RU58653U1 - PIPE PLUG - Google Patents

Abstract

The utility model is aimed at simplifying the technology of placing plugs in pipelines by reducing the size of the required technological holes for their entry into the internal volume of the pipeline. The plug for pipelines contains a sealed sheath of elastic material in the form of a cylindrical toroid, the internal volume of which is connected to a gas source through a flexible hose, and the inner hole of the cylindrical toroid is closed by a sealed elastic membrane. In special cases, the implementation of the elastic membrane can be fixed: on the end surfaces of the cylindrical toroid facing the incoming flow of fluid; on the end surfaces of a cylindrical toroid, rear with respect to the incoming flow of the pipeline fluid; along the plane of symmetry of a cylindrical toroid perpendicular to its axis of rotation. In addition, a sealed elastic membrane can be connected to a means of removal of the remaining fluid of the pipeline, which is made in the form of a rigid or elastic L-shaped pipe, the inlet of which through the elastic membrane is connected to the volume of the incoming fluid flow, and the outer surface of the cylindrical toroid is provided with at least two sealing cuffs located symmetrically with respect to the plane of symmetry of the cylindrical toroid perpendicular to its axis of rotation. 9 dependent items, 4 ill.

Description

The utility model relates to construction and is used during emergency recovery and repair work on gas pipelines and oil pipelines under excessive pressure.

From the prior art it is known that when carrying out repairs related to welding on the pipeline, there is a danger of fire or explosion of the gas-air mixture. To prevent this, the repair zone is isolated by the installation from two sides along its borders in the pipeline of sealing devices. When carrying out emergency repairs and repairs on pipelines, various designs of rubber and rubber cord sealing pneumatic devices are used.

A device is known, made in the form of a “ball plug” for sealing the internal cavity of a gas pipeline (see SU 1219859 A, 03/23/1986 [1]). To increase the safety of welding operations on the existing gas pipeline, to eliminate the explosion of the gas-air mixture in the repair work area, plugs are installed on both sides of the pipeline — elastic sealed chambers, each of which is filled with air through the hose. When air is injected into the chamber, the plug takes the form of a ball and closes the internal cavity of the pipeline, isolating the zone of welding work inside the pipeline. As you know, overpressure in the existing pipeline before the plug has the last pushing effect and, under certain circumstances, leads to a shift of the plug from the place of its installation. A disadvantage of the known device is its low reliability, since with possible shifts of the elastic rubber chamber from the place of installation, the possibility of damage is not excluded, as a result of which the air pressure in the plug chamber drops, gas from the pipeline enters the welding zone, which will lead to gas-air mixture explosion, resulting in injuries to working personnel, the occurrence of defects in welds.

A device is known as a “plug for pipelines” (see SU 932085 A, 05/30/1982 [2]). The known device comprises a rigid cylindrical body with flanges between which an elastic annular chamber is placed. The latter is equipped with a fitting for connection to a line connected to a pressure source. The inlet and outlet openings are made in the end walls of the hollow body. The outlet is connected to an overflow pipe. The plug is placed in the internal cavity of the pipeline and the supply of medium under pressure increases the outer diameter of the elastic chamber, while the plug is fixed in the pipeline. The outer end of the overflow pipe is connected to the discharge line. The liquid medium in the pipeline with suspensions through the inlet enters the internal cavity of the housing and is discharged through the overflow pipe, and particles suspended in the liquid medium settle in the hollow housing. A disadvantage of the known solution is the presence of a rigid housing, the size of which is limited by the permissible dimensions of the technological window in the pipeline through which the device is introduced into the blocked trunk. In addition, there is no control over the excess pressure in front of the plug and there is no possibility of its regulation, which can lead to extrusion of the plug by the medium pumped through the pipeline, damage to the elastic chamber.

Closest to the claimed object in its technical essence and the achieved result is a shell for a device for blocking a sewer pipe (RU 2042077 [3]). The known technical solution comprises a shell, a sealed toroidal chamber made of rubber provided with a nipple, covering a power cage chamber made of layers of rubberized cord threads, and a rubber cover layer placed on a power cage, provided with a metal ring that is located on the power cage on the inner cylinder-shaped part of the casing and coaxially with her. The metal ring can be connected to the side wall of the shell, in addition, it can contain a channel for accommodating the nipple, have blind holes with threads, can have attached rods.

A disadvantage of the known technical solution is the presence of rigid elements not subject to deformation (metal rings), which

does not allow to introduce a device for blocking the pipeline into relatively small technological holes cut through its walls.

