RU201393U1 - DEVICE FOR DELIVERY OF INNER PIPE INSPECTION PRODUCTS TO SECTIONS OF A GAS PIPELINE WITH A DIAMETER WHICH IS LESS THAN THE BASIC DIAMETER OF A GAS PIPELINE - Google Patents

Abstract

The utility model relates to the field of non-destructive testing and can be used for flaw detection of main gas pipelines during their operation to identify defects in gas pipelines and their subsequent repair. The device for delivery of in-line inspection shells to sections of the gas pipeline, the diameter of which is less than the main diameter of the gas pipeline, consists of at least one in-line inspection tool-flaw detector. The in-line inspection tool-flaw detector is connected in a known manner to a pulling tool, which is equipped with an elastic pulling collar for passage in a section of a gas pipeline of a smaller diameter and an expandable elastic collar for passage in a section of a gas pipeline of a basic diameter. At the ends of the collar for passage in the section of the gas pipeline of the main diameter, at least two roller wheels are fixed in a known manner. A cross-country cleaning projectile can act as a pulling projectile. The technical result of the utility model is to ensure the passability of the in-line inspection tool-flaw detector when carrying out in-line flaw detection in the cavity of gas pipelines with a smaller inner diameter than the main diameter of the gas pipeline. 3 C.p. f-ly, 3 dwg

Description

The utility model relates to the field of non-destructive testing and can be used for flaw detection of main gas pipelines during their operation to identify defects in gas pipelines and their subsequent repair.

To ensure safe operation and reliable operability of the gas pipeline, timely detection of changes in its technical condition, assessment of its residual resource, as well as selection of the most effective repair methods are required.

Methods for diagnosing the technical condition of pipes of main gas pipelines using in-line inspection shells (hereinafter VIS) make it possible to determine factory defects of pipes, as well as violations of the continuity of the pipe metal and cracks associated with corrosion. Based on the results of such diagnostics, it is possible to accurately determine the location of the pipe defect and carry out a partial repair of the gas pipeline without complete re-insulation and replacement of the pipe.

There is a known method for detecting defects in gas pipeline pipes (RF patent No. 2211998, priority date 11/28/2001) not prepared for in-line inspection, in which the VIS is passed through the selected section of the gas pipeline through the temporary VIS launch and receive chambers connected to the existing gas pipeline. The VIS is passed through the launching and receiving chambers made of pipes, the connecting diameter of which corresponds to the nominal diameter of the gas pipeline, equipped with shut-off valves and gates and temporarily connected to the existing gas pipeline through the plug connections of the linear valves bordering the area to be inspected.

This method of detecting defects in gas pipeline pipes cannot be carried out on gas pipelines with sections with a diameter less than the main (nominal) diameter of the gas pipeline. The reason is that the VIS magnetic block has a constant diameter, structurally designed to ensure a minimum gap between the magnetic block and the inner wall of the pipeline. In addition, temporary nodes for receiving and launching in-line devices are designed to use the existing piping of linear valve nodes of gas pipelines, in this regard, there is no possibility of their use at other places of gas pipelines.

The closest to the claimed technical solution are a device and method for non-destructive testing of pipelines (patent for invention US 8146449 (B2), registration date 04/03/2012). According to this patent, the VIS design allows it to move along a gas pipeline with sections with different diameters. The design, similar to other VIS using the magnetic field control method, consists of a magnetic system with measuring sensors and cuffs for moving in a liquid or gas flow. Depending on the inner diameter of the pipeline section, the device allows you to change the radial position of the magnetic system with measuring sensors for flaw detection.

The disadvantage of this method is the high cost of equipment: the VIS is designed for flaw detection of pipelines with internal diameters from the range determined by the design and has complex mechanisms for changing the radial position of the magnetic system.

The technical problem solved by the proposed utility model is to ensure the delivery of VIS using temporary cameras to the inspected section of the gas pipeline through sections of the gas pipeline with a large diameter. It also solves the problem of ensuring the movement of the VIS through the valve assemblies having an inner diameter larger than the inspected gas pipeline, and movement inside the cavity of temporary chambers for launching and receiving the VIS, which have an inner diameter of the cavity larger than the inspected gas pipeline.

The task is solved by means of a device for the delivery of VIS to sections of the gas pipeline, the diameter of which is less than the main diameter of the gas pipeline. The device consists of a cylindrical body with at least one collar installed on it, at the ends of which there are guide rollers. In front of the cuff, equipped with rollers, a cuff of a smaller diameter is installed, made of an elastic material, which serves as a stabilizer for the position of the device when the device passes through a gas pipeline of a larger diameter and as a pulling one when passing through sections of a smaller diameter. In this case, the set of elements of the device is located outside the in-line inspection tool and is connected to it by means of a coupling mechanism.

The technical result of the utility model is the delivery of an in-line inspection tool-flaw detector when carrying out in-line flaw detection in the cavity of gas pipelines to areas with a smaller inner diameter than the main diameter of the gas pipeline.

