RU2418231C1 - Elastic casing for pressure tight pipeline shutdown - Google Patents

Abstract

FIELD: machine building.

SUBSTANCE: elastic casing consists of cylinder and two end parts, of connecting part and of air tube for compressed air pumping. The air tube is coupled with the connecting pipe by an angular connecting pipe. At its free end it is equipped with the second angular connecting pipe for fixation in an orifice of the pipeline wall. The connecting pipe is arranged on an internal side of an arc-shaped or circular groove, preferably of "П"-form section. The groove is formed with the wall of a cylinder part of the casing and is designed for air tube placement. Additionally, labyrinth packing in form of circular lugs of triangular section is made on external surface of the cylinder part of the casing.

EFFECT: increased safety factor of casing, reliability of pipeline internal cavity sealing, raised fire safety at repair and fire operations.

Description

The invention relates to pipeline transport and can be used to shut off oil pipelines and oil pipelines.

In oil pipelines, in order to exclude the effects of the effects of hot work on the pneumatic pipe supplying compressed air to the shell, the pneumatic pipe is located in the middle of the cylindrical part of the shell around the circumference in the zone of contact between the shell and the pipe.

Known for use in pipelines is an elastic sheath for tightly shutting off a pipeline, comprising a cylindrical and two end parts, a fitting located on a cylindrical surface or in a sample on a cylindrical part, and a hose for pumping with compressed air connected to the fitting and having an angled fitting at the free end for fixing in the hole of the pipeline (RU 2297571 C2, publ. 10.10.2006).

During inflation, the shell touches the inner wall of the pipeline in the middle of the cylindrical part of the shell, where the fitting and hose for pumping the shell are located.

The shell fitting is attached to the shell using a disk, the diameter of which is determined by the dimensions of the shell and cannot be less than a certain size to ensure reliable fastening in the shell.

Since in the known device the fitting is installed on the outside of the cylindrical part of the shell, then the rubberized disk of the fitting, having a certain diameter and thickness of the metal layer and the rubber layer, is located outside the shell.

In addition, when placing the fitting in the sample in the cover rubber of the shell, the hole in the fitting for attaching the hose is made perpendicular to the axis of the fitting and has its own dimensions and dimensions of the nozzle wall, which are located above the nozzle disk and protrude beyond the cylindrical surface of the shell.

Therefore, in order to place the fitting completely inside the sample in the rubber coating layer, it is necessary that the thickness of the rubber coating layer at the fitting location is at least 18 mm, and the total shell thickness at the fitting location is at least 30 mm.

Thus, in the known device, the fitting is surrounded by an array of rubber with a thickness four times the thickness of the remaining cylindrical part of the shell, and when the shell is inflated due to the stiffness of the thickened part of the wall, only the main thin wall of the shell is stretched. At the same time, in the places where the shell wall transitions to the thickened part of the array, stress concentration arises in individual threads of the power frame, causing a decrease in the shell strength.

On the currently used shells for sealing oil pipelines, the cylindrical part of the shell in the initial state has a diameter 1.5 times smaller than the inner diameter of the pipeline itself and, accordingly, greater than the curvature of the pipe. When the shell is inflated, its curvature approaches the curvature of the pipe. However, the curvature of the thickened array of the section of the shell in the area of the fitting changes slightly due to its rigidity and when in contact with the pipe exceeds the curvature of the pipe, which causes the non-adherence of part of the shell to the wall of the pipe and the formation of gaps between the shell and the pipe, and, accordingly, the lack of sealing of the pipeline. Through these openings, penetration of combustible gases from the cavity of the pipeline into the area of conducting hot repair work is possible.

In addition, in the known solution, the hose and the corner fitting are between the shell and the inner surface of the pipe, which also causes non-adherence of the cylindrical part of the shell to the pipe and, accordingly, the formation of gaps. In order to achieve complete sealing of the pipeline and remove all the gaps that have arisen, it is necessary to significantly increase the internal pressure of compressed air in the shell, which will obviously reduce the margin of safety of the product and, accordingly, its reliability.

In the case when an array in the area of the fitting or a hose with an angled fitting falls on the weld of the pipeline, the tightness of the overlap can be ensured only by the remaining part of the cylindrical part of the shell in contact with the pipe, the length of which, due to the large size of the rubber array, is about half the length of the contact spot separating the cavity of the pipeline and the repair zone, and this, in turn, can lead to depressurization of the ceiling and the breakthrough of combustible gases in the zone of fire work.

The technical result of the claimed invention is to eliminate these drawbacks, namely, increasing the margin of safety of the shell and the reliability of sealing the internal cavity of the pipeline, as well as increasing the fire safety of ongoing firing and welding operations.

