RU201048U1 - ROCK SHEET FOR UNDERGROUND STRUCTURES WITH ELECTROCHEMICAL PROTECTION - Google Patents

Abstract

The technical solution relates to the field of building materials used to protect anti-corrosion coatings on structures buried in the ground, preferably metal structures, products and structures, such as pipelines placed in trenches, from mechanical damage from the outside, both during installation and during operation. ... The task of the solution is to create means that, in their entirety, ensure the presence of long-term electrolytic contact of the surface of the protected structure, for example, a metal pipe, with the environment due to the electrolyte located between the rock sheet and the pipe surface. The technical result is an increase in the duration of the electrolytic contact and the possibility of displacement of the potential of the protected structure, for example, a metal pipe with insulation, into the cathode region by more than 500 mV and the presence of a stable response to polarization with an alternating current with a frequency of 1000 Hz, allowing to localize defects in the insulating coating during acceptance and operation section of the pipeline and localize through defects in the insulating coating of the pipeline during its corrosion inspection. This result is achieved irrespective of the angular position of horizontally located notches, which is achieved by the fact that the rock sheet for underground structures with electrochemical protection contains a layer of non-woven synthetic material laminated with a thermoplastic polymer material with through parallel notches made in it, the thickness and surface density of the non-woven synthetic material The material is selected from the condition of keeping it in the space between the thermoplastic polymer material and the underground structure of the electrolyte necessary for the implementation of electrochemical protection. For this, a non-woven synthetic material with a basis weight of 200-450 g / m2, preferably with a basis weight of 300-350 g / m2 and a thickness before lamination of 4.0-6.0 mm, preferably a thickness of 4.8-5.2 mm, the thickness of the rock sheet is 4.0-6.0 mm with a thickness of its laminating layer of 1.5-3.5 mm. 12 p.p. f-crystals, 2 dwg., 3 tbl.

Description

The technical solution relates to the field of building materials used to protect anti-corrosion coatings on structures buried in the ground, preferably metal structures, products and structures, such as pipelines placed in trenches, from mechanical damage from the outside, both during installation and during operation. ...

The closest known is a rocky polymer sheet containing a layer of thermoplastic polymer material, preferably polyethylene, with through cuts or cuts made in it, the length of which is at least one and a half times their width, and the cuts or cuts are made in a direction parallel to the longitudinal the axis of the pipeline, and on the side facing the pipeline, it has a layer of non-woven synthetic material or filtering synthetic material, which is connected over the entire surface or discretely with a layer of thermoplastic material (RF patent No. 101770, 01/27/2011).

The use of the known rock sheet does not provide adequate long-term provision of the electrolytic liquid to the process of electrochemical protection of a structure submerged in the ground.

The objective of this technical solution is to create means that, in their totality, provide the presence of long-term electrolytic contact of the protected surface of the structure, for example, a metal pipe, with the environment due to the electrolyte located between the rock sheet and the surface of the pipe.

The technical result consists in increasing the duration of the electrolytic contact and the possibility of displacing the potential of the protected structure, for example, a metal pipe with insulation, into the cathode region by more than 500 mV and the presence of a stable response to polarization with an alternating current with a frequency of 1000 Hz, which allows localizing defects in the insulating coating during acceptance and operation of the pipeline section, and localize through defects in the insulating coating of the pipeline during its corrosion inspection. This result is achieved regardless of the angular position of the horizontally positioned notches.

This is achieved by the fact that the rock sheet for underground structures with electrochemical protection contains a layer of non-woven synthetic material laminated with a thermoplastic polymer material with through parallel grooves made in it, the thickness and surface density of the non-woven synthetic material are selected from the condition of keeping it in the space between the thermoplastic polymer material material and underground structure of the electrolyte required for the implementation of electrochemical protection. In this case, the cuts can be arranged in parallel rows along the length of the rock sheet and / or along its width, or with a staggered offset relative to each other in rows along the length of the rock sheet and / or along its width. And the length of the groove exceeds the distance between them in parallel rows. The polymeric material in the place of formation of the notches has bordering edges located with a gap to each other, or in the place of formation of the notches it has contacting edges, which form a gap between them when the rock sheet is bent. The non-woven synthetic material can be bonded to the thermoplastic layer over the entire surface or discretely. To accomplish this task, as an example, a nonwoven synthetic material with an areal density of 200-450 g / m ² , preferably with an areal density of 300-350 g / m ² and a thickness before lamination of 4.0-6.0 mm, is used, preferably 4.8-5.2 mm thick. Thermoplastic polymer material can be laminated on the front side with water-permeable fiberglass. And as a thermoplastic polymer material, high pressure polyethylene (LDPE) can be used. At the same time, the thickness of the rock sheet for underground structures with electrochemical protection is 4.0-6.0 mm with a thickness of its laminating layer of 1.5-3.5 mm.

