RU2317464C2 - Method and device for preventing emergency situation in damaging main pipeline - Google Patents

Abstract

FIELD: valving systems.

SUBSTANCE: method comprises detecting break-down by means of dropping pressure of the fluid pumped, detecting the location of the break-down in the pipeline, and shutting off the valving members of the damaged section. The device comprises two valves provided with driving devices at the ends of the break-down section and detecting system made of electric circuit wound on the surface of pipeline.

EFFECT: enhanced reliability.

Description

The invention relates to the field of valve engineering, in particular to safety, fire-fighting, shut-off and emergency devices, which serves to block the flow of the pumped medium into the emergency zone at the protected facility, to prevent the worsening of the accident and its further development until the catastrophe, and can be used first of all, in systems for ensuring the safety of operation of trunk pipelines for pumping gas, oil, and products of its processing. One of the most serious emergency situations on main pipelines is a violation of the integrity of the pipeline: both partial in the form of cracks, fistulas, and complete in the form of a rupture of the pipeline wall along the generatrix, at a length comparable in size to the diameter of the pipeline and its subsequent opening, like shell flaps or destruction of the wall of the pipeline around the circumference up to the separation of one part of the pipeline from another. The reasons for the destruction of the integrity of the pipeline can be: anthropogenic impact - accidental force or shock by the working body of the earth moving mechanisms when performing earth moving directly in the vicinity of the pipeline; geophysical impact - soil movement during landslides and earthquakes; sabotage, terrorist act - the deliberate destruction of the pipeline by blowing it up with explosives. In case of violation of the integrity of the main pipeline, the pumped medium leaks into the surrounding space, which leads to material losses and destruction of the environment ecology. In the event of a partial violation of the integrity, the scale of the leak is relatively insignificant and the maintenance staff manages to take measures to eliminate the accident before the consequences are catastrophic, but this is possible only in the absence of ignition of the leak and, as a consequence, of the fire leading to a catastrophic development of the situation - thermal mass destruction pipeline with all the ensuing consequences. Self-ignition is most likely when a gas pumped through a pipeline leaks under high pressure.

A complete violation of the integrity of the pipeline, sometimes accompanied by irreparable leakage of the pumped medium in huge quantities, determined by the volume of the pumped medium contained not only in the area where the accident occurred, but also in the neighboring sections of the pipeline, from which the pumped medium additionally flows to the place by gravity or under pressure leaks, causing significant material damage and catastrophic consequences of the destruction of the ecology of the environment, if measures are not taken in time to stop ke and localization of leaks, elimination of the causes and consequences of the accident. Moreover, in most cases, especially in case of gas leakage, it is possible with a higher probability of ignition of the leak and fire of the pumped medium that leaked from the pipeline for the following reasons: sparking with significant fast-flowing deformation of the pipe wall during destruction or when a high-speed stream of medium acts on a rocky or pebble soil, etc. If the pipeline is blown up by explosive, fire occurs in 100% of cases. The fire makes it extremely difficult and time-consuming to eliminate the causes and consequences of the accident and many times increases material and environmental damage, leading to catastrophic consequences for the pipeline and nature. The most rational and primary action to deal with the accident and its consequences is the emergency shutdown of the site where the accident occurred, from both ends from the rest of the pipeline, in order to block the flow of the pumped medium to the accident site and prevent the catastrophic development of the emergency on the main pipeline: limit the maximum amount leaks from the pipeline by the volume of the pumped medium contained in the emergency section, and thereby limit direct material and environmental damage, to extinguish or prevent a fire by stopping the supply of additional combustible material to the place of a previous or possible fire and thereby prevent further destruction of the pipeline due to the thermal effect of the fire on the constantly expanding spreading area of the pumped medium, constantly coming from the pipeline and constantly feeding fire, and to provide conditions for early elimination pipeline accident, which provides the opportunity to significantly reduce the total loss from the accident. In practice, on existing main pipelines at the ends of sections into which the linear part of the main pipeline is divided according to the conditions for ensuring the safety of its operation, according to the terrain on which it is laid; in accordance with the requirements of the pumping technology of the medium and the operating conditions of the main pipeline, linear valves or linear valves with remote control and electric actuators, linear pressure sensors for the pumped medium and telecommunication channels connecting linear valves or valves, linear pressure sensors with the control point and employees are installed as a single system for energy transfer for electric linear valves or gate valves, readings of linear pressure sensors, commands controlling the electric drive.