To achieve the technical result, the shell fitting is mounted on the inside of the arcuate or annular groove, preferably a U-shaped section formed from a cylindrical portion of the shell wall. The shell fitting is made without the outer part, which was replaced by an angular fitting of the pneumatic pipe, which consists of two corner fittings and a sleeve. The pneumatic pipe is located in whole or in part in an arcuate or annular groove, where one of the corner fittings is hermetically fixed in the shell fitting and the other in the pipe wall.

Thus, in an elastic shell for tightly shutting off a pipeline containing a cylindrical and two end parts, a shell fitting and a pneumatic pipe for pumping with compressed air, connected to the shell fitting and having an angled fitting at the free end for fixing in the hole of the pipe wall, according to the invention, the shell fitting is installed on the inner side of an arcuate or annular groove, preferably having a U-shaped section, formed from the wall of the cylindrical part of the shell and intended hydrochloric accommodation of pneumatic, which is connected to the casing nipple by a second corner fitting.

In addition, on the outer surface of the cylindrical part of the shell on both sides of the groove, labyrinth seals in the form of annular protrusions of a triangular section can be made to seal the pipe weld.

Figure 1 shows the proposed elastic shell, front view.

Figure 2 is a section along aa in figure 1.

Figure 3 is a section bB in figure 2.

Figure 4 is a section bb in figure 3.

The elastic shell for tight shutoff of the pipeline contains a cylindrical part 1 and two end parts 2, 3, on one of which a shank 5 of the coupling device is fixed. The sleeve 4 of the shell is installed on the inner side of the arcuate or annular groove 9 of the U-shaped section, formed by the wall of the shell on its cylindrical part 1, either along the circumference (the groove 9 has an arcuate shape in longitudinal section), or around the entire circumference (the groove 9 has closed ring shape). In contrast to the sample in the cover rubber, with the shape of the force frame in the known device being unchanged, the groove 9 is formed by molding the wall of the shell itself inward and is a continuation of the cylindrical part of the shell. The groove may also have a cross section of a different shape, for example, with inclined side walls.

The nozzle of the casing 4 is made without the outer part, which was replaced by the corner fitting 7 of the pneumatic pipe, consisting of two corner fittings 7 and 8 and the sleeve 6. The pneumatic pipe is located completely or partially in the groove 9, where the corner pipe 7 is hermetically fixed in the pipe connector 4, and the corner pipe 8 is fixed in the hole made in the upper part of the pipeline wall.

On the outer surface of the cylindrical part 1 of the shell, labyrinth seals are made in the form of annular protrusions of a triangular section located on both sides of the annular groove 9. The labyrinth seals further increase the reliability of sealing the internal cavity of the pipeline having a weld.

The elastic shell works as follows.

The elastic shell is moved along the pipeline using the coupling device 5 to the repair site. The corner fitting 8 is fixed in the hole made in the upper part of the pipe wall, and compressed air is pumped into the shell through the pneumatic pipe. The shell is inflated, adjoins its cylindrical part 1 to the wall of the pipeline and hermetically closes the internal cavity of the pipeline. In this case, the sleeve 6 and the fittings 7 and 8 of the pneumatic pipe are placed in an arcuate or annular groove 9 bounded by the side walls and do not prevent the remaining surface of the cylindrical part 1 from contacting the pipeline, which ensures reliable sealing and sealing of the internal cavity of the pipeline.

The proposed design has the following advantages over the known:

1) an increase in the strength of the shell due to the absence on the cylindrical part at the installation site of the fitting of multiple thickening of the shell wall and, accordingly, the concentration of stresses in the threads of the shell shell;

2) an increase in the safety margin of the power shell of the shell by reducing the necessary air pressure in the shell by the amount required to eliminate the gaps between the shell and the pipe caused by the stiffness of the rubber array at the installation location of the shell fitting;

3) an increase in the reliability of sealing the internal cavity of the pipeline by increasing the area of the contact spot of the shell with the inner surface of the pipeline, caused by the transfer of the sleeve of the pneumatic pipe and the angle fitting to the outer surface of the shell in the annular groove;

4) increasing the fire safety of hot work due to the above advantages.

Claims (3)

1. An elastic sheath for hermetically shutting off a pipeline, comprising a cylindrical and two end parts, a sheath fitting and a pneumatic pipe for pumping with compressed air, connected to the nozzle and having an angled fitting at the free end for fixing in the hole of the pipe wall, characterized in that the sheath fitting is mounted on the inner side of the arcuate or annular grooves formed by the wall of the cylindrical part of the shell and designed to accommodate a pneumatic pipe that is connected to the nozzle ki by a second corner fitting. 2. The shell according to claim 1, characterized in that on the outer surface of the cylindrical part of the shell on both sides of the grooves are made labyrinth seals in the form of annular protrusions of a triangular section. 3. The shell according to claim 1, characterized in that said groove has a U-shaped cross-section.

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