 and 2 of the housing between the diaphragm 5 and the lower part of the disconnector 2, a compression spring 27 is installed.

To increase the reliability in the operation of the unit ?. 12 control includes a timer (mechanical clockwork) that connects the heating element 17 to the power source 13 after a predetermined period in case of failure of the hydroacoustic receiving device 11. The disconnector operates as follows.

Both parts 1 and 2 of the case are connected (before setting up the station) using a tie 4 and a nut with a weakened element, which includes a threaded sleeve 6, articulated by means of pins 8 with ring 7 (in the case of vacuuming the internal cavity of the disconnector by a vacuum pump through pipeline 25, such elements a breaker like a coupler 4, a nut with a weakened element and a piston 9 can be excluded).

When the station is immersed at the calculated depth, the hydrostatic pressure acting through the holes in the cap 10 on the piston 9 cuts off the pins 8 and recesses the screed 4, after which both parts 1 and 2 of the casing are held together only by the external pressure of the medium.

At the end of the station, the code signal from the surface waterborne is received by sonar receivers 11 and enters the control unit 12, which connects the power source 13 to the heating element 17. As a result of heating, the sleeve 16 loses its strength and is destroyed by the hydrostatic pressure of the medium transmitted through it central groove.

Entering the internal cavity of the circuit breaker, the water equalizes the internal pressure with the external pressure, after which the spring 27 discards parts 1 and 2 of the housing and the load attached to the ring 23 by the halyard 22 is separated from the station, which, having the necessary buoyancy margin, floats to the surface. The lower part 2 of the housing after separation, hanging on a flexible connection 24, rises with the station and can be used again.

The proposed cable breaker has structural simplicity, is convenient to use and does not require the installation of additional devices to disconnect the parts of the housing, which leads to the reliability of its operation.

Claims (2)

(54) GUN RELEASE The invention relates to technical means for providing deep-sea research and can be used to remotely disengage from indigenous objects, such as buoy stations. Closest to the present invention is a cable breaker comprising a housing connected to the cable, made of two parts, tightly connected to each other by a fastening assembly with a weakened element, a control device located in the housing, an actuator with a power source and a wedge mounted in the cavity and interacting with fastening assembly 1. A disadvantage of the known device is that, having carried out the destruction of the fastening assembly, it does not ensure reliable separation of the housing parts in case of its application tim bolschoy at depth due to the increased hydrostatic pressure. In addition, the operation of the piston is due to the pyrotechnic device, which causes additional complexity and leads to a decrease in reliability. The purpose of the invention is to increase the reliability of tripping of the breaker under deep-sea diving conditions. To achieve this goal, the cable breaker is provided with a sleeve installed inside the body, having a groove and interacting with the actuator, the sleeve groove and the piston cavity communicating with the environment. In addition, the actuator is made in the form of a heating element mounted on a sleeve made of a thermoplastic material. FIG. 1 shows the proposed breaker, cut; in fig. 2 — node I in FIG. one; in fig. 3 - node II in FIG. 1. The cable breaker comprises a hermetic housing made of two parts 1 and 2 connected through a sealing ring 3 with a stitch 4, which enters the opening of the diaphragm 5, and a nut with a loose element, which includes a threaded bushing, 6 coupled to the ring 7 by means of shear ridges 8. In the channel of the lower part of the housing 2 there is a piston 9 and the cover 10 with openings for supplying hydrostatic pressure in the cavity of the piston 9. In the upper part of the housing 1 there are hydroacoustic receivers 11, control unit 12, power supply 13 which are separated from the inner flooded cavity by the switch 14. The electric contacts 15 are brought out through the cover 14. In the upper part 1 of the switch there is a breakable sleeve 16 made of a thermoplastic material with a hollow central bore, and an actuator is placed on the outer surface of the sleeve 16. a heating element (e.g. a nichrome spiral) 17 connected via contacts 15 and a control unit 12 to the power supply 13, the sleeve 16 is fixed in the switch body by means of a flange 18 and lotnitelnogo ring 19. The station is connected to the disconnect by a cable 20 and 21. The earring Division emy load is fixed tether 22 to the ring 23 and the upper 1 and lower 2 parts breaker associated flexible linkage 24 to prevent loss of part 2 after separation breaker. To evacuate the internal cavity, part 1 of the disconnector is equipped with a pumping line, which includes conduit 25 and shut-off valve 26. To facilitate the separation of the housing parts 1 and 2, a compression spring 27 is installed between the diaphragm 5 and the lower part of the disconnector 2. To increase the reliability of the operation of the unit. The control unit 12 is switched on a timer (mechanical clock mechanism) connecting the heating element 17 to the power source 13 after a predetermined period of time in case of failure of the sonar receiver 11. The opener operates as follows. Both parts 1 and 2 of the housing are connected (before setting up the station) with a stitch 4 and a nut with a weakened element, which includes a threaded sleeve 6, coupled by pins 8 with a ring 7 (in the case of evacuating the internal cavity of the release with a vacuum pump through pipeline 25 such elements of the uncoupler, such as the clamp 4, the nut with the weakened element and the piston 9 can be excluded). When the station is immersed at the calculated depth, the hydrostatic pressure acting through the holes in the cover 10 on the piston 9 cuts off the pins 8 and lowers the tie rod 4, after which both parts 1 and 2 of the body are held together only by the external pressure of the medium. At the end of the station, the code signal from the surface corbal is received by sonar receivers 11 and fed to control unit 12, which connects the power supply 13 to the heating element 17. As a result of heating, the sleeve 16 loses its strength and is destroyed by the hydrostatic pressure of the medium transmitted through its central groove. The flow into the internal cavity of the opener, the water equalizes the internal pressure with the external one, after which the spring 27 rejects parts 1 and 2 of the body and the weight attached to the ring 23 by the fella 22, separates from the station, which, having the necessary buoyancy, floats to the surface. The lower part 2 of the hull, after separation, hangs on the flexible link 24, rises together with the statio and can be reused. The proposed cable breaker has a constructive simplicity, is convenient in operation and does not require the installation of additional devices for disconnecting body parts, which leads to the reliability of its operation. Claim 1. Cable release device comprising a housing connected to a cable, filled in two parts, tightly connected to each other by a loosened fastener unit, a control device, an actuator with a power source, and a piston installed in the cavity and interacting with the fastening unit. node, characterized in that, in order to increase the reliability of the operation of the breaker in deep-sea diving conditions, it is provided with a sleeve installed inside the hull, having a groove and acting with the actuator, the liner bore and the piston cavity communicating with the environment. 2. The disconnecting device according to claim 1, characterized in that the actuator is made in the form of a heating element mounted on a sleeve made of a thermoplastic material. Sources of information taken into account during the examination 1. USSR author's certificate No. 262630, cl. B 64 D 17/22, 1968 (prototype). IIW Z /and / 7 Fig-1