RU2644431C2 - Method for providing movement mode of an intelligent pig in the ethane pipeline - Google Patents

Abstract

FIELD: measurement technology.

SUBSTANCE: invention relates to gas supply system operation, in articular to organization and carrying out of non-destructive testing, and can be used to create optimal modes of movement of flaw detectors for ethane pipelines in in-line inspection. Technical task of the method for providing a movement mode of an intelligent pig in an ethane pipeline, including the movement of an intelligent pig at a given uniform speed, introduction of a intelligent pig into the launch (reception) chamber, replacement of air in the launch (reception) chamber with equalization of pressure in launch (reception) chamber, extension of the intelligent pig from the launch (reception) chamber, extension of the intelligent pig from the launch (reception) chamber, impact on the structure of the intelligent pig, partially overlapping the cross section, movement of the intelligent pig by force, created by the differential pressure, is achieved by the fact that the method is carried out in the following stages: at the first stage, with closed tap cranes 14 and 24, communications between the ethanol pipeline and gas pipeline are installed through spark plugs, through the spark plugs are installed with the installation of control valves 15 and 23, and mobile receiver connected through back-flow valves 26 and 27, at the second stage, the spark plugs are muffled at the points of jumper connection and plug valves 1, 2, 5, 18, 20, plug valves 6, 7, 8, 9, 12, 13, 11, 22, 21 are constantly closed, at the third stage, the plug valve 17 is opened, ethane is discharged between valves 17 and 18 and the intelligent pig is injected to the ethane pipeline space through launch (reception) chamber 28, at the fourth stage, the plug valve 17 is closed and plug valves 20, 16, 19 are opened to equalize the pressure between plug valves 17 and 18 and the pressure behind plug valve 18, at the fifth stage plug valve 19 is closed, and when plug valves 14, 24, 26, 27 are opened, by operation of plug valves 15 and 23, a pressure drop between plug valves 17 and 18 and the ethane pipeline space behind plug valve 18 to 2-3 atm is achieved, at the sixth stage, at the end of the surveyed section, a plug valve is opened to ensure discharge of gas mixture into the atmosphere and necessary pressure drop, at the seventh stage, with closed plug valve 19, plug valves 18 is opened, adjusting the pressure behind plug valve 18, a constant drop of 5 atm is achieved, at the eighth stage, passage of the intelligent pig is adjusted by adjusting the plug valves 15, 23, 26, 27. Sequence of actions with closing and opening the plug valves, as well as bleeding and parallel operation of the mobile receiver, create additional conditions for smoothing the pulsation and provide equalization of pressure, the possibility of carrying out in-line diagnostics without additional funds (technical, financial, etc.). Possibility of returning the gas mixture back to the gas pipeline leads to energy savings and minimization of environmental pollution, and the replacement of ethane with cheaper methane provides reduced operating costs.

EFFECT: technical task of the proposed method for providing the mode of movement of an intelligent pig in an ethane pipeline is to create a method for organizing the mode of movement of intelligent pigs with regulation of movement speed during the in-line inspection (diagnostics) of the ethane pipeline, depending on the conditions of laying the ethane pipeline and a parallel line of the gas pipeline using the available communications, stop valves and mobile receiver.

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Description

The invention relates to the field of operation of gas supply systems, in particular to the organization and conduct of non-destructive testing, and can be used to create optimal modes of movement of flaw detectors of ethanol pipelines during in-line diagnostics.

From the existing level of technology there is known a method of introducing a mole type projectile into an operating pipeline, such as a fluid pipeline, wherein the pipeline is drilled during operation and the projectile is launched into the pipeline through a drilled hole using a pneumatic or hydraulic cylinder (see patent No. RU 2372549 “Method, device and work tool for cleaning and inspection of“ Moisture-proof ”pipelines”, authors Stromayer Uwe (DE), Kopp Gunnar (US), IPC F16L 55/46, publication date 06/27/2003).