In this case, the catastrophic development of an emergency in case of violation of the integrity of the main pipeline is carried out as follows: according to the readings of the linear pressure sensors, the pressure drop of the pumped medium is recorded and thereby the violation of the integrity of the pipeline is detected and the section where this violation occurred, disconnect this section from neighboring pipeline sections by closing linear cranes or gate valves installed at the ends of the section by applying energy and a command to the electric actuators to close s being sent by the telecommunications channels. After disconnecting the site, a repair team is sent to the accident site to eliminate the accident and its consequences.

The disadvantages of the known method and device are:

- a high probability of failure of the device and the loss of their ability to implement the method under geophysical impact on the main pipeline. This is explained as follows: the shift of the soil during landslides and an earthquake most likely disables telecommunication channels, therefore, the transmission of the readings of linear pressure sensors, energy and commands to electric actuators of linear cranes or gate valves is impossible. It is impossible to determine a specific section, a place where the integrity of the pipeline is violated in the absence of sensors, shutting down a specific section is impossible. Those linear valves or gate valves that remain controlled and are closest to the affected area are closed, including not only the pipeline integrity violation section, but also a significant number of neighboring sections that cannot be turned off to prevent the further development of the emergency until the catastrophe. During the time spent searching for a place of violation of the integrity of the pipeline, making a decision and turning off the linear valves and latches manually at the ends of the lesion site, the leakage amount can be a factor many times higher than the leakage allowed during normal operation of the device. In combination with a possible fire, and the likelihood of its occurrence with the time elapsed since the start of the accident increases many times, destroying the pipeline, the exceptional amount of leakage causes damage, material and environmental, of such a magnitude that clearly gives reason to talk about the development of the accident into a catastrophe. Such a development of events is possible when committing sabotage on the main pipeline - undermining the pipeline with explosives;

- the complexity of the design, the high price list and significant material costs for the installation and dismantling of linear valves or gate valves on the pipeline make it economically impractical to install them along the pipeline more often than is currently accepted in practice, at a distance from each other, determined on the basis of minimization conditions damage in case of a possible pipeline accident;

- the unreliability of the device as a whole, consisting in the fact that the purpose of sequential actions, which is the basis of the device’s functioning from the cause of the accident - violation of the pipeline integrity to the function of the device assignment - disconnecting the emergency section from the rest of the pipeline, includes too many links, which significantly reduces reliability and the performance of the device, the unreliability of each of them significantly reduces the reliability of the device as a whole. This chain includes: violation of the integrity of the pipeline - pressure drop in the pumped medium - recording and transmitting information about it to the control center - analyzing information and making decisions - transferring energy from an extraneous source and a command to execute electric drives - executing a command by electric drives - transmitting information about it to the center control - closing the locking elements - shutting down the emergency section.

Only 9 links.

- a high probability that the device will not recognize a partial violation of the integrity of the pipeline, will not respond to the fact of the accident and will not prevent its development to catastrophic limits. This is explained as follows: the pulse that starts the device into action is the pressure drop of the pumped medium, i.e. the device does not directly respond to the violation of the integrity of the pipeline, but to its consequence as a cause. On a large-diameter pipeline, a partial violation of its integrity in the form of a crack of small length will not cause, against the background of permissible errors, the measurement of a noticeable pressure drop of the pumped medium, which the device would react to, but at a higher nominal pressure it will lead to significant leakage and accumulation of medium at the pipeline, which itself in itself is a significant material and environmental damage. In the event of a fire, the pipeline will collapse under thermal influence, which will definitely lead to catastrophic consequences.

This method and device are closest in technical essence and the achieved results to the invention.

Known valve shutoff valve with thermal control, made of a material endowed with the effect of "shape memory" (SU, a / c, No. 713211, F16K 17/38, F28F 27/00 from 06/21/1976).

