RU139642U1 - COATING FROM HEAT-INSULATING SCORLUPS - Google Patents

Abstract

1. A coating for waterproofing pipelines, including a set of heat-insulating shells, characterized in that at least one groove is made on the inner side of the shells, directed across the main direction of the pipe. 2. The coating according to claim 1, characterized in that in front of each groove there is at least one channel inside at least one shell connecting the groove with the outer surface of the shell. The coating according to claim 1, characterized in that the shell is made of polyurethane foam. The coating according to claim 1, characterized in that it is equipped with axial and radial heat locks made in the form of displacements in the axial direction by the length L and relative to the axis by an angle. The coating according to claim 1, characterized in that a waterproofing layer made of polymer is applied to the outer surface of the heat-insulating layer, and a decorative and protective coating is applied to the waterproofing layer.

Description

The utility model relates to thermo-waterproofing coatings made of shells and can be used for thermo-waterproofing of pipelines.

The well-known "Method for installing a shell for pipelines" US 5,079,824 [1], including installing the shell on the outer surface of the pipe and installing a siphon for condensate outlet, and the siphon is made in the form of a tube between the inner space and the outer surface of the shell (fig 8).

The disadvantages of the known design are the complexity of installation and the high cost of manufacture due to the installation of a metal shell, as well as the need for special equipment for mounting the shell. Another disadvantage is the low heat-insulating ability of the known shell.

Closest to the claimed technical solution is “THERMAL WATERPROOFING SCORLUP” RU PM 25297 [2], including a heat-insulating layer, characterized in that the heat-insulating layer is made of polyurethane foam in the form of a cut along the pipe, equipped with axial and radial heat locks made in the form of displacements in the axial direction on the length L and relative to the axis at an angle, a waterproofing layer made of polymer is applied to the outer surface of the heat-insulating layer, and paint and varnish is applied to the waterproofing layer orativno protective coating.

The known design allows to simplify the installation and reduce the complexity of installation while increasing the insulating ability.

A disadvantage of the known design is the lack of the ability to remove condensate, leading to a decrease in the service life of the coating and pipe, as well as to a decrease in the heat-insulating ability.

The technical result of the proposed utility model is to increase the service life of the coating and pipe, as well as increase the heat-insulating ability.

The technical result is achieved in that the coating, including a set of heat-insulating shells, is characterized by the fact that at least one (radial) groove (recess, groove, groove) is made on the inner side of the shell, directed across the main direction of the pipe.

Opposite each recess groove, there is at least one channel (hole) inside at least one shell connecting the groove with the outer surface of the shell. A hole opposite each groove will increase the rate of condensate removal from the space adjacent to the pipe.

The shells can be made of polyurethane foam. Polyurethane foam has high thermal insulation and sufficient mechanical properties for the production of heat-insulating coating of pipelines.

The coating can be equipped with axial and radial heat locks, made in the form of displacements in the axial direction by the length L and relative to the axis by an angle. Heat locks will increase the tightness of the coating.

A waterproofing layer made of polymer may be applied to the outer surface of the heat-insulating layer, and a decorative paint and varnish coating may be applied to the waterproofing layer. The presence of a waterproofing layer will increase the durability of the coating by reducing the damaging effects of atmospheric and other precipitation on the coating. The presence of the coating will increase the durability of the coating by reducing the impact of direct solar and other radiation on the coating.

Figure 1 shows a transverse section of the shell, figure 2 shows the inner side of the shell, figure 3 shows the inner side of the shell with channels, figure 4 shows a section of the cover assembly, made using PP. 1, 2, 4 and 5, where:

1 - shell;

2 - the inner side of the shell;

3 - grooves;

4 - the outer side of the shell;

Channel 5;

6 - heat locks.

The device operates as follows: Shell 1 is mounted with the inner side 2 on a pipe (not shown). In this case, the grooves 3 lie in the outer surface of the pipe. Since the shells are made identical, when properly installed, the grooves of adjacent shells are connected. During the formation of condensate, the condensate collects in the groove 3 and through the gap between the lower part of the shell, formed by the loose fit of the shell to the pipeline or through the channel 5 enters the outer side of the shell 4, where it is scattered into the environment. Preferably, the channels in the form of holes are located on the lower side (lower shells) of the coating. Holes can be produced on site, after partial or complete installation of the coating. Heat locks 6 are used to increase thermal insulation due to the extension of the heat path at the joints between the shells. A waterproofing layer and a decorative paint and varnish coating serve to protect against external influences on the coating.

The technical result is an increase in the service life of the coating is achieved by the fact that when removing condensate from the inner space of the coating, the rate of destruction of the coating material is reduced.

EFFECT: increased pipe service life is achieved by the fact that when the condensate is removed from the pipe surface, the corrosion intensity of the external surface of the pipe is reduced.

The technical result is an increase in heat-insulating ability is achieved by the fact that when the condensate is removed, a drier coating has a greater heat-insulating ability.

Industrial application The utility model can be used in the production of pipe coatings from insulating shells.

Claims (5)

1. A coating for waterproofing pipelines, including a set of heat-insulating shells, characterized in that at least one groove is made on the inner side of the shells, directed across the main direction of the pipe. 2. The coating according to claim 1, characterized in that opposite each groove is at least one channel inside at least one shell connecting the groove with the outer surface of the shell. 3. The coating according to claim 1, characterized in that the shell is made of polyurethane foam. 4. The coating according to claim 1, characterized in that it is equipped with axial and radial heat locks made in the form of displacements in the axial direction by the length L and relative to the axis by an angle. 5. The coating according to claim 1, characterized in that a waterproofing layer made of polymer is applied to the outer surface of the heat-insulating layer, and a decorative and protective coating is applied to the waterproofing layer.

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