RU212263U1 - POLYMER PIPE - Google Patents

Abstract

The utility model relates to the field of construction and operation of hidden communications and, mainly, can be used in underground pipelines. The polymer pipe contains an inner polymer layer in the form of a circular cylinder and an outer polymer layer enclosing it. Between the inner and outer polymeric layers, radio-frequency identification marks are installed, located along the diametrically opposite first and second generatrices of the cylinder of the inner polymeric layer and along the diametrically opposite third and fourth generatrixes of the cylinder of the inner polymeric layer. The third and fourth generatrices of the cylinder of the inner polymer layer are located in the axial section of the cylinder of the inner polymer layer, perpendicular to the axial section of the cylinder of the inner polymer layer, in which the first and second generatrix of the cylinder of the inner polymer layer are located. The utility model provides the achievement of a technical result, which consists in expanding the arsenal of used technical means of a similar purpose. 2 w.p. f-ly, 2 ill.

Description

The utility model relates to the field of construction and operation of hidden communications and can mainly be used in underground pipelines.

In the construction of underground pipelines for water, gas, electricity and telecommunications distribution networks, pipes made of polymeric materials are widely used, which are not subject to corrosion and have plasticity that fends off possible soil displacements. At the same time, the lack of electromagnetic properties of polymer materials makes it difficult to detect underground polymer pipelines.

In this regard, the marking of polymer pipes used in the construction of underground pipelines is used with the help of the so-called radio frequency identification tags or otherwise RFID tags (Radio Frequency ldentification), which make it possible to detect them using the radio frequency identification method.

For example, the following similar technical solutions are known that use the marking of polymer pipes using radio frequency identification marks:

a cylindrical polymer pipe, which is provided with radio-frequency identification marks regularly spaced along one of its generatrix, attached to it using fasteners, for example, clamps, or clips, or screws, and covered with a polymer protective layer (RU 2575183 C2, 2016);

a cylindrical polymer pipe, which is provided with an endless polypropylene tape glued along one of its generatrix with regularly spaced radio frequency identification marks (RU 2575183 C2, 2016);

a cylindrical polymer pipe, which is wrapped in a spiral polypropylene endless tape containing regularly spaced radio-frequency identification tags, the longitudinal axes of which are located at such an angle to the axis of the tape, in which, as a result of wrapping the tape of the polymer pipe, the longitudinal axes of the radio-frequency identification tags are located along one of the generatrix of the pipe parallel to its axis, and is provided with a protective polymer layer covering the tape (RU 2575183 C2, 2016).

The closest in design to this utility model is (RU 2575183 C2, 2016) a cylindrical polymer pipe, which is provided with radio frequency identification marks regularly located along one of its generatrix, glued to it and covered with a polymer protective layer.

In order to be able to detect using the method of radio frequency identification of a pipeline made of polymer pipes, which are the closest analogue, like all analogues mentioned above, it is necessary that the radio frequency identification marks be located as close as possible to the surface of the soil covering the pipeline.

In this regard, during the construction of the pipeline, it is required to install each cylindrical pipe when laid horizontally in a trench so that the radio-frequency identification marks located along one of its generatrices are located on top (see: RU 2619818 C2, 2017, Fig. 1), which, as practice shows, is not always carried out, for example, due to the lack of care of the builders and therefore complicates the construction of the pipeline, since it requires additional control over the pipe-laying process.

The objective of this utility model was to create a polymer pipe, the design of which simplifies the process of laying it in a trench during the construction of a pipeline, since it does not require compliance with a given orientation of the pipe relative to its axis.

The utility model provides the achievement of a technical result, which consists in expanding the arsenal of used technical means of a similar purpose.

The problem is solved, and the declared technical result is achieved by the fact that a polymer pipe containing, as in the closest analogue, an inner polymer layer in the form of a circular cylinder, covering its outer polymer layer and a set of radio-frequency identification marks located between the inner and outer

polymer layers along the first generatrix of the cylinder of the inner polymer layer, differs from the closest analogue in that it is equipped with radio-frequency identification marks, which are placed along the second generatrix of the cylinder of the inner polymer layer, located diametrically opposite to the first generatrix of the cylinder of the inner polymer layer, and radio-frequency identification marks, which are placed along the third and fourth generatrices of the cylinder of the inner polymer layer, which are located in the axial section of the cylinder of the inner polymer layer, perpendicular to the axial section of the cylinder of the inner polymer layer, in which the first and second generatrix of the cylinder of the inner polymer layer are located.