The known valve closure has disadvantages in that it can only be triggered by the thermal influence of the working medium from the inside, it does not include a seat on which the closure fits, adapted to deviations of the spatial position of the closure from the nominal in order to increase the tightness valve.

Known shut-off valve with heat-sensitive control, comprising a housing in which a seat and a spring-loaded locking element with a holder of material endowed with the effect of "shape memory" are installed (SU, a / c, No. 629393, F16K 17/38, F28F 23/00 from 16.03 .1977).

A disadvantage of the known shut-off valve is that it only works under the thermal influence of the working medium from the inside, for which it is intended to shut off the flow, and its design is not designed for any external influence.

Known shut-off valve is closest in technical essence and the achieved results to the invention.

An object of the invention is a method, device and shutoff valve in its composition to prevent the catastrophic development of an emergency in case of violation of the integrity of the main pipeline, providing reliable recognition and fixing directly before the emergency, detecting a violation of the integrity of the pipeline simultaneously with its formation and determining the emergency section, emergency, directly without unnecessary intermediate links, actuation of the locking organs, regardless of t external influences on the application object of the method, autonomous, without attracting energy from the outside, reliable disconnection of the emergency section from the rest of the pipeline and prevention of further development of the emergency with a minimum of damage from the accident.

1. The technical task of a method for preventing the catastrophic development of an emergency in case of violation of the integrity of the main pipeline, including recognition and recording of the fact of the emergency as a result of it, a drop in the pressure of the medium pumped through the main pipeline, determining the emergency section among the remaining sections of the main pipeline, supplying energy and command to actuating the locking elements at the ends of the emergency section and thereby disconnecting the emergency section from the emergency of the main part of the main pipeline, is solved according to the invention by recognizing and fixing at the place of the accident the fact of the cause of the emergency — violation of the integrity of the main pipeline during its commission, and thus determining the emergency section and issuing a command to actuate the locking elements of the emergency section by the release in the form of heat of energy accumulated in the locking organs, in addition, duplicate the recognition and recording of the fact of an emergency as a consequence, the presence of a fire at the scene of the accident and thereby duplicate the definition of the emergency site and the issuance of a command to actuate the locking organs by releasing the energy stored in them.

2. The technical task of the device to prevent the catastrophic development of an emergency in case of violation of the integrity of the main pipeline, containing locking elements at the ends of the sections, pressure sensors of the pumped medium through the main pipeline, a signal transmission line from pressure sensors, a command transmission line for actuating the locking elements, is solved according to the invention in that the locking elements are made in the form of shut-off valves with accumulated energy and trigger devices ohm to release it and the device includes a system for recognizing and recording the fact of an emergency at each site, made by type and in the form of a security alarm system, based on monitoring the integrity of the watchdog circuit, communicating with each other shutoff valves, and the watchdog circuit in the form of an isolated the wire conductor is wound in a spiral along the entire length of the linear portion of the main pipeline between the shutoff valves at its ends and glued to the surface of the of the pipeline under isolation, while the system for recognizing and recording the fact of an emergency has two sources of electric current and two actuators, each connected respectively to its trigger device, shutoff valves, and is configured for simultaneous operation of the actuators, in addition to the trigger device on each side of the shut-off valve, two initiating remote chemical means connected in the form of a Bikford cord laid each the first surface of the linear portion of the main pipeline, along the upper generatrix of the tube under its insulation, the entire length of each of two adjacent on both sides to the valve shut-off portions.