A disadvantage of the known method is that it can be reliably applied at relatively low working pressures in the pipeline, while the guide device must be held in position against the working pressure in the pipeline by means of a holding device, which complicates the method by using additional technical means. In addition to the above, the known technical solution involves the use of additional tools, such as inserting an additional pipeline into the pipeline, which reduces the reliability of the diagnosis.

There is a method of controlling an in-pipe object during the diagnosis of a pipeline by accumulating diagnostic and telemetric information using control commands on two control channels — a low-frequency electromagnetic channel and a radio channel of the meter wavelength range, and low-frequency electromagnetic signals are emitted and received using transceiver equipment installed outside and inside pipeline, and the signals transmitted over the radio channel meter wavelength range, emit and receive t with the help of transceiver equipment installed inside the pipeline, using it as a waveguide, with the placement of one set of transceiver equipment of a meter wavelength range on the in-tube object, the transmission of the control command is carried out sequentially through two control channels, initially a control command via a low-frequency electromagnetic channel using transceiver equipment installed outside the pipeline is transmitted through the wall into the pipe and the transceiver is received equipment installed inside the pipeline, then the control command is converted and using the transceiver equipment of the meter wavelength range located inside the pipeline, it is transmitted over the air to the transceiver equipment located on the in-pipe object, the receipt of the receipt of the execution of the in-pipe object control commands is carried out sequentially through two control channels , originally a radio channel meter wavelength receipt using transceiver equipment, p located on the in-pipe facility, it is transmitted to the meter-wave wave transceiver located inside the pipeline, then the receipt is converted through the low-frequency electromagnetic channel using the transceiver equipment installed inside the pipeline, it is transmitted through the pipe wall to the outside and received by the transceiver equipment installed outside the pipe, and the transmission Diagnostic and telemetry information accumulated on the in-tube object is carried out using transceivers authorizing meter waveband equipment placed on the pipe object, receiving transceiver equipment placed in the pipe and fixed in the storage device that is part of its structure (see. Patent No. RU 2528790 “Method and device designed to control an in-tube object”, authors: Skvortsov V.S. et al., IPC F17D 5/00, publication date 09/20/2014).

The disadvantage of this method is the binding of its position to the current coordinates during the diagnosis of the pipeline by accumulating diagnostic and telemetric information contained in the control of the in-pipe object using control commands on two control channels. This leads to the need for preliminary accumulation and analysis of the information received, which leads to an increase in the overall time interval for the implementation of control measures, the complexity of the hardware design and the requirement for highly qualified specialists who are able to operate the specified equipment.

A known method of controlling a two-module flaw detector during an in-tube flaw detection is to control a flaw detector according to the information obtained on the condition of the material of the pipe walls and the magnitude of the electric current distributed in the pipe walls during the movement of the flaw detector through the pipeline in the flow of the product being transported, linked to current coordinates in the process of movement, that information about the state of the pipeline, including the image of its inner surface, obtained in the process All movements of the flaw detector-projectile through the pipeline in the gaseous state of the transported product gas are transmitted from the flaw detector-projectile via radio communication in the meter wavelength range via the pipeline to pumping stations located on the pipeline between which the flaw detector is located, by the electromagnetic wave pipeline type H11, the operating frequency range of the radio communication is defined within 1.25 ± 0.05 relative to the critical frequency for this type of wave in a flaw detector waveguide, processed It is received at pumping stations and, based on the results of processing from pumping stations via a radio link in the same frequency range, commands are issued to the flaw detector shell to control it during movement through the pipeline (see Patent No. RU 2425278 “A method for controlling a two-module flaw detector-projectile during in-tube flaw detection and a device for its implementation”, authors: Shilo V.K. et al., IPC F17D 5/00, publication date 07/27/2011).