The utility model is illustrated by drawings, where FIG. 1 shows the layout of the equipment coupler and its passage through the gas pipeline, FIG. 2 shows an embodiment of the device; FIG. 3 shows a variant of the device application using temporary chambers for launching and receiving in-line shells.

In the above figures, the following designations are adopted by numbers:

1 - device for VIS delivery;

2 - VIS;

3 - inspected section of the gas pipeline with a smaller diameter;

4 - sections of the gas pipeline with the main (nominal) diameter;

5 - pulling elastic cuffs;

6 - cylindrical body of the device for VIS delivery;

7 - coupling mechanism;

8 - roller wheels;

9 - temporary camera for launching VIS;

10 - temporary VIS reception chamber.

The device 1 for the delivery of VIS 2 to sections of the gas pipeline with a smaller diameter 3 than with the main (nominal) 4 is a pulling projectile. This device consists of pulling cuffs 5, made of elastic material, for example, polyurethane, mounted on a cylindrical body 6, and a coupling mechanism 7, made in a known manner, for example, by means of a hinge for connection with VIS 2. The rear cuff when moving inside the section of the gas pipeline with with a smaller diameter, it folds and contacts the walls of the pipeline by means of roller wheels 8 installed at its ends to reduce the friction force. The front collar is designed to ensure the movement of VIS 2 in a section of a gas pipeline with a smaller inner diameter 3 and as a stabilizer for the position of the device when passing sections with a large diameter.

The device operates as follows. On the selected section of the existing gas pipeline, which is not equipped with stationary launch and receive chambers for VIS, at the ends of the inspected section of the gas pipeline with a large (nominal) diameter 4, temporary launch and receive chambers 9 and 10 are mounted with a bypass gas pipeline through which the medium is transported through the gas pipeline. Through the open shutter of the temporary launch chamber 9, the pulling projectile 1 is launched to which the VIS 2 is attached using the coupling mechanism 7. The movement of the VIS 2 in the coupling with the pulling projectile 1 is carried out under pressure in the medium of the transported gas in the pipeline sections having different diameters. After passing the section with a large (nominal) diameter of the gas pipeline 4, the pulling projectile 1 with VIS 2 enters the narrowing of the inspected section, while the rear elastic cuff of a larger diameter is folded, and the movement is provided by the front cuff of a smaller diameter. When the hitch moves to reduce the friction force of the collar of a larger diameter against the walls of the inspected section of the gas pipeline 3, rollers 8 are installed in a known manner. In this case, the speed of the coupler of in-line devices 1 and 2 when approaching the place of narrowing 3 is ensured by setting the speed of the transported medium by setting the pressure drop in the section of the gas pipeline between the temporary chambers, in order to ensure the optimal speed of the VIS 2 within the section with a smaller diameter 3. Move the VIS 2 until the entire section planned for diagnosis has been passed. In the case when a gas pipeline section with a smaller diameter 3 is followed by a gas pipeline section with a large diameter 4, the flexible polyurethane collar 5 of the pulling shell 1 opens due to the elastic properties of the material, resting against the walls of the gas pipeline of a larger diameter, ensuring the movement of the coupling to the receiving chamber.

The use of the claimed utility model makes it possible to carry out in-line diagnostics of gas pipeline sections with a smaller inner diameter than the main one, while the installation of temporary nodes for receiving and launching VIS at the inspected section is impossible or irrational. Also, the utility model makes it possible to reduce the cost of assembling / dismantling temporary chambers at each section of a gas pipeline with a smaller diameter than the main one, if there are several such sections.

Claims (4)

1. A device for the delivery of in-line inspection shells to sections of the gas pipeline, the diameter of which is less than the main diameter of the gas pipeline, consisting of a cylindrical body with at least one collar installed on it, at the ends of which there are guide rollers, characterized in that the set of elements of the device is located outside the in-line inspection tool in connection with it by means of a coupling mechanism located at the end of the housing opposite to the direction of the device thrust, while at the other end of the housing in front of the cuff provided with rollers, a cuff of a smaller diameter is installed. 2. A device for delivering inline inspection shells to sections of a gas pipeline, the diameter of which is less than the main diameter of the gas pipeline, according to claim 1, characterized in that the collar of a smaller diameter is predominantly made of an elastic material, for example, of polyurethane. 3. A device for delivery of in-line inspection shells to sections of a gas pipeline, the diameter of which is less than the main diameter of a gas pipeline, according to claim 1 or 2, characterized in that a collar of a smaller diameter is made to ensure the movement of an in-line inspection tool in a section of a gas pipeline with a smaller internal diameter and position stabilizer when moving in a section of a gas pipeline with a larger diameter. 4. A device for delivering in-line inspection shells to sections of a gas pipeline, the diameter of which is less than the main diameter of the gas pipeline, according to claim 1, characterized in that the coupling mechanism is made in a known manner, for example, by means of a hinge.

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