3. The technical problem of the shut-off valve as part of a device to prevent the catastrophic development of an emergency in case of violation of the integrity of the main pipeline, containing a housing in which a saddle and a spring-loaded locking element with a holder made of material with the effect of "shape memory" are installed, is solved according to the invention the fact that the shut-off valve includes a chemical heat generator with a store of stored energy and a trigger for releasing energy, a metal housing The horn is made in the form of a sleeve with a regular multifaceted inner surface, to the faces of which spring-loaded petals with holders are pressed tightly, with the entire surface mating with the face, made at the same time as the holder in the form of specially profiled plates made of a material with the effect of “shape memory”, mated between each other by the edges in such a way that the edges of two adjacent petals play the role of a saddle for each petal, and all the petals in the aggregate are a locking organ of the petal type, axial design, etc. from an opposite flow direction, with each petal at the free end on the outside having two consoles resting on two adjacent petals, and, in addition, the shut-off valve includes a pyrocool made of heat-resistant grades of gunpowder, tightly planted along the total inner surface of the petals of the locking organ, which is destructible a sleeve, the inner cavity of which forms the passage channel of the shut-off valve, tightly planted on the inner surface of the pyrometer, and forming together with a heat generator, a shut-off element a separate functional module assembled as a whole by a cylindrical cassette mounted and fixed coaxially with a radial clearance using end caps in the housing, the free surfaces and faces of the heat generator, the surfaces and edges of the petals are thermally insulated from the pyrometer with a layer of dusty heat insulating substance, the inner cavity of the cartridge is sealed with a sleeve and the cavity between the cassette and the housing is in communication with the passage channel with three check valves, low inertia, plate-ring valves, data in the form of an elastic plate, rolled into a ring, prestressed tightly with a predetermined force, tuned to the pressure of the let-in medium P _cf ≤1.5 P _slave , where P _cf is the pressure of the let-through medium, P _slave is the working pressure of the pumped medium; covering the window in the free parts of the cylindrical wall of the cartridge, and installed in the following order in the direction of flow of the pumped medium in the passage channel: the first non-return valve with the passage of the medium from the passage channel in the front of the cartridge, the second with the passage of the medium into the passage channel and the third with the passage of medium from the passage channel - at the rear of the cassette; the middle part of the cassette is occupied by a functional module; moreover, sealing elements made of heat-resistant elastomer in the form of cords are fixed on the edges of the petals.

The invention is illustrated by drawings: FIG. 1 is a general view of a trunk pipeline, FIG. 2 is a view A is a general view of a shut-off valve with a quarter section, FIG. 3 is a section B-B along a shut-off valve perpendicular to its axis, FIG. 4 - section B-B is a general view of the trigger device, FIG. 5 is a section G-D for mating the edges of the petals, FIG. 6 is a section DD for mating the petals with the correct multifaceted inner surface of the body of the heat generator, FIG. 7 is a view of E closed ends of the petals when locking the shut-off valve.

A device for preventing the catastrophic development of an emergency in case of violation of the integrity of the main pipeline with a shut-off valve in its composition consists of a linear part 1 of the main pipeline formed by insulated pipes welded into a string, divided into sections 2 by shut-off valves 3 with drain devices 4 for releasing chemical energy accumulated in the shut-off valve 3. A pressure sensor 5 of the pumped medium is connected next to the shut-off valve 3 in the linear part 1; minutes via the signal transmission line 6 to the control center operation of the main pipeline which is in turn connected 7 commands the transmission line to the trigger device 4 each shut-off valve 3.

Two initiating remote chemical means 8 are connected to the trigger device 4 from two sides in the form of a Bickford cord, each laid along the surface of the linear part 1 along the upper generatrix of the pipe under its insulation for the entire length of each section 2 of two adjacent on both sides of the shutoff valve 3 The system 9 for recognizing and recording the fact of an emergency is made according to the type and in the form of a security alarm system based on the integrity control of a watchdog circuit 10 communicating with each other at 3 at the ends of section 2, and the watchdog circuit 10 also functions as a command line and in the form of an insulated wire conductor is wound in a spiral around the entire section 2 and glued to the surface of the linear part 1 under its insulation, while system 9 has two power sources and two executive bodies, each organically integrated in the trigger device 4, respectively, of each shut-off valve 3 of section 2, and is configured for simultaneous operation of both executive bodies. Sources of electricity can be dry galvanic cells, designed for a long period of operation in standby mode. Executive bodies designed to generate a signal initiating the trigger device 4 in case of violation of the integrity of the watchdog circuit 10, as well as sources of electricity, are not conventionally shown in the drawings. Placement under isolation of initiating remote chemicals 8 and a watchdog circuit 10 is designed to prevent unauthorized access to them.