The disadvantage of this method is the inability to quickly control the movement modes of flaw detectors-shells in the process of being inside the pipeline, this is especially important when examining long-distance pipelines. Given the significant attenuation of radio waves during propagation in the pipeline, possible changes in the configuration of the gas pipes, the presence of bends, insets with a smaller diameter and local inhomogeneities, it is necessary to optimize both the wavelength range in which radio communication is carried out and the maximum permissible wavelength interval within the selected range used for these purposes, outside of which the appearance of higher harmonics with high attenuation or falling into transcendental waveguide mode is possible.

There is a method of organizing the movement of flaw detectors during flaw detection of a main gas pipeline, which consists of placing a flaw detector in a pipeline, creating a pressure differential by adjusting the pressure before and after the flaw detector, supporting the velocity of the projectile through the pipeline by adjusting the pressure on the pulling cuff, scanning the inner surface of the pipeline during the movement of the flaw detector along the pipeline, when moving depending on changes in speed, regulate the pressure drop across the pulling cuff by passing part of the gas through the adjustable holes and thereby maintain the velocity of the projectile within certain limits along the pipeline, while the distance between the support and pulling cuffs is set to at least 1.2 of the diameter of the measured pipe, and also that give the specified speed by rotation around its axis by installing the shoes of the magnetic modules at a certain angle to the axis of rotation, the angle of installation of the shoes is changed from 0 to 10 °, transverse magnetization is carried out walls of the gas pipe, and the magnetization system is made in the form of a magnet closed in plan, create in the control zone a magnetic field strength equal to the intensity of technical saturation due to the fact that the distance between the magnets is set in accordance with a certain algorithm that does not depend on the diameter of the pipe, magnetization produce sections with pairwise opposite directions of the magnetic field in each section, while the control zones of the first and second magnetization blocks are formed so that it overlap each other by at least 10%, while the total length of the control zone should be equal to the inner perimeter of the cross-section of the pipeline, and the sensors are arranged in the form of a matrix above the surface of the pipeline and covering the perimeter of the pipeline with a given step between the sensors, they dynamically power the sensors, power switching carried out in a circle and read out in a circle, to avoid loss of recorded information, the distance between the sensors should not exceed 3.5 mm, using an induction sensor The distance from the surface of the pipeline to the point of measurement of the magnetic field of dispersion is measured, the distance from the magnet to the nearest sensor must be at least 25 mm, the step of taking information along the axis of the pipeline is set to no more than 3.5 mm due to bypass of the gas stream through the flaw detector, and leakages are recorded magnetic field in the places of defects, carry out multi-channel measurement and high-frequency reading of the received information, form a mathematical model of the fields of the discrete spatial distribution function of the discrete function of the magnetic field, analyze the specified distribution and select defects by type, surface orientation and determine their parameters, perform multichannel measurement and high-frequency reading of the information received, systematize information about defects by groups, for example, general corrosion, longitudinal main cracks, determine the assortment of pipes, orientation longitudinal welds, analyze telemetric information about the parameters characterizing the movement of the flaw detector, measuring the speed of movement of plague strictly on the basis of a fixed ratio to the sectional area of the wire cross-sectional area of the magnetic circuit is equal to 0.25 (see. Application for invention No. RU 2004125461 “Method for flaw detection of a main gas pipeline and a magnetic backbone flaw detector”, authors: Kovalenko AN, Sedykh AA, (RU) IPC G01N 27/87, F17D 5/06, publication date 10.02. 2006).

The disadvantage of this method is the high complexity of the process, high requirements for personnel, the difficulty of adjusting the holes and the need for laying support and traction cuffs, which complicates the process and prevents its use for the implementation of the tasks.

A known method of organizing the movement of in-pipe flaw detectors, described in the method for detecting defects in gas pipeline pipes, includes selecting a section of the pipeline to be inspected in-pipe, passing in-pipe inspection shells through a selected section of the gas pipeline through the launch and receiving chambers of in-pipe inspection shells connected to an existing gas pipeline, and conducting an in-pipe inspection , the passage of in-pipe inspection shells is conducted through the launch and reception chambers, made in the form of , the connecting diameter of which corresponds to the diameter of the gas pipeline, equipped with shut-off valves and gates and temporarily connected to the existing gas pipeline through the candle strands of linear valves adjacent to the section to be inspected (see patent No. RU 2211998 "Method for detecting defects in gas pipeline pipes", authors: Melnik B . I. et al., IPC F17D 3/08, publication date 09/10/2003).