The significance of the features is confirmed by their causal relationship with the technical result. So, the implementation of a rock sheet with a layer of non-woven synthetic material allows you to concentrate in a volume limited on the one hand by a laminated thermoplastic polymer material, and on the other by the insulation of an underground structure, an electrolyte, which, in this case, is water containing salts dissolved in it. In this case, the thickness and surface density of the non-woven synthetic material used to contain the electrolyte are selected from the condition that it retains the electrolyte necessary for the implementation of electrochemical protection in the space between the thermoplastic polymer material and the underground structure. Such a choice is determined for each type of soil, taking into account the non-woven synthetic material used, with a surface density of 200-450 g / m ² (at a density less than 200 g / m ^{2, the} material is not completely distributed in the cavity "underground structure - thermoplastic polymer material", which is not allows to provide electrochemical protection throughout the cavity, at a density of more than 450 g / m ^{2, the} porosity of the material decreases, which leads to a rapid removal of the electrolyte from the cavity), preferably with an areal density of 300-350 g / m ² and a thickness of 4 before lamination, 0-6.0 mm (this thickness allows to obtain after lamination the retention of the required amount of electrolyte per unit area), preferably 4.8-5.2 mm thick. The type of thermoplastic polymer material and the location of the notches in it determine the possibility of penetration through them from the outside of the electrolyte, and due to deformation during bending around an underground structure, for example a metal pipe, the inner surface of each of the parallel notches has a shape that tapers towards the nonwoven synthetic material, facilitating the penetration of the electrolyte it and making it difficult to flow back, ensuring its retention in the nonwoven synthetic material. Exceeding the length of the notch distance between them in parallel rows provides the formation of zones of uniform saturation of the non-woven synthetic material with electrolyte. As options, the nonwoven synthetic material is bonded to the thermoplastic layer over the entire surface or discretely, which allows the accumulation and retention of electrolyte therein. The implementation of the technical result for a rock sheet with a thickness of 4.0-6.0 mm made in the manner described was confirmed (this thickness allows the sheet to bend with the formation of openings during bending, ensuring uniform filling of the space between the polymer sheet and the surface of the underground structure with electrolyte) with the thickness of its laminating layer 1.5-3.5 mm. Here, a rocky sheet is understood to mean various forms of its execution, for example, directly the rocky sheet itself in the form of a piece of web, protective mats or, for example, tapes for placing such protection on curved sections.

FIG. 1 shows a general view of a rock sheet for underground structures with electrochemical shielding, placed in watered soil on an underground structure in the form of a metal structure protected by insulation.

FIG. 2 - node A in Fig. 1.

The protected underground structure can be made in the form of a metal pipe 1 with insulation 2, in which a damaged section 3 can form, requiring the use of electrochemical corrosion protection. To do this, use a rock sheet containing a layer of non-woven synthetic material 4, laminated with a thermoplastic polymer material 5 with through, parallel grooves 6 made in it. For example, high-pressure polyethylene (LDPE) 158 and LDPE can be used as the material of the polymer sheet. 15803-020 OOO Gazprom neftekhim Salavat STO 05766575-140-2013, LDPE 15803-020 OOO Tomskneftekhim, LDPE 15803-020 OAO NAFTAN GOST 16337-77. The thickness and surface density of the non-woven synthetic material 4 are selected from the condition of keeping it in the space between the thermoplastic polymer material and the underground structure of the electrolyte necessary for the implementation of electrochemical protection. For these purposes, needle-punched fabric is used, for example, produced by Technoline according to STO 78262563.003-2008, the surface density of which is 300 g / m ² . In this case, the notches 6 can be arranged in parallel rows along the length of the rock sheet and / or along its width (as shown in Fig. 1) or with a staggered offset relative to each other in rows along the length of the rock sheet and / or along its width, and the length of the notch exceeds the distance between them in parallel rows. The polymeric material in the place of formation of the notches has bordering edges located with a gap to each other, or in the place of formation of the notches it has contacting edges, which form a gap between them when the rock sheet is bent. The non-woven synthetic material can be bonded to the thermoplastic layer over the entire surface or discretely. To accomplish this task, as an example, a nonwoven synthetic material with an areal density of 200-450 g / m ² , preferably with an areal density of 300-350 g / m ² and a thickness before lamination of 4.0-6.0 mm, is used, preferably 4.8-5.2 mm thick. Thermoplastic polymer material can be laminated on the front side with water-permeable fiberglass. And as a thermoplastic polymer material, high pressure polyethylene (LDPE) can be used. Needle-punched fabric can be used as a non-woven synthetic material. At the same time, the thickness of the rock sheet for underground structures with electrochemical protection is 4.0-6.0 mm with a thickness of its laminating layer of 1.5-3.5 mm.