The shut-off valve 3 consists of a housing 11 with front 12 and rear 13 end caps and includes a chemical heat generator 14 with a store of stored energy, for example a powder heat generator with a trigger device 4, which serves to initiate the release of thermal energy as a result of the combustion reaction of the powder. The metal case of the heat generator 14 has the shape of a sleeve with a regular multifaceted inner surface, to the faces 15 of which spring-loaded petals 16 with holders 17 are pressed with force, tightly mating with the entire face of the surface, made in the form of specially profiled plates made of a material with the effect of “shape memory” ".

The petals 16 with the holders 17 in a free state have a deflection away from the face 15 and, when tightening the bolted joints 18, are spring-loaded completely, which ensures a tight, effortless contact across the face 15 of the petal 16 with the heat generator 14 and effective heat transfer from the heat generator 14 to the petal 16. The petals 16 are interconnected by the edges so that the edges of two adjacent petals 16 act as a saddle for each petal 16, and all the petals 16 together are a locking member 16a of the molding stock type, axial design, upflow direction. The flow of the pumped medium is directed towards the petals 16 when locking the passage channel of the shutoff valve 3 by bending them in position 18a and contributes to the process of bending the petals 16, the bearing capacity and tightness of the shut-off member 16a in this case are maximum. At the free end of each petal 16 there are two consoles 19, supported by two adjacent petals 16. The conjugation of the petals 16 between themselves by means of the consoles 19 ensures synchronization of movement of the petals 16 when they are bent to position 18. On the inner aggregate surface of the petals 16 of the locking member 16a is tightly fitted pyrotechnics 20, molded from heat-resistant grades of gunpowder, on the inner surface of which a destructible protective sleeve 21 is made tightly made of brittle plastic with sufficient strength, the inner floor nce which forms a passageway During shut-off valve 3 and the inner surface is metallized to improve wear resistance. Pyrovolka 20 is thermally insulated from the free surfaces of the faces of the heat generator 14 and the edges and surfaces of the petals 16 by a layer 20a of a dusty heat insulating substance, devoid of binding properties, for example chalk. Chalk is applied to heat-insulated surfaces in a mixture with water, gruel, and when dried forms a dense layer, which crumbles into dust with any external shock or vibration. The heat generator 14, the shut-off element 16a, the pyro-sleeve 20 and the sleeve 21 form a combined functional module 22, assembled into a single unit by a cylindrical cassette 23, mounted coaxially with a radial clearance in the housing 11 and secured with axial interference in it with end caps 12, 13. Cassette 23 consists of two halves that are assembled together along the axis, and the functional module 22 is assembled into a single unit. Thermal insulation 24 is installed between the cassette 23 and the heat generator 14, which reduces heat loss to the environment. When axially assembling the cartridge 23, the sleeve 21 is clamped at the ends, which provides reliable sealing of the cavity of the cartridge 23 with the functional module 22 in it.

The cavity 23 and between the housing 11 and the cartridge 23 is in communication with the passage channel. For three low-inertia, plate-type ring valves 25, 26, 27, each made in the form of an elastic plate, rolled into a ring, prestressed tightly with a predetermined force adjusted to the pressure transmitted medium P _cf ≤1.5 P _slave , where P _cf is the pressure of the medium passed through, P _slave is the working pressure of the pumped medium that covers the windows 28, 29, 30 in the free parts of the cylindrical wall of the cartridge 23 and installed the medium being pumped in the passage channel 3a in the order and purpose: the valve 25 with the passage of the medium from the passage channel 3a in the front of the cartridge 23, the valve 26 with the passage of the medium in the passage channel 3a and the valve 27 with the passage of medium from the passage channel 3a in the rear of the cartridge 23. The cavity 23a must always be in a dry working condition, it is unacceptable that the pumped medium enters it. To ensure that these requirements are met, the valves 25, 26, 27, during installation, sit on the “Sealant” type sealing mastic with a large margin, which ensures reliable sealing of the shutoff state of the valves 25, 26, 27. All joints between the sleeve 21 and the cartridge 23 are sealed with the same sealing mastic , cassette 23 and end caps 12, 13. Valves 25, 26, 27 are installed in sockets 31, 32, 33, which are a continuation of windows 28, 29, 30 and are limited from axial displacement: valve 25 - on one side of the front end cover 12, on the other - the end of the cartridge 23 with Alami 34 for the passage of the medium; valve 26 - on the one hand the blank end wall of the cartridge 23, on the other - the end of the cartridge 23 with channels 35 for passing the medium, valve 27 - on the one hand the end of the cartridge 23, on the other - the end of the rear end cover 13 and channels 36 for passing the medium.

