RU2317475C1 - Bedrock sheet for protecting a pipeline (variants) and method for manufacturing said bedrock sheet - Google Patents

Abstract

FIELD: construction of pipeline transportation means, possible use for protecting isolated surface of pipelines during driving in bedrock, permafrost soils, and also in mineral soils with inclusions, which cause damage to isolation of pipeline, such as inclusions of grass, pebbles, individual burs.

SUBSTANCE: bedrock sheet is capable of taking on the form of hollow cylinder encasing the pipeline, and is formed by flexible strip of synthetic material. Flexible strip is made one-layered, two-layered or multi-layered of fibrous bonded sheet material laminated on one or two sides based on fibers of polypropylene or polyether group with saturation of fibrous bonded material with self-hardening composition for whole thickness. Bedrock sheet has required flexibility for enveloping the pipeline and following fastening on it in field conditions, has high impact resistance, resistance to comminution and punching through by sharp soil fractions.

EFFECT: increased reliability of pipeline.

3 cl

Description

The invention relates to the construction of pipeline transport and is used to protect the insulated surface of pipelines when laying them in rocky, permafrost soils, as well as in mineral soils with inclusions causing damage to the pipeline insulation, for example, with inclusions of gravel, pebbles, individual blocks.

It is known that when laying pipelines in rocky, gravel-pebble, gravel and the like soils, it is necessary to protect the insulation of the pipelines from damage (see clause 5.6. SNiP 2.05.06-85 *).

In the prior art, various shockproof protective devices of an insulated pipe surface are known. So, it is known a protective device containing a hollow open cylinder with an external solid after special surface treatment. The hollow cylinder is made of a flexible cloth based on synthetic material (see US 4413656 A, 1982, F16L 57/00). A disadvantage of the known solution is the complexity of manufacturing the panel from the polymer composition, the need for heat treatment to obtain a device with the necessary hardness of the outer surface and the complexity of mounting the device on the pipeline in the field.

Known "shockproof protective device of various surfaces, mainly the pipeline" (see RU 2162187 C1, 01/20/2001). In the known device, a hollow open cylinder is made of a multilayer cloth made of synthetic material with each layer impregnated from a certain surface to a predetermined thickness, followed by gluing all the layers in the cloth. A disadvantage of the known device is a rather complicated manufacturing technology and increased consumption of materials.

Closest to the claimed solution is known from the prior art "rock sheet for pipeline protection" RU 2214553 C1, 10.20.2003. In a known solution, the rock sheet comprises a hollow open cylinder formed by a flexible sheet of synthetic material. A flexible panel with a total thickness of not more than 7 ± 0.5 mm is made single or double layer of fibrous sheet non-woven material based on fibers of the group of polypropylene or polyesters with a thickness of 3.5-7.0 ± 0.5 mm with impregnation of the fibrous non-woven material for the entire the thickness of the urea-formaldehyde resin self-curing composition.

The device is manufactured in the factory. From a roll of nonwoven fibrous material, billets are cut with a length equal to the circumference of the outer surface of the pipeline with technological allowance. Each preform is impregnated with the specified composition at a rate depending on the thickness of the preform material. If it is necessary to obtain a rock sheet with enhanced mechanical properties, it is made two-layer. The fabricated rock sheets are cured until the resin is fully cured.

A disadvantage of the known technology is the increased consumption of resin, the possibility of bonding blanks in packages, including at the ends, gluing the bottom blank to the pallet and the possibility of damage to the rock sheets (hereinafter referred to as SL) when they are separated after the composition is cured.

In addition, if it is necessary to obtain SL with enhanced physical and mechanical properties, for example, by 20-30% it is necessary to increase the number of SL layers, which also leads to unreasonable cost overruns of materials.

The solved problem of this invention is to increase the physicomechanical properties of SLs, to obtain SLs that are neutral to the cathodic protection of the pipeline, increase the reliability of SLs when transporting and installing them on the pipeline in the field, while maintaining the flexibility and strength of SLs, as well as reduce the consumption of materials in the manufacture of SLs.