In this case, the inner and outer polymeric layers are made of polyethylene.

Radio frequency identification marks are regularly placed along the first, second, third and fourth generatrices of the cylinder of the inner polymer layer.

Provision of the inventive polymer pipe with radio-frequency identification marks, which are placed along the second generatrix of the cylinder of the inner polymer layer, located diametrically opposite the first generatrix of the cylinder of the inner polymer layer, and radio-frequency identification marks, which are placed along the third and fourth generatrix of the cylinder of the inner polymer layer, which are located in the axial section cylinder of the inner polymer layer, perpendicular to the axial section of the cylinder of the inner polymer layer, in which the first and second generatrix of the cylinder of the inner polymer layer are located, simplifies the process of laying it in a trench during pipeline construction, since it does not require compliance with the specified orientation of the pipe relative to its axis.

The above indicates the solution of the problem of the present utility model declared above and the achievement of the formulated technical result.

In FIG. 1 shows a side view of the inventive polymer pipe.

In FIG. 2 shows a cross-section along A-A of the inventive polymer pipe shown in FIG. one.

The polymer pipe 1 contains an inner polymer layer 2 in the form of a circular cylinder and an outer polymer layer 3 enclosing it, which are made, for example, of PE100 grade polyethylene. The polymer pipe 1 also contains radio frequency identification marks 4, which are placed between the inner polymer layer 2 and the outer polymer layer 3 directly in the process of manufacturing the polymer pipe 1 at the stage of extrusion formation of the outer polymer layer 3.

As radio frequency identification marks 4, linear electromechanical resonance radio frequency marks manufactured by 3M Company, USA can be used, in which at least the identification data of radio frequency identification marks 4 and information related to the pipeline made on the basis of polymer pipes 1 are recorded.

Radio frequency identification marks 4 are regularly located along the first, second, third and fourth generatrices 5, 6, 7 and 8 (shown in dashed lines in Fig. 1, and dots in Fig. 2) of the cylindrical surface of the inner polymer layer 2 of the polymer pipe 1 at a given distance from one another.

The first and second generatrixes 5 and 6 of the cylindrical surface of the inner polymer layer 2 of the polymer pipe 1 are located diametrically opposite. The third and fourth generators 7 and 8 of the cylindrical surface of the inner polymer layer 2 of the polymer pipe 1 are located diametrically opposite in the axial section of the cylindrical surface of the inner polymer layer 2, perpendicular to the axial section of its cylindrical surface, in which the first and second generators 5 and 6 of the cylindrical surface of the inner polymer are located. layer 2 of polymer pipe 1.

During the construction of the pipeline, each polymer pipe 1 is placed in a trench with an arbitrary orientation relative to its axis. Adjacent polymer pipes 1 are connected, for example, using thermal welding, after which the trench is filled with soil.

As a result, despite the arbitrary relative to the axis orientation of the polymer pipes 1 in the composition of the pipeline, radio-frequency identification marks 4, which are located along either the first 5, or the second 6, or the third 7, or the fourth 8 generatrices of the cylindrical surface of the inner polymer layer 2, are located on top, those. closer to the surface of the soil covering the pipeline.

To detect and determine the location of an underground pipeline made using polymer pipes 1, radio frequency identification marks 4 are activated using one of the known devices for this purpose, for example, a mod marker detector. 7420, manufactured by 3M Dynatell, USA.

Thus, the utility model provides the achievement of a technical result, which consists in expanding the arsenal of used technical means of a similar purpose.

Claims (3)

1. A polymer pipe containing an inner polymer layer in the form of a circular cylinder, covering its outer polymer layer and a set of radio frequency identification marks located between the inner and outer polymer layers along the first generatrix of the cylinder of the inner polymer layer, characterized in that it is equipped with radio frequency identification marks, which are placed along the second generatrix of the cylinder of the inner polymer layer, located diametrically opposite to the first generatrix of the cylinder of the inner polymer layer, and RF identification marks, which are placed along the third and fourth generatrix of the cylinder of the inner polymer layer, which are located in the axial section of the cylinder of the inner polymer layer, perpendicular to the axial section cylinder of the inner polymer layer, in which the first and second generators of the cylinder of the inner polymer layer are located. 2. Polymer pipe according to claim 1, characterized in that the inner and outer polymer layers are made of polyethylene. 3. A polymer pipe according to claim 1, characterized in that the radio frequency identification marks are regularly placed along the first, second, third and fourth cylinder generatrices of the inner polymer layer.

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