The limitation of the maximum radial displacement of the valves 25, 26, 27 is ensured by: the valve 25 - by the grooves in the front end cover 12 - the end face of the cartridge 23, the valves 26 and 27 - by the grids 37, 38.

The housing 11 has internal distance projections 39 evenly spaced around the circumference to facilitate mounting of the cartridge 23 into the housing 11. The mating edges of the petals 16 are sealed with a cord 40 made of heat-resistant elastomer.

The trigger device 4 is firmly fixed to the housing 11 and communicated with the heat generator 14, the passages in the housing 11 and the heat generator 14 are securely sealed. A device for the release of gaseous products of the reaction of combustion of gunpowder in the heat generator 14 into the environment is conventionally not shown in the drawings. The watchdog circuit 10, remote initiating chemicals 8 in the form of a Bickford cord are laid to the trigger device 4 along the surface of the housing 11 under the insulation layer with which it is covered with end caps 12, 13. According to the signals of the system 9, which initiates the remote chemical means 8, the transmission line of command 7, the descent device 4 should be energized and start the heat generator 14, providing the release of accumulated chemical energy in the form of heat. The closest analogue of the trigger device 4 are the starting pyrotechnic igniters, triggered by an external initial impulse: electric current, heat, mechanical stress; and igniting the main charge, in this case, gunpowder in the heat generator 14.

A way to prevent the catastrophic development of an emergency in case of violation of the integrity of the main pipeline is as follows.

The linear part 1 of the main pipeline is divided into sections 2, limited by shutoff valves 3. The length of sections 2 is chosen depending on various conditions and reasons, including:

from the terrain on which the main pipeline is laid, the seismicity of the laying area, the likelihood of sabotage acts in this area, but the priority will always be the requirement of minimal material and environmental damage in the event of a catastrophic development of an emergency in case of violation of the integrity of the main pipeline. In order to prevent such a development of events, the proposed method and device with a shut-off valve also serve.

In case of violation of the integrity of the linear part 1 in section 2 for various reasons: geophysical - landslide, earthquake, man-made or sabotage act, etc .; the violation can be significant up to the complete destruction of the pipeline or partial - a crack, but in any case this is due to local deformation of the pipeline, causing a violation of the integrity of the watchdog circuit 10 of the system 9 for recognizing and recording the fact of an emergency. Recognition and recording of the fact of an emergency and the definition of the emergency section in this case are a complete break of the watchdog circuit 10 in section 2 before the onset of the emergency, or rather, before the accident. By a rupture of the watchdog circuit 10, the actuators of the system 9 are integrated in the triggers 4 of the two shut-off valves 3 at the edges of section 2, and initial pulses are triggered to trigger the triggers 4, which in turn trigger heat generators 14, for example, powder ignition . The released accumulated energy in the form of heat is used to heat the lobes 16 of the closure body 16a to a critical temperature of the “shape memory” effect of the material, at the same time through the lobes the pyromania 20 is heated to the flash point of the gunpowder 20, but since the pyromania 20 and the petals 16 are separated by a layer 20a of dusty heat insulating substance, the increase in temperature of the pyrometer 20 lags behind the increase in temperature of the petals 16, but reaching the critical temperature of the effect of the “shape memory” of the material of the petal 16 and to the flash point of the powder 20 is carried out simultaneously pirovtulki selection layer 20a and the thickness of the heat insulating material. For example, the critical temperature of a material with the “shape memory” effect based on precipitation hardening austenitic steels is ≈320 ° С, and the flash point of heat-resistant powders is ≈250 ° С.