Increasing the duration of electrolytic contact and the possibility of displacing the potential of the protected structure, for example, a metal pipe with insulation, into the cathode region by more than 500 mV and the presence of a stable response to polarization with an alternating current with a frequency of 1000 Hz, which makes it possible to localize defects in the insulating coating during the acceptance and operation of a pipeline section , and localize through defects in the insulating coating of the pipeline during its corrosion inspection. This result is achieved irrespective of the angular position of the horizontally located notches relative to the longitudinal axis of the pipe.

To confirm the technical result, full-scale tests were carried out using the following equipment (see tables 1 and 2):

Based on the tests performed on a rock sheet with the above parameters, the following conclusions were made:

- the tested rock sheet has an electrolytic contact with the environment evenly distributed over the area due to the electrolyte accumulated in the non-woven synthetic material;

- under the influence of an external cathodic current, the potential of the defect is shifted into the cathode region by 500 mV or more, regardless of the angular position of the rock sheet;

- the defect located under the rock sheet has a stable response to polarization with an alternating current with a frequency of 1000 Hz, which makes it possible to localize defects in the insulation coating.

Claims (12)

1. A rock sheet for underground structures with electrochemical protection, containing a layer of non-woven synthetic material laminated with a thermoplastic polymer material with through parallel grooves made in it, characterized in that the thickness and surface density of the non-woven synthetic material are selected from the condition of holding it in the space between thermoplastic polymer material and underground electrolyte structure required for the implementation of electrochemical protection. 2. Rock sheet for underground structures with electrochemical protection according to claim 1, characterized in that the cuts are arranged in parallel rows along the length of the rock sheet and / or along its width. 3. A rock sheet for underground structures with electrochemical protection according to claim 2, characterized in that the cuts are displaced staggered relative to each other in rows along the length of the rock sheet and / or along its width. 4. Rock sheet for underground structures with electrochemical protection according to claim 2 or 3, characterized in that the length of the cut exceeds the distance between them in parallel rows. 5. A rock sheet for underground structures with electrochemical protection according to claim 1, characterized in that the polymeric material at the site of the formation of cuts has edges that are delimited to each other with a gap to each other. 6. A rock sheet for underground structures with electrochemical protection according to claim 1, characterized in that the polymeric material in the place of formation of cuts has contacting edges, which form a gap between them when the rock sheet is bent. 7. Rock sheet for underground structures with electrochemical protection according to claim 1, characterized in that the non-woven synthetic material is bonded to a layer of thermoplastic material over the entire surface or discretely. 8. Rock sheet for underground structures with electrochemical protection according to claim 1, characterized in that a non-woven synthetic material with a surface density of 200-450 g / m ^{2 is used} , preferably with a surface density of 300-350 g / m ² and a thickness before lamination of 4.0-6.0 mm, preferably 4.8-5.2 mm thick. 9. Rock sheet for underground structures with electrochemical protection according to claim 1, characterized in that the thermoplastic polymer material is laminated on the front side with a water-permeable fiberglass cloth. 10. Rock sheet for underground structures with electrochemical protection according to claim 1, characterized in that high pressure polyethylene (LDPE) is used as a thermoplastic polymer material. 11. Rock sheet for underground structures with electrochemical protection according to claim 8, characterized in that needle-punched fabric is used as a non-woven synthetic material. 12. Rock sheet for underground structures with electrochemical protection according to claim 1, characterized in that its thickness is 4.0-6.0 mm with a thickness of the laminating layer of 1.5-3.5 mm.

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