A disadvantage of the known method is the impossibility of using it on launching and receiving inspection shells equipped with stationary cameras, the complexity of the preliminary preparatory work, the small range of regulation of the movement of the in-tube projectile.

A known method of moving an in-tube transport projectile in a main pipeline with a given uniform speed, including supplying from an external source at the beginning of the examined section of the pipeline with the open end of the working medium flow to the in-pipe transport projectile, creating a differential pressure of the working medium on it and moving it by the force created by the differential pressure , as well as the creation of a braking force on the in-tube transport projectile relative to the surface of the pipeline, the value of which depends um from the characteristics of the terrain on which the pipeline section is laid, which is essential, the working medium is used air or gas, the flow pressure of which is pre-set depending on the terrain, control the velocity of the projectile, in case of deviation of the magnitude of the last from the set, correct it by changing the magnitude of the braking force, for which part of the energy of the working fluid stream is converted into hydraulic and electric forms of energy that are used to create a braking force me (see patent No. RU 2369454 “Method for moving an in-tube transport projectile in a main pipeline with a given uniform speed and device for its implementation”, author: I. Hasanov, IPC VVB 9/055, publication date 10.10.2009).

The disadvantage of this method is the use of energy in the form of a medium flow with a predetermined constant pressure for moving the projectile in the pipeline and converting part of the flow energy into hydraulic and electric to create a controlled braking force of the projectile on the pipeline walls in order to adjust the speed in the event of deviation from the set one, which complicates the process of movement, the creation of regulatory efforts requires a special design of diagnostic shells.

The closest to the claimed technical solution for the combination of essential features is a method of moving the in-line inspection apparatus in the main gas pipeline with a given uniform speed, including introducing the apparatus into the launch (reception) chamber, replacing the air in the launch (reception) chamber with natural gas with equalizing the pressure in the chamber the launch (reception) and in the gas pipeline, the extension of the apparatus from the launch (reception) chamber to the linear part of the gas pipeline, the effect on the design of the device, partially overlapping the cross-section of the gas pipeline, the flow of transported gas, the movement of the apparatus along the linear part of the gas pipeline by the force generated by the pressure drop of the transported gas flow and the axial force created by the action of the motor-generator-wheels on the inner surface of the gas pipeline, recharging the battery of the power supply system, controlling the speed of the apparatus, correction the speed of movement of the apparatus in case of deviation of its value from the set, the extension of the apparatus from the linear part of the gas pipeline to the reception chamber ), turning the apparatus on and off in operation due to the presence or absence of a working medium pressure in the gas pipeline in excess of a predetermined minimum level, the apparatus is extended from the launch (reception) chamber to the linear part of the gas pipeline and the apparatus is moved from the linear part of the gas pipeline to the reception (launch) chamber using the motor-generator-wheels operating in a motor mode from the battery of the power supply system, the apparatus is moved along the linear part of the gas pipeline with a minimum transverse displacement of the longitudinal axis of the app arata relative to the axis of symmetry of the gas pipeline due to the spring suspension blocks of the motor-generator-wheel suspension, the correction of the speed of movement of the apparatus, in case of deviation of its value from the set, is carried out using the brake, motor and passive modes of operation of the motor-generator-wheels, with independent control of each motor-generator-wheels, which is selected as a prototype (see Patent No. RU 2451867 “In-pipe inspection apparatus and method for moving it in the main gas pipeline with a given uniform speed”, authors: Natarov B.N. et al., IPC F16L 55/26, F16L 101/30, publication date 05.27.2012).

