RU116960U1 - ELASTIC ENCLOSURE FOR SEALING PIPELINES - Google Patents

Abstract

1. An elastic shell for a hermetically sealed pipeline, containing a cylindrical and two end parts and a fitting for supplying compressed air, while a group of sealing annular protrusions is made on the outer surface of the cylindrical part, characterized in that a separate annular protrusion is made on the outer surface, spaced from the extreme the protrusion of the group by a distance greater than the distance between the protrusions of the group, and having a height greater than the height of the protrusions of the group. ! 2. Elastic shell according to claim 1, characterized in that each annular protrusion of the group has a cross-section in the form of an isosceles triangle. ! 3. Elastic shell according to claim 1, characterized in that the separate annular protrusion has a triangular or trapezoidal section, the sides of which, facing the end part of the shell and the group of annular protrusions, are located at angles to the radius of the cylindrical part of the shell α and β, respectively , with α <β. ! 4. Elastic shell according to claim 2, characterized in that the angle γ is selected from 50 ° to 90 °. ! 5. An elastic casing according to claim 3, characterized in that the angle α is selected from 5 ° to 15 °, and the angle β is from 30 ° to 50 °.

Description

The utility model relates to pipeline transport and can be used to shut off oil pipelines and oil product pipelines.

At present, sealants and pneumatic plugs are used, which are a closed cylindrical rubber-cord shell with a valve for connecting to a source of compressed air.

Known elastic shell for tight shutoff of the pipeline, containing a cylindrical and two end parts, a fitting of the shell and a pneumatic pipe for pumping with compressed air connected to the fitting (see RF patent No. 102742, publ. 10.03.2011).

The closest analogue to the proposed utility model is an elastic shell for tight shutoff of the pipeline, containing a cylindrical and two end parts, a fitting for supplying compressed air, while on the outer surface of the cylindrical part a group of sealing ring protrusions is made (see RF patent No. 90526, publ. 01/10/2010).

A disadvantage of the known technical solution is incomplete sealing of relatively large irregularities on the inner surface of the pipeline — welds, shells and growths, the dimensions of which are comparable with the height of the sealing protrusions. This is especially true when bumps cross several sealing tabs in a row.

Due to the fact that the annular grooves are made between the protrusions imperfectly (within the tolerance) in diameter, defects in the mold material, shrinkage of the rubber after vulcanization, and also the operating conditions of the sealant itself, the height difference of the sealing protrusions along the axis of the pipe can reach 1.5 mm, which, when the sealing protrusions are equal to 2-3 mm and the height of the weld up to 4 mm, creates the possibility of local lack of sealing and, accordingly, breakthrough of combustible gases or liquids in the area of repair of the pipeline, leading to an emergency.

In addition, in case of non-tight overlap of the inner cavity of the pipe, the medium to be blocked penetrates into the space between the sealing protrusions and the inner surface of the pipe, which leads to a decrease in the degree of deformation of the protrusions due to the pressed wall of the shell from the inner wall of the pipe, a decrease in the friction force between the shell and the pipe , to a decrease in the pressure of the overlapping medium that the shell can hold.

A decrease in the friction force leads to a shear shift to the area of repair work. A decrease in the degree of deformation leads to depressurization of the damping device and a breakthrough of the damped medium and its vapors into the area of repair work. Both factors are fraught with emergency.

The objective of the utility model is to prevent the penetration of the transported liquid and its vapors into the area of repair, welding and other fire and construction works.

The technical result of the claimed utility model is to improve the quality of sealing of relatively large irregularities on the inner surface of the pipeline.

The technical result of the utility model is achieved due to the fact that the elastic shell for tight shutoff of the pipeline containing a cylindrical and two end parts and a fitting for supplying compressed air, while on the outer surface of the cylindrical part a group of sealing ring protrusions is made, while, according to the change, the outer surface of the elastic shell has a separate annular protrusion, spaced from the extreme protrusion of the group at a distance greater than the distance between the protrusions of the group, and having height exceeding the height of the projections of the group.

Preferably, each annular protrusion of the group has an isosceles triangle section, and a separate annular protrusion has a section in the form of a triangle or trapezoid, the sides of which facing the end part of the shell and the group of ring protrusions are angled to the radius of the cylindrical part of the shell α and β respectively, with α <β.

It is preferable to choose the angle y from 50 ° to 90 °, the angle α from 5 ° to 15 °, the angle β from 30 ° to 50 °.

The essence of the utility model is illustrated by drawings, where:

figure 1 - shows a well-known elastic shell, front view;

figure 2 - shows the proposed elastic shell, front view;

figure 3 - shows a fragment of the proposed elastic shell (view A in figure 2);

figure 4 - shows the proposed elastic shell installed in the pipeline, front view;

figure 5 - shows a fragment of the proposed elastic shell with sealing protrusions after its deformation in the pipeline (type B in figure 5);

figure 6 shows a fragment of the cross section of the shell at the place of sealing of the weld seam spaced annular protrusion.

The proposed elastic shell for tight shutoff of the pipeline contains a cylindrical part 1 and two end parts 2, 3, one of which is attached to the shank 4 of the coupling device. The fitting for supplying compressed air is not shown in the drawing.

On the outer surface of the cylindrical part 1 of the shell, a seal is made in the form of a group of sealing annular protrusions 5 of a triangular section. Also on the outer surface of the cylindrical part 1 of the shell there is a separate annular protrusion 6 located closer than the group of protrusions 5 to the end part, spaced from the extreme protrusion 5 of the group by a distance greater than the distance between the protrusions 5 of the group, and having a height exceeding the height of the protrusions 5 groups (see figure 3).