This problem is solved in that the SL is made in the form of a flat flexible cloth made of synthetic material impregnated with a self-curing composition, with the possibility of bending the cloth with the formation of a hollow cylindrical shell covering the pipeline, and the SL is made of one or more sheets of porous material, for example, non-woven synthetic material ( HCM) based on a group of, for example, polypropylenes or polyesters, while the outer / outer side / sides of the panel are laminated, for example, with polyethylene and / or rmitex. "

Lamination of the outer / outer sides of the SL increases its physical and mechanical properties without a significant increase in the thickness and mass of the SL. For example, a double-sided laminated SL “Armetex” has a thickness of 3.6 mm, with the specified standard thickness “not less than 3 mm”, and the impact strength of the laminated SL increases from 20 to 28 J.

Thus, based on the above example, it can be seen that to obtain SL with improved physicomechanical properties, it is sufficient to laminate its surfaces, while using known technology it is necessary to increase the SL layers to two and, accordingly, double the consumption of materials.

The problem is also solved by the fact that the SL is made in the form of a flat flexible cloth made of synthetic material impregnated with a self-hardening composition, with the possibility of bending the cloth with the formation of a hollow cylindrical shell covering the pipeline, and the SL is multilayer of porous sheet material, for example, non-woven synthetic fabric based on NSM , for example, a group of polypropylene or polyesters and contains one or more reinforcing layers of fleecy fabric, for example, cotton-lavsan, while zhnaya / outer side / side webs laminated SL, for example, polyethylene and / or "armiteksom".

In the particular case of performing SL as a reinforcing fabric located between layers of a porous sheet material, having the ability to impregnate it with a self-hardening composition and adhesion with layers of a porous sheet material, a cotton-lavsan fabric made of synthetic yarns or complex yarns is used, each of which is twisted one or more fleecy cotton threads or complex cotton threads.

The use of a reinforcing layer of fleecy cotton-lavsan fabric can significantly increase the physicomechanical properties of SL without significantly increasing its weight, which is important in the case of manual installation of SL in a pipeline, especially in cramped trench conditions. Reinforcing SL leads to a decrease in the consumption of materials, including a self-hardening composition, which helps to improve sanitary and hygienic working conditions. Fleecy fabric (cotton-lavsan), as a reinforcing material, has the necessary physical and mechanical properties due to the presence of lavsan threads non-wettable by this composition, and in the presence of cotton threads, the fabric is effectively wetted by a self-hardening composition, providing the necessary connection between the SL layers.

At the same time, as tests have shown, the claimed solutions provide SL with its physical and mechanical properties neutral to cathodic protection, which is very important in the construction of pipelines, for example, in irrigated, permafrost soils, especially with possible thawing.

In addition, this problem is also solved by the fact that in the method of manufacturing a rock sheet (SL) for protecting the pipeline, which consists in laying flat flexible billets of synthetic material on a pallet, impregnating them with a self-curing composition, followed by drying, the production of SL is carried out in a batch set of flat flexible blanks, and to prevent them from sticking to the pallet and between each other, self-hardening composition locking sheets are used in said blanks with which one or two-sided laminate said preform across the surface, or leaving the free edges of the laminate sheets HCM - preforms including pre-use one-sided laminated preform, for example, "armiteksom" or polyethylene.

In addition, the non-laminated edges of the flat flexible blanks overlap with tapes of non-adhesive material with a self-hardening composition, while the edges of the ribbons are aligned with the edges of the flat flexible blanks, or the edges of the ribbons protrude outward beyond the edges of the flat flexible blanks.

In the particular case of the method, flat flexible preforms with non-laminated edges are overlapped with sheets of non-adhesive material with a self-hardening composition, while the edges of these sheets are aligned with the edges of the flat flexible preforms, or the edges of these sheets protrude outward beyond the edges of the flat flexible preforms.