The disadvantages of the technical solution described in the prototype are the use of the braking, motor and passive modes of operation of the motor-generator-wheels, with independent control of each of the motor-generator-wheels separately, as well as the additional costs of the power system with a battery, which generally reduces reliability of diagnostic work. Constructive complexity leads to high requirements for staff. The introduction of additional elements into the device leads to an increase in the cost of equipment, and, as a consequence, the implementation of the described method itself (for streaming production).

The technical task of the proposed method for ensuring the movement mode of a diagnostic projectile in an ethane conduit is to create an economical way of organizing a movement mode of diagnostic projectiles with speed control when conducting an in-line flaw detection (diagnostics) of an ethane conduit depending on the conditions for laying the ethane conduit and parallel gas pipeline using available communications, shutoff valves and mobile receiver installation.

The technical task posed is a method of providing a diagnostic projectile movement mode in an ethan conductor, including moving a diagnostic projectile at a predetermined uniform speed, introducing a diagnostic projectile into the launch (reception) chamber, replacing air in the launch (reception) chamber with equalizing the pressure in the launch (reception) chamber, the extension of the diagnostic projectile from the launch (reception) chamber, the impact on the design of the diagnostic projectile partially overlapping the cross section, the movement of the diagnostic force, created by the pressure drop, is achieved by the fact that the method is carried out in the following steps: at the first stage, with the taps 14 and 24 closed, the communications between the ethane pipe and the gas pipe are installed through the candle bends, with the installation of control valves 15 and 23 and a mobile receiver connected through non-return valves 26 and 27, at the second stage the candle bends at the junction points are closed and the valves 1, 2, 5, 18, 20 are closed, while the valves 6, 7, 8, 9, 12, 13, 11 are constantly closed 22, 21, on the third stage open the valve 17, bleed ethane between the valves 17 and 18 and through the launch (reception) chamber 28 put a diagnostic projectile into the pipe space of the ethane conduit, at the fourth stage close the valve 17 and open the valves 20, 16, 19 to equalize the pressure between the valves 17 and 18 and pressure after the valve 18, at the fifth stage, close the valve 19 and the operation of the valves 15 and 23 with the open valves 14, 24, 26, 27 achieve a pressure difference between the valves 17 and 18 and the space of the ethanoprop behind the valve 18 to 2-3 atm., on the sixth stage at the end of the surveyed area open the crane for cookies to bleed the gas mixture into the atmosphere and create the necessary pressure drop, at the seventh stage, open the valve 18 with the closed 19 and adjust the pressure behind the 18 valve, achieve a constant differential of 5 atm., at the eighth stage, adjust the passage of the diagnostic projectile by adjusting the valves 15, 23, 26, 27.

The proposed method for ensuring the movement mode of a diagnostic projectile in an ethanol pipe has no analogues. An ethanol pipeline has been proposed a method for organizing the movement of a diagnostic projectile using as a working (moving) medium a gas mixture, mainly methane and to a small extent ethane, selected from a parallel branch of the gas pipeline, instead of ethane. In this case, the smooth passage of the projectile is carried out due to the parallel operation of the mobile receiver unit, which is connected to the methane bypass line from the gas pipeline to the ethane pipeline. Due to the creation of an additional volume, the pulsations arising during the movement of diagnostic shells and during the operation of the control valves of the gas piping and ethane piping are smoothed out.

The range of regulation of the passage of the diagnostic shell due to the application of the proposed scheme for pumping methane through the communications of the ethane pipeline and gas pipeline has been expanded. At the same time, due to the creation of artificial free volumes in communications, which serve as a receiver and an additional free volume of a mobile receiver installation to smooth out pulsations caused by the passage of a diagnostic projectile in an ethan conductor.

The proposed method for ensuring the movement mode of a diagnostic projectile in an ethanol pipeline is universal and suitable for all sections of an ethanol pipeline that are less than 500 m away from the parallel gas pipeline and where it is possible to lay a jumper. The additional volume of the mobile receiver unit allows you to expand the control range, to compensate for the ripple that occurs when regulating the movement of diagnostic shells.