Declared as a utility model, the device is aimed at simplifying the technology of placing plugs in pipelines by reducing the size of the required technological holes for their entry into the internal volume of the pipeline.

This result is achieved by the fact that the plug for pipelines contains a sealed sheath of elastic material in the form of a cylindrical toroid (torus), the internal volume of which is connected to a gas source through a flexible hose, and the inner hole of the cylindrical toroid is closed by a sealed elastic membrane.

The indicated result is also achieved by the fact that the membrane is fixed on the end surfaces of the torus (cylindrical toroid) facing the incoming flow of the pipeline fluid.

The indicated result is also achieved by the fact that the membrane is fixed on the end surfaces of the cylindrical toroid (torus), rear with respect to the incident flow of the pipeline fluid.

The indicated result is also achieved by the fact that the membrane is fixed along the plane of symmetry of the cylindrical toroid perpendicular to its axis of rotation.

The indicated result is also achieved by the fact that the sealed elastic membrane is connected to a means for removing residual fluid of the pipeline, which is made in the form of a rigid or elastic pipe, the inlet of which through the elastic membrane is connected to the volume of the incoming fluid flow.

The specified result is also achieved by the fact that a rigid or elastic pipe is made in the form of a L-shaped pipe.

The specified result is also achieved by the fact that the membrane is made of a gas-tight oil-gas-resistant material.

This result is also achieved by the fact that the outer surface of the cylindrical toroid is equipped with at least one sealing collar.

The specified result is also achieved by the fact that the sealing sleeve is made of an elastic elastomeric material.

The indicated result is also achieved by the fact that the outer surface of the cylindrical toroid is provided with at least two sealing cuffs located symmetrically with respect to the plane of symmetry of the cylindrical toroid perpendicular to its axis of rotation.

The implementation of the plugs for pipelines in the form of a cylindrical toroid, the inner hole of which is blocked by a sealed elastic membrane, can significantly reduce the size of the technological holes made in the pipeline, since the absence of rigid assemblies and parts in the plug makes it easy to change (minimize) its volume.

In special cases, the implementation of the elastic membrane can be fixed: on the end surfaces of the cylindrical toroid facing the incoming flow of fluid; on the end surfaces of a cylindrical toroid, rear with respect to the incoming flow of the pipeline fluid; along the plane of symmetry of a cylindrical toroid perpendicular to its axis of rotation. All of these implementation options can be used depending on the technological capabilities of the manufacture of the plug or the conditions of its operation.

The implementation of a sealed elastic membrane connected to a means of removal of the remaining fluid of the pipeline, which is made in the form of a rigid or elastic pipe, the inlet of which through the elastic membrane is connected to the volume of the incoming fluid flow in order to ensure that in the absence of the possibility of blocking the pipeline or after its closure removal of fluid residues that impede the repair work.

It seems most appropriate that the means for removing fluid residues from the pipeline will be made in the form of a rigid or elastic L-shaped pipe, since in this case the most optimal preservation of the mechanical parameters of the means for removing the fluid is ensured and its entry into the process hole is simplified.

The implementation of the membrane from a gas-tight oil-gas-resistant material provides a wide range of uses for the plug, as it allows its use in pipelines through which gas, oil or oil products are transported.

The supply of the outer surface of the cylindrical toroid with at least one sealing collar provides a more reliable sealing of the pipeline at its overlap. In this case, it is advisable that the sealing collar was made of an elastic elastomeric material, since in this case the most reliable sealing of the pipeline section.

Moreover, as practice shows, the presence of one cuff in some cases, for example, with increased residual pressure in the pipeline, is not enough to reliably overlap the cross section of the pipeline. Therefore, in particular cases of implementation, it is advisable that the outer surface of the cylindrical toroid be provided with at least two sealing lips located symmetrically with respect to the plane of symmetry of the cylindrical toroid perpendicular to its axis of rotation. This allows you to increase the mechanical stability of the plug in the presence of increased fluid pressure acting on it.

The essence of the claimed utility model is illustrated by examples of its implementation and drawings. Figure 1 schematically shows a longitudinal section of a pipeline with a plug in it in the form of a cylindrical toroid, when the membrane is mounted on the end surfaces of the cylindrical toroid facing the oncoming fluid flow; Figures 2 and 3 show schematically embodiments of a plug placed in a pipeline when the membrane is fixed on the end surfaces of a cylindrical toroid that are rear with respect to the incident fluid flow and along the plane of symmetry of the cylindrical toroid perpendicular to its rotation axis; figure 4 presents the most optimal embodiment of the plug placed in the pipeline when it is equipped with a means for removing fluid residues and several sealing cuffs.