The explosion of the pyrotechnic barrel 20, which was heated to a flash point, destroys the sleeve 21 to small fragments with the simultaneous spraying of the layer 20a, which is removed from the scene by the flow of the pumped medium. The shock wave in the pumped medium from the explosion is quenched by check valves 25 and 27, through which part of the pumped medium is passed into the dry cavity 23a and thereby limit the pressure increase of the pumped medium. The petals 16 are bent from the initial position to position 18a in that they are heated to a critical temperature and the “shape memory” effect is realized. The consoles 19 of each petal 16 rest on two adjacent petals 16, do not let them lag behind when bending, but the consoles of two neighboring petals rest on the considered petal 16 and do not in turn let them fall behind. Thus, the bend of the petals 16 is synchronized and at the same time bend them to position 18a and thereby close the locking member 16a. The hydraulic shock of the flow of the pumped medium from the emergency closing of the shut-off element 16a is quenched by check valves 25 and 26 by passing through them and the cavity 23a part of the pumped medium and limit the pressure increase of the pumped medium in front of the shutoff valve 3. Similar actions are carried out on another shut-off valve 3 of section 2. Thus, the emergency section 2 is disconnected from the rest of the main pipeline. In the case of a slight violation of the integrity of the main pipeline, which is not recognized by system 9, recognition of the fact of an emergency is carried out after the start of the emergency due to a violation of the integrity of the main pipeline - a drop in the pressure of the pumped medium - the fact is fixed by pressure sensor 5, a signal is transmitted via transmission line 6 to the center control, where after the decision is taken, the initial impulse is transmitted along the command line 7 to the triggers 4 of the shut-off valves 3 ava iynogo portion 2, which is determined in known manner by the pressure readings of sensors 5 adjacent sections 2. Turn off the emergency portion 2 after the start pulse transmission line for entering commands 7 descenders 4 valves 3-stripper emergency site just as described above. If there is a slight violation of the integrity of the main pipeline, for example, a fistula or a small crack not recognized by the system 9, and also due to the consequences of the integrity violation not recognized by the pressure sensor 5, since the pressure drop of the pumped medium is so insignificant that it does not exceed the measurement error, recognition and fact fixing emergency situations are possible under the following circumstances: accumulated leaks of the pumped medium ignite spontaneously or from lightning, or from any For reasons, a fire starts and, under thermal influence, remote initiating chemicals are triggered 8 and the initial impulse in the form of a fire in a bicford cord is transmitted after the onset of an emergency to the triggers 4, but with the simultaneous determination of the emergency section 2, since the fact itself is recognized and recorded emergency situation after the start of its occurrence occurred in the emergency section 2. The initial impulse is transmitted to the trigger device 4 shutoff valves 3 at the ends of the emergency section 2 and turn off the emergency section 2 in the same manner as described above. In the act of sabotage, the fact is recognized and recorded both by the system 9 and the pressure sensor 5 and the remote initiating chemical device 8 at the same time, since significant destruction of the pipeline and fire are 100% likely. After eliminating the consequences of the accident and when restoring the main pipeline, the functional module 22 is replaced with a previously prepared one.

The use of the invention allows to prevent the catastrophic development of an emergency in case of violation of the integrity of the main pipeline and to minimize the material and environmental damage from the accident due to emergency, with double duplication, the operation of the device and the ability to reduce the probable possible amount of damage by reducing the length of the sections taking into account the relatively low cost and simplicity of designs of shut-off valves compared to electric valves and latches.