The main advantage of the proposed method for ensuring the movement mode of a diagnostic projectile in an ethan conductor is the possibility of performing in-line flaw detection without involving additional funds. The possibility of returning the gas mixture (ethane and methane, mainly methane) back to the gas pipeline, by installing an additional jumper between the purge plug of the ethane pipeline at the end of the ethane pipeline section under investigation and parallel to the gas pipeline’s thread, leads to saving of material resources and minimizing environmental pollution. In this case, the return of the gas mixture (ethane and methane, mainly methane) to the gas pipeline can be carried out without the involvement of specialized means (compressors or other pressure boosting systems) only provided that the pressure in the gas pipeline is less than the pressure of the returned gas mixture (ethane and methane, mainly methane). This, in turn, can be achieved by reducing pressure in the gas pipeline by means of dispatch and technological control. Replacing the working environment from ethane to a less valuable gas mixture (mainly methane) leads to significant cost reductions when conducting in-line flaw detection of an ethane pipeline and reducing the cost of the finished product, for which ethane is used as raw material. The use of a mobile receiver installation connected in parallel allows smoothing pulsations in the system and expanding the ranges for regulating the passage of diagnostic shells when examining an ethan conductor.

An analysis of the known technical solutions carried out according to scientific, technical and patent documentation showed that the set of essential features of the claimed technical solution is not known from the prior art, therefore, it meets the patentability conditions of “novelty” and “inventive step”. It has practical suitability for gas transmission enterprises.

The claimed technical solution is illustrated by a diagram illustrating a method for organizing a pass of a diagnostic projectile during an in-line inspection of an ethane pipe.

The method is carried out according to the following steps: if the project of the ethan pipeline does not provide a stationary launch (reception) chamber in areas where it is necessary to conduct in-line diagnostics, then the camera is mounted at the beginning of the surveyed area with closed valves 17, 14, 10, 11, 3, 4 launch (reception) 28. Installation of the launch (reception) chamber is carried out by cutting out the coil of the ethanol conduit (breaking) under the installation location of the launch (reception) chamber. Also, if the project does not provide for a launch (reception) chamber at the end of the ethanol pipe section being examined, then a launch (reception) camera is installed at the end of the diagnosed ethan pipe section. At the first stage, with closed taps of inset 14 and 24, the communications between the ethane and gas pipelines are installed through the candle taps, with the installation of control shutoff valves 15 and 23 and the mobile receiver unit connected through the check valves 26 and 27, at the second stage, the candle taps in places the jumper is connected and the valves 1, 2, 5, 18, 20 are closed, while the valves 6, 7, 8, 9, 12, 13, 11, 22, 21 are constantly closed, at the third stage they open the valve 17, bleed the ethane between the valves 17 and 18 and through the camera start (reception) 28 lead into the pipe the space of the ethane conduit between the taps 17 and 18, a diagnostic projectile, with the subsequent purging of air entering the start-up (intake) chamber, and pressure equalization in the start-up (intake) chamber with the pressure in the ethane conduit, for this, at the fourth stage, close the valve 17 and open the valves 20, 16, 19 to equalize the pressure between the valves 17 and 18 and the pressure after the valve 18, in the fifth stage, close the valve 19 and the operation of the valves 15 and 23 with the open valves 14, 24, 26, 27 achieve a pressure differential between the valves 17 and 18 and the space of the ethane conduit behind the crane 18 to 2-3 atm., on w In a different stage, at the end of the surveyed section, a valve is opened to ensure that the gas mixture is vented to the atmosphere and the necessary pressure drop is created (in the case of, for example, organizing the bypass of the gas mixture, at the end of the diagnosed ethan pipeline, back to the gas pipeline, due to existing communications, venting the gas mixture does not occur), at the seventh stage, the valve 18 is opened while the valve 19 is closed, and by adjusting the pressure behind the 18 valve, they achieve a constant difference of 5 atm., while after passing the diagnostic projectile ohm of the initial section, which is equal to 50 diameters of the ethan pipeline, the pressure is relieved by adjusting the taps 25 and 24 until a constant gradient is established on the diagnosed section of the ethan pipeline 2-3 atm., at the eighth stage, the passage of the diagnostic projectile is adjusted by adjusting the taps 15 , 23, 26, 27, increasing or decreasing the volume of methane sent from the gas pipeline to the ethanol pipeline through communications through a mobile receiver unit, while the diagnostic projectile is moving along this pipeline, due to the impact of the gas mixture on the design of the diagnostic projectile, partially overlapping the cross-section of the ethan conductor, which allows you to move the diagnostic projectile at a given uniform speed.

