RU2274793C1 - Method and device for laying pipeline - Google Patents

Abstract

FIELD: pipeline engineering.

SUBSTANCE: method comprises trenching to define trench widenings symmetrically with respect to the pipeline, laying the pipeline, overlapping the pipeline and trench bottom with flexible mats at the sites of widenings, and filling the trench and pits for permitting the flexible mats to be pressed to the bottoms of the pits and the trench.

EFFECT: enhanced reliability.

21 cl, 4 dwg

Description

The invention relates to the construction and is used when laying pipelines in thawing permafrost soils and in irrigated areas. The prior art method of constructing a pipeline in flooded soils. Soft sheets are hung on the pipeline laid at the bottom of the trench, the edges of which are folded in advance in 2-3 layers and fixed in this state by mechanical tacks or surface fusion. Ready reinforcing mats from the bars are lowered into the trench with the spikes down, orienting the latter towards the closure of the walls and the bottom of the trench, on the folded edges of the soft panels.

Partially loading the reinforcing mats from their own weight after the studs come into contact with the edges of the soft panels folded into the fold, push the latter with spikes, and then continuing to lower the opposite ends of the bars, lay the reinforcing mats on the soft panels. The trench is filled with backfill soil until a surface roll is formed. The soil for filling the trenches is taken from the dump piled when digging the trench, moving it with a bulldozer. In the case of flooding the trench, the pipeline experiences a buoyancy force that causes some upward displacement of the pipeline. Together with the pipeline, sections of soft panels also rise, covering the pipeline from above.

The sections of soft panels located under the reinforcing mats of the beams and fastened to them with the help of spikes are deprived of the ability to move. Therefore, the process of raising the pipeline under the action of the buoyancy of water is accompanied by the tension of the sections of soft panels hanging from the pipeline and the rotation of the reinforcing mats with the spikes turning out of the ground. Since the material of the panels has a relative elongation, there is a loss of the ballasting ability of the panels and, possibly, the displacement of the pipeline from the design marks under the action of the buoyancy force of water (see SU 1809226 A1, 04/15/1993).

The prior art method for laying an underground trunk pipeline in an irrigated area (see SU 1013689 A, 04/23/1983). According to the known method, the trench is torn off with the formation of symmetrical trench broadening at calculated distances from each other, and then the berm (at the location of the broadening) is closed, the walls and the bottom of the trench with continuous flexible carpets placed on the pipeline, the width of which is no more than the broadening length in the direction of the axis of the trench. In conclusion, fill the trench and broadening with ballasting material, including open ground. To increase the reliability of pinching of the edge sections of continuous carpets, broadening is performed with the bottom having slopes away from the bottom of the trench. If it is necessary to place the technological road on the berm of the trench when performing its broadening in the form of extended trench-branches, the trench fragment with its symmetrical broadening and backfill are carried out in two stages, in the first of which half the trench broadening is fragmented and filled in the lane of the technological road. In this case, backfilling is carried out after the passage, and before filling in each half of the broadening, the edge section of the rolled-up continuous carpet is placed. This allows you to further mount the pipeline directly on the berm of the trench, and then lower it into the trench.

Thus, as a result of the obtained possibility of crushing the edge sections of continuous carpets with soil, it was possible to fix the pipeline at the bottom of the trench. The disadvantage of this method is the lack of reliability of the soil being pinched by the backfill of the edges of the flexible carpets, especially when the backfill layer is low in height, since the latter is quite loose, unbreakable and its holding ability is ensured only by friction at the boundary of the "flexible carpet-ground" surfaces.

A known method of laying a pipeline, which is used in the construction of pipelines in flooded areas. The method is as follows. In the case of using flexible carpets with enhanced deforming properties, pits are made at the bottom of the broadening, while backfillings are filled with soil, flexible carpets fit to the bottom of the broadening and pits. If there is water in the trench, the bottom of the broadening is performed with a calculated slope towards the pipeline, while the thickenings are located above the water level. When constructing a pipeline in permafrost soils, the end sections of flexible carpets are placed outside the areola of thawing soil, i.e. they are constantly frozen into the ground. As a material for flexible carpets, fabric for ballasting gas pipelines TBG-360 can be used, as well as a container thread “Ponikon”.

Preliminary stretching of flexible carpets allows more fully utilizing their mechanical properties for pipeline ballasting and eliminates instability of loading forces due to operational drawing of flexible carpets (see SU 1638419 A1, 03.30.1991). This solution is the closest analogue to the claimed group of inventions - variants of the method. The indicated drawbacks are characterized by the above-mentioned disadvantages: to increase the ballasting ability, it is necessary to increase the resistance to pulling the edges of flexible carpets out of the ground, which can be achieved by increasing the length of the edges of flexible carpets pinched by the soil, increasing the height of the backfill, using compaction of the backfill soil, increasing the drag force when pulling the end sections of the flexible Carpets from soil backfilling trenches.