Claims (3)

1. A way to prevent the catastrophic development of an emergency in case of violation of the integrity of the main pipeline, which includes, in the event of an emergency, the recognition and recording of the fact of the emergency as a result of it, the pressure drop of the medium pumped through the main pipeline, the determination of the emergency section among the remaining sections of the main pipeline, energy supply and commands for actuating the locking elements at the ends of the emergency section and thereby shutting down the emergency about the section from the rest of the main pipeline, characterized in that, in addition to the occurrence of the emergency situation, the fact of the cause of the emergency is recognized and recorded at the place of the accident directly — the violation of the integrity of the main pipeline during its completion with the alarm system and thus the emergency section is determined and give a command to bring the locking organs of the emergency section into action by releasing the stored energy in the form of heat into constipation authorities, in addition, in addition, in the event of an emergency that is not recognized by the alarm system, recognition and recording of the fact of the emergency is made according to its consequence, the presence of a fire at the scene of the accident, and thereby determine the emergency section and issue a command to actuate the shut-off organs on it by the release of energy accumulated in them. 2. A device for preventing the catastrophic development of an emergency in case of violation of the integrity of the main pipeline, containing locking bodies at the ends of the sections of the linear part of the main pipeline, pressure sensors for the medium pumped through the main pipeline, a signal transmission line from pressure sensors, a command transmission line for actuating the locking elements at the ends of the emergency section, characterized in that the locking elements are made in the form of shut-off valves with a reserve accumulated of energy and a trigger for releasing it, the device includes a system for recognizing and recording the fact of an emergency in each section, made by type and in the form of a security alarm, based on monitoring the integrity of the watchdog circuit, communicating with each other the shutoff valves in the section, and the watchdog an electric circuit in the form of an insulated wire conductor is wound in a spiral along the entire length of the linear portion of the main pipeline between the shut-off valves at its end m and glued to the pipe surface, under insulation on it, while the system for recognizing and recording the fact of an emergency has two sources of electricity and two actuators, each connected respectively to its trigger device, shutoff valves and configured for simultaneous operation of the actuators, in addition , to the trigger device of each shut-off valve from two sides are connected two initiating chemicals, made in the form of a bicford cord, each laid on the surface minute linear portion of the main pipeline, along the upper generatrix, the insulation on the whole length of each of the adjacent portions adjacent to the shut-off valve on both sides. 3. The shut-off valve as part of a device for preventing the catastrophic development of an emergency in case of violation of the integrity of the main pipeline, comprising a housing in which a seat and a spring-loaded locking element with a holder are installed, made of material with the effect of "shape memory", characterized in that the valve the cutter includes a chemical heat generator with a stored energy supply and a trigger device for releasing energy, the metal body of which is made in the form of a sleeve with the correct m a faceted inner surface, to the faces of which spring-loaded petals with holders pressed integrally with the holder are pressed against the faces of the surface, which are firmly joined with the face, in the form of profiled plates made of a material with the effect of “shape memory”, mating with each other so that the edges two adjacent petals play the role of a saddle for each petal, and all the petals in the aggregate are a locking organ of the petal type, axial design, upstream flow, with each petal to the free end, on the outside, it has two consoles, resting on two adjacent petals, in addition, the shut-off valve includes a pyrocock made of heat-resistant grades of gunpowder, tightly planted on the inner surface of the lobes of the locking member, a collapsible protective sleeve, the inner surface of which forms a passage the channel of the shutoff valve, tightly planted on the inner surface of the pyro-sleeve, forming together with the heat generator, the locking element a separate functional module, assembled into a single whole cylinder a cassette mounted and secured coaxially with a radial clearance using end caps in the housing, the free surfaces and faces of the heat generator, the surfaces and edges of the petals are thermally insulated from the pyrometer with a layer of dusty heat insulating material, the internal cavity of the cartridge is sealed with a sleeve, and the cavity between the cartridge and the housing is connected with a passage channel with three non-return, low-inertia, lamellar-ring valves, made in the form of an elastic plate, rolled into a ring, preliminary a hard, tight, with a predetermined force, tuned to the pressure medium flows through the P _cf. ≤1,5R _slave where _cf. P - pressure medium flows; _Slave is the working pressure of the pumped medium, which covers the windows in the free parts of the cylindrical wall of the cartridge, and installed in the following order in the direction of the pumped medium’s flow in the passage: the first non-return valve with the passage of the medium from the passage in the front of the cartridge, and the second with the passage of medium in the passage channel and the third with the passage of the medium from the passage channel in the rear of the cassette, while the middle part of the cassette is occupied by a functional module, moreover, sealing e ementy of heat-resistant elastomer in the form of cords.

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