Pressure pulses are smoothed out by creating strapping (ethan conduit and gas pipeline) areas that act as a receiver for smoothing pulsations and a mobile receiver unit, which ensures smooth adjustment of the diagnostic projectile travel modes inside the ethan conduit (ethan conductor section from tap 1 to tap 10 and from tap 2 to crane 3 and other sections of the ethan pipeline).

The sequence of actions with closing and opening taps, as well as bleeding and parallel operation of the mobile receiver unit creates additional conditions for smoothing pulsations and provides pressure equalization, the possibility of performing in-line diagnostics without involving additional funds (technical, financial, etc.). The possibility of returning the gas mixture back to the gas pipeline leads to energy savings and minimizes environmental pollution, and replacing ethane with cheaper methane leads to lower operating costs.

Claims (3)

1. A method for ensuring the movement mode of a diagnostic projectile in an ethan conductor, including moving a diagnostic projectile at a predetermined uniform speed, introducing a diagnostic projectile into the launch (receiving) chamber, replacing air in the launch (receiving) chamber with equalizing the pressure in the launch (receiving) chamber, extending the diagnostic projectile from the launch (reception) chamber, the impact on the design of the diagnostic projectile, partially overlapping the cross section, the movement of the diagnostic projectile by the force created by pressure hell, characterized in that the method is carried out in the following stages: at the first stage, with closed taps of inset 14 and 24, communications are installed between the ethane pipeline and the gas pipeline through the candle bends, with the installation of control valves 15 and 23 and a mobile receiver unit connected through the return valves 26 and 27, at the second stage, the candle bends are plugged at the junction points and the valves 1, 2, 5, 18, 20 are closed, while the valves 6, 7, 8, 9, 12, 13, 11, 22, 21 are constantly closed , at the third stage, open the valve 17, bleed ethane is formed between the taps 17 and 18 and a diagnostic projectile is introduced into the tube space of the ethane conduit through the start-up (intake) chamber 28, at the fourth stage, the valve 17 is closed and the taps 20, 16, 19 are opened to equalize the pressure between the taps 17 and 18 and the pressure after the valve 18 , at the fifth stage, close the valve 19 and the operation of the cranes 15 and 23 with the open cranes 14, 24, 26, 27 achieve a pressure differential between the valves 17 and 18 and the space of the ethanol conduit behind the valve 18 to 2-3 atm., at the sixth stage at the end of the subject section open the crane to ensure bleeding gas with If you enter the atmosphere and create the necessary pressure difference, at the seventh stage, open valve 18 with the closed 19 and adjust the pressure behind the 18 valve, achieve a constant differential of 5 atm., at the eighth stage, adjust the passage of the diagnostic projectile by adjusting the taps 15, 23 , 26, 27. 2. A method for ensuring the movement mode of a diagnostic projectile in an ethan conductor according to claim 1, characterized in that the movement of a diagnostic projectile with a predetermined uniform speed is achieved through the use of a mobile receiver installation and communications of an ethanol conduit and a gas pipeline that perform the functions of a receiver apparatus to smooth out pressure pulsations that occur when movement of the diagnostic shell. 3. A method of providing a movement mode of a diagnostic projectile in an ethane pipeline according to claim 1, characterized in that the gas mixture consists of ethane and methane, moreover, primarily methane, from a parallel gas pipeline string.

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