Thus, the use of locking layers in the form of laminating SLs, as well as tapes, sheets, for example, of polyethylene, not only improves the physicomechanical properties of SLs, but also prevents bonding of workpieces, including their ends, during the production of SLs, which in turn, eliminates the damage to the SL when they are separated from the bag after curing the specified composition.

The claimed device is manufactured industrially. From a roll of nonwoven fibrous material, preforms of a design length are cut that exceed the circumference of the outer surface of the pipeline by the size of the technological allowance.

Flat flexible preforms are successively laid on a pallet, impregnated with a self-hardening composition, and to prevent them from sticking to the pallet and with each other, self-hardening composition locking sheets are used in these preforms, which laminate one or two sides of these preforms, for example, “Armitex” (see www .ayaskom.ru).

“Armitex” is a fibrous material with a unilaterally processed (laminated) surface and has the following properties:

- surface density, g / m ² 72-76 - thickness, mm 0.264-0.258 - breaking load kgf / 5 cm along 8.9-10.6 across 5.3-6.5 - elongation at break,% along 50.6-59.6 across 48,2-40,4

To remove air from the pores of the porous material of the billets (LFM) and better impregnation of the billets with a self-hardening composition, the LFM of each billet treated with the specified composition is rolled. Rolling of the SL billets impregnated with a self-hardening composition by roller helps to remove air from the porous material of the billets, improves their impregnation with a self-hardening composition. At the same time, in the unilaterally laminated sheets of a porous material, the HCM layer tends to stretch due to the properties of the HCM when rolling on it by a roller, however, the layer of the laminating material prevents this.

The removal of air from the pores of the material of the blanks of the NSM sheets can be accomplished by squeezing the NSM sheets on their surface, for example, by pressing or evacuating the NSM sheets with their impregnation with a self-curing composition.

In the case of using preforms from a pre-one-sided laminated, for example, polyethylene, porous material, the preforms are laid with a laminated layer on a pallet. Moreover, as locking self-hardening composition using sheets of non-adhesive material with a self-hardening composition, for example sheets of polyethylene.

In the manufacture of double-sided laminated SL in the case of using preforms from a material preliminarily unilaterally laminated, for example, with polyethylene, on the fleecy surface of the workpiece impregnated with the specified composition, after rolling it with a roller, a locking layer of “Armitex” is laid with a fleecy layer.

At the same time, the edges of the flat flexible preforms are overlapped with tapes of non-adhesive material with a self-curing composition, the edges of the tapes being flush or protruding outside the edges of the flat flexible preforms. In the case when the flat flexible preforms are overlapped with sheets of non-adhesive material with a self-hardening composition, the edges of these sheets are flush or protrude beyond the edges of the flat flexible preforms, which prevents bonding of the preforms, including the ends during the subsequent curing of the specified composition. If it is necessary to obtain SLs with enhanced physicomechanical properties of the billet, the NSM sheets after impregnation of the lower layer, a reinforcing material is laid on it, which, after impregnation with the specified composition, is covered with a blank - the NSM sheet with its subsequent impregnation with the composition, the lamination technology of such SLs is indicated above.

The product of the claimed method is SL for protecting the pipeline, made in the form of a flat flexible cloth made of synthetic material impregnated with a self-curing composition, with the possibility of bending the cloth with the formation of a hollow cylindrical shell covering the pipeline, while SL is made of one or more sheets of porous material, for example, non-woven synthetic material (HCM) based on a group, for example polypropylenes or polyesters, the outer / outer side / sides of the panel being laminated For example, polyethylene and / or "armiteksom".