The shell is installed in such a way that the end part 2, closer to which there is a separate protrusion 6, is subjected to the pressure of the transported medium.

In the drawings are indicated:

figure 1, 2:

L _ref. - the length of the shell in the initial state;

L _cont. - the length of the contact spot of the shell with the inner surface of the pipe;

L _rep. - the length of the zone of the annular sealing protrusions 5;

D _ref. - the initial diameter of the elastic shell;

figure 3:

α is the distance between the protrusions in the group of sealing protrusions 5;

β is the distance between the separate sealing protrusion 6 and the first sealing protrusion 5 in the group;

l ₁ - the length of the pressure zone of compressed air in the shell on one sealing protrusion 5 in the group;

l ₂ - the length of the pressure zone of compressed air in the shell on a separate sealing lug 6;

H ₁ - the initial height of the sealing protrusion 5 in the group of protrusions;

H ₂ - the initial height of the individual sealing ledge 6;

figure 4:

L _cont. - the length of the contact spot of the shell with the inner surface of the pipe;

P _environment - the pressure of the medium on the elastic shell;

P _slave. - working pressure in the elastic shell;

D _pa6. - working diameter of the elastic shell;

d _pipe - the inner diameter of the pipeline 7;

figure 5:

l ₁ - the length of the pressure zone of compressed air in the shell on one sealing protrusion 5 in the group;

l ₂ - the length of the pressure zone of compressed air in the shell on a separate sealing lug 6;

h ₁ - the height of the sealing protrusion 5 in the group after deformation;

h ₂ - the height of the individual sealing protrusion 6 after deformation (plug in working condition);

Δh ₁ - the amount of deformation of the sealing protrusion in the group of protrusions;

Δh ₂ - the amount of deformation of a separate sealing protrusion;

figure 6:

h _stitch - the height of the weld;

h _Walmax - the maximum height of the individual sealing protrusion 6 after deformation in the weld zone.

The elastic shell works as follows.

An elastic sheath for tight shutoff of the pipeline 7 is moved along the pipeline 7 with the help of the coupling device 4 to the place of repair. An angled fitting (not shown in the drawing) is fixed in the hole made in the upper part of the wall of the pipeline 7, and compressed air is pumped into the shell through the pneumatic pipeline. The shell is inflated, adjoins its cylindrical part 1 to the wall of the pipeline 7 and hermetically closes the internal cavity of the pipeline 7.

The sealing of relatively large irregularities on the inner surface of the pipeline 7 — welds, sinks and growths — is provided by a separate annular protrusion 6, the first on the side of the transported medium, spaced a distance greater than the distance between the protrusions of group 5 and having a height exceeding the height of the protrusions of group 5.

Since a separate annular protrusion 6 is spaced from the extreme protrusion 5 by a distance 6 greater than the distance a between the protrusions 5, the length l _{2 of} the compressed air pressure zone in the shell by a separate sealing protrusion 6 exceeds the length l _{1 of} the compressed air pressure zone in the shell by one sealing projection 5 in this group can significantly increase the area of the wall of the sheath along the length l ₂ of the transmitting _slave pressure P of the compressed air into the sheath and, respectively, a pressure force on this separate projection 6, which leads to an increase in the degree of deformation ation Δh ₂ sealing strip 6 with sufficient rigidity shell wall thickness commensurate with the height H ₂ of a detached annular projection 6, and ensures reliable overlapping and sealing the recess zone located between the surface of the weld and the inner cylindrical surface of the pipe (see FIG. 6) .

This also applies to pipe defects in the form of growths or shells.

Preferably, each annular protrusion 5 of the group has a cross section in the form of an isosceles triangle, and a separate annular protrusion 6 has a cross section in the form of a triangle or trapezoid, the sides of which facing the end part of the shell and the group of ring protrusions 5 are angled to the radius of the cylindrical part 1 of the shell α and β, respectively, with α <β.

The angle γ at the apex of the isosceles triangle, the shape of which preferably has a cross section of each annular protrusion 5, is preferably selected from 50 ° to 90 °, angle α is from 5 ° to 15 °, angle β is from 30 ° to 50 °.

Preferably, the separate annular protrusion 6 has a section in the shape of a triangle or trapezoid. This geometry of the protrusion 6 allows you to additionally withstand the pressure P of the _{medium of the} transported fluid on the elastic shell, the penetration of the transported fluid and its vapors into the area of repair, welding and other firing construction work, which improves the quality of sealing relatively large irregularities on the inner surface of the pipeline 7.

Claims (5)

1. An elastic shell for tightly shutting off the pipeline, containing a cylindrical and two end parts and a fitting for supplying compressed air, while on the outer surface of the cylindrical part a group of sealing annular protrusions is made, characterized in that a separate annular protrusion is made on the outer surface, spaced from the extreme the protrusions of the group at a distance greater than the distance between the protrusions of the group, and having a height exceeding the height of the protrusions of the group. 2. The elastic shell according to claim 1, characterized in that each annular protrusion of the group has a cross section in the form of an isosceles triangle. 3. The elastic shell according to claim 1, characterized in that the separate annular protrusion has a section in the form of a triangle or trapezoid, the sides of which, facing the end part of the shell and the group of annular protrusions, are located at angles to the radius of the cylindrical part of the shell α and β, respectively , while α <β. 4. The elastic shell according to claim 2, characterized in that the angle γ is selected from 50 ° to 90 °. 5. The elastic shell according to claim 3, characterized in that the angle α is selected from 5 ° to 15 °, and the angle β is from 30 ° to 50 °.