The closest known solution to the method of surface pipeline laying is laying the pipeline in an embankment when the lower generatrix of the pipeline has a mark at or above the surface when laying the pipeline on an unpaved cushion (see BORODAVKIN P.P. et al. "Construction of trunk pipelines" , M., Nedra, 1987, p. 15, Fig. 1.7 c.

The objective of the claimed group of inventions is to increase the reliability of securing the pipeline at design elevations when laying it in the trench irrigated periodically, in a trench with a high level of standing water, with surface laying of the pipeline on the irrigated area. Achievable technical result in the implementation of the group of inventions is to increase the crushing ability of the soil backfill when using flexible carpets for ballasting and securing the pipeline at design elevations.

This problem is solved by the fact that in the method of laying an underground pipeline, a trench is torn off with the formation of trenches symmetrical with respect to the pipeline at the calculated distance from each other, laid in the pipeline, the pipeline and the bottom of the trench transversely overlap the pipeline and the bottom of the trench at the locations of the broadening, jammed edge sections of flexible carpets , backfill the trenches and pits, ensuring that the flexible carpets fit to the bottom of the pits and trenches. To increase the reliability of fixing the pipeline, flexible carpets are pre-attached with symmetrical deflections and fixed with the formation of a pair of design capacity of pockets filled with soil, which are placed on both sides of the pipeline. In addition, the bottom of the broadening trenches is performed with a design slope away from the pipeline or towards the pipeline, moreover, the symmetrical deflections of the flexible carpets are fixed by means of flexible tapes, and the broadening is filled up from their ends farthest from the pipeline and symmetrically relative to the pipeline with elastic extension of the flexible carpets to their fit to the bottom of the trench.

To increase the reliability of securing the pipeline by increasing the pinching ability of the edge sections of the flexible carpets in the soil, textile containers placed in the ears of the flexible carpets parallel to the pipeline parallel to the pipeline are textile containers, while the cuts perpendicular to them are made in the center of the edge sections of the flexible carpets with eyes. for introducing anchor elements into the flexible carpeting lugs.

This problem is also solved in a method of laying an underground pipeline in a trench with a high level of standing water, consisting in extracting the trench with the formation of trench broadening symmetrical relative to the pipeline, laying the pipeline into it, cross-covering the pipeline with the flexible carpets and the bottom of the trench in the location of the broadening, pinching of the edges of the flexible carpets and backfilling of the trench with the fit of the pipeline and flexible carpets to the bottom of the trench it, in which, to increase the reliability of fixing the pipeline in the flooded trench, the trenches are torn to a depth not exceeding the water level in the trench, before the ceiling is covered with flexible carpets, the pipeline is fused or laid in the flooded trench, and to increase the reliability of fixing the pipeline to flexible carpets, symmetrical deflections are preliminarily given and fix them with the formation of a pair of design capacity of the pockets filled with soil, which are placed on both sides of the pipeline.

In addition, the bottom of the broadening trenches is performed with a calculated slope towards or away from the pipeline, the symmetrical deflections of the flexible carpets are fixed using flexible tapes, and the broadening is filled from the edges of the flexible carpets farthest from the pipeline and symmetrically relative to the pipeline with elastic elongation of the flexible carpets.

For pinching in the broadening, equipped with eyes and anchoring elements of the edges of the flexible carpets, textile cylindrical containers placed in the eyes parallel to the pipeline are used, textile containers are filled in the edges of the flexible carpets to the depth of the eyes, they are pre-cut perpendicular to them for inserting anchoring elements into the eyes of the flexible carpets.

The problem is also solved in the method of laying an onshore pipeline on an irrigated area, which consists in laying the pipeline on a day surface of the soil or on a foundation prepared on it, securing it in the design position of the pipeline by filling the soil embankment, in which to increase the reliability of securing the pipeline on irrigated areas at a calculated distance to each other symmetrically relative to the pipeline, pairs of sumps are torn off in the soil, the pipeline, slopes and bottom of the sipes are transversely blocked by flexible carpets for example, backfill, equipped with eyes and anchoring elements, with edge sections of flexible carpets, are jammed in them with soil, and cylindrical textile containers placed in the eyes parallel to the pipeline parallel to the pipeline are used as anchoring elements, while the edges perpendicular to the depth of the eyes are filled with textile perpendicular to them sections, and filling with soil each pair of pits lead in the direction of the pipeline and symmetrically with respect to the pipeline.

In this case, the distance between the pits in the pair is not more than the diameter of the pipeline and not less than the width of its bed. The bottom of the trench broadening is performed with a calculated slope towards or away from the pipeline.

In addition, in the method of laying the pipeline, which consists in laying the pipeline on the day surface of the soil or on the base prepared on it, securing it in the design position of the pipeline by filling the soil embankment, in which, to increase the reliability of securing the pipeline on flooded areas, symmetrically arranged ones are torn off before laying the pipeline in the soil relative to the axis of the pipeline sumps, overlap the pipeline transversely with flexible