If it is necessary to obtain SL with enhanced physical and mechanical properties according to the claimed method, SL is obtained for protecting the pipeline, made in the form of a flat flexible cloth made of a synthetic material impregnated with a self-curing composition, with the possibility of bending the cloth with the formation of a hollow cylindrical shell covering the pipeline, while the SL is made laminated from a sheet of porous material, for example, nonwoven synthetic material HCM) based on, for example, a group of polypropylene or poly firs and contains one or more reinforcing layers of fleecy fabric, for example, cotton-lavsan, while the outer / outer sides / sides of the panel are laminated, for example, with polyethylene and / or “armitex”. As a reinforcing fabric, capable of impregnating it with a self-hardening composition and adhesion with layers of a porous material, a cotton-lavsan fabric made from synthetic threads or from complex threads, each of which is entwined with one or more cotton threads or complex cotton threads, is used, which provides high-quality impregnation of SL layers and the necessary bonding of layers between each other.

A self-curing composition for impregnating preforms and gluing them is prepared in a mixer, introducing components from the dispensers: the resin is a polycondensation product of urea with formaldehyde, a diluent, plasticizer and hardener. The composition of the composition is adjusted depending on the brand of resin, the magnitude of the required viscosity, the rate of curing of the resin and the required values of the physico-mechanical properties of SL. The SL made according to the invention has the necessary flexibility to compress it in the field, followed by securing the rock sheet on the pipeline before laying it in the trench or directly in the trench. It is possible to fix the rock sheet on insulated pipes before sending them to the consumer. SL has high impact strength, resistance to abrasion and crushability by solid sharp fractions of the soil, both under static vertical pressure and under the combined action of vertical and shear loads acting on the pipeline during its operation. It is possible to use SL to protect against the shock load of the arrows of lifting machines, such as pipe layers, cranes, as well as to protect the pipes during transportation.

Claims (6)

1. Rock sheet (SL) for protecting the pipeline, made in the form of a flat flexible sheet of synthetic material impregnated with a self-curing composition, with the possibility of bending the sheet with the formation of a hollow cylindrical shell covering the pipeline, characterized in that the SL is made of one or more sheets of porous material , for example, non-woven synthetic material (HCM) based on a group of, for example, polypropylenes or polyesters, while the outer / outer side / sides of the panel are laminated, for example EP, polyethylene and / or Armitex. 2. Rock sheet (SL) for protecting the pipeline, made in the form of a flat flexible sheet of synthetic material impregnated with a self-curing composition, with the possibility of bending the sheet with the formation of a hollow cylindrical shell covering the pipeline, characterized in that the SL is multilayer of porous sheet material, for example non-woven synthetic material (HCM) based on, for example, a group of polypropylenes or polyesters and contains one or more reinforcing layers of fleecy fabric, such as cotton kovo-lavsanova, while the outer / outer side / sides of the SL panel are laminated, for example, with polyethylene and / or “Armitex”. 3. The rock sheet according to claim 2, characterized in that as a reinforcing fabric having the ability to impregnate it with a self-hardening composition and adhesion with layers of porous material, a fleecy fabric, for example cotton-lavsan fabric made of synthetic threads or from complex threads, is used each of which is entwined with one or more fleecy, for example, cotton threads or complex cotton threads. 4. A method of manufacturing a rock sheet (SL) for protecting the pipeline, which consists in laying flat flexible blanks of synthetic material on a pallet, impregnating them with a self-curing composition, followed by drying, characterized in that the manufacturing of SL is carried out with a batch set of flat flexible blanks, and to prevent gluing them with a pallet and between each other, use self-hardening composition locking sheets in said blanks, with which the blanks are laminated one or two-sided over the entire surface or leaving the edges of the NSM sheets free from laminate, including using preliminarily one-sided laminated blanks, for example, “Armitex” or polyethylene. 5. The method according to claim 4, characterized in that the non-laminated edges of the flat flexible blanks overlap with tapes of non-adhesive material with a self-curing composition, while the edges of the ribbons are aligned with the edges of the flat flexible blanks or the edges of the ribbons protrude outside the edges of the flat flexible blanks. 6. The method according to claim 4, characterized in that the flat flexible preforms with non-laminated edges are overlapped with sheets of non-adhesive material with a self-curing composition, while the edges of these sheets are flush with the edges of the flat flexible preforms or the edges of these sheets protrude outside the edges of the flat flexible preforms .