Example 1. The plug for pipelines contains a sealed shell 1 of elastic material in the form of a cylindrical toroid (torus), the inner volume 2 of which is connected through a flexible hose 3 to a gas source (not shown), and the inner hole of the cylindrical toroid is closed by a sealed elastic membrane 4 The stub is used as follows. In the pipeline 5, in which it is necessary to carry out appropriate repair work, a technological hole is cut

6, through which the plug is assembled, is placed in the pipeline and through the flexible hose 3, air or inert gas is supplied into it under pressure. The flexible hose is equipped with a manometer for measuring pressure and means for blocking the channel through which gas is supplied (not shown in the drawings).

Embodiments of the stub shown in FIGS. 2 and 3 are used similarly.

Example 2. The plug for pipelines contains a sealed shell 1 of elastic material in the form of a cylindrical toroid, the inner volume 2 of which is connected through a flexible hose 3 to a gas source (not shown), and the inner hole of the cylindrical toroid is closed by a sealed elastic membrane 4. Sealed elastic the membrane 4 is connected to the means for removing residual fluid of the pipeline 7, which is made in the form of a rigid or elastic pipe, the inlet of which is connected through an elastic membrane to the volume of the flowing fluid. As the material of the pipe, a structural material can be used that satisfies the conditions of corrosion resistance to the fluid. The pipe is connected to the elastic membrane hermetically using any known means of sealing (flanges, cuffs, gaskets, adhesive bonding, etc.). The outer surface of the cylindrical toroid is provided with one or more sealing cuffs 8, which are placed on the outer surface of the cylindrical toroid and provide the most complete sealing between the surface of the cylindrical toroid and the walls of the pipeline. In this case, the cuffs 8 can be made integral with the sealed shell or made separately and fixed on the outer surface of the cylindrical toroid or can be placed in the pipeline, and then the outer surface of the cylindrical toroid is brought into contact with them already inside the pipeline at the place of installation of the plug. The means for draining the fluid to ensure appropriate operating conditions can be equipped with manometers, taps, pumps that allow you to remove (pump out) and direct the fluid for disposal or in tanks (not shown in the drawings).

The stub is used as follows. In the pipeline 5, in which it is necessary to carry out the appropriate repair work, a technological hole 6 is cut through which the plug in the assembled form is placed in the pipeline and through the flexible hose 3 air or inert gas is supplied into it under pressure. The flexible hose is equipped with a manometer for measuring pressure and means for blocking the channel through which gas is supplied (not shown in the drawings). After installing the plugs, the presence of fluid residues in the pipeline 5 is checked, which are removed through the means 7 for their removal (removal).

Claims (10)

1. A plug for pipelines containing a sealed sheath of elastic material in the form of a cylindrical toroid, the internal volume of which is connected through a flexible hose to a gas source, and the inner hole of the cylindrical toroid is closed by a sealed elastic membrane. 2. The plug according to claim 1, characterized in that the membrane is mounted on the end surfaces of the cylindrical toroid facing the incoming flow of the pipeline fluid. 3. The plug according to claim 1, characterized in that the membrane is mounted on the end surfaces of the cylindrical toroid, rear with respect to the incoming flow of the pipeline fluid. 4. The plug according to claim 1, characterized in that the membrane is fixed along the plane of symmetry of the cylindrical toroid perpendicular to its axis of rotation. 5. The plug according to claim 1, characterized in that the sealed elastic membrane is connected to a means for removing residual fluid of the pipeline, which is made in the form of a rigid or elastic pipe, the inlet of which through the elastic membrane is connected to the volume of the incoming fluid flow. 6. The plug according to claim 5, characterized in that the rigid or elastic pipe is made in the form of a L-shaped pipe. 7. The plug according to claim 1, characterized in that the membrane is made of a gas-tight oil-gas-resistant material. 8. The plug according to claim 1, characterized in that the outer surface of the cylindrical toroid is provided with at least one sealing collar. 9. The plug of claim 8, wherein the sealing sleeve is made of an elastic elastomeric material. 10. The plug according to claim 8, characterized in that the outer surface of the cylindrical toroid is provided with at least two sealing lips located symmetrically with respect to the plane of symmetry of the cylindrical toroid perpendicular to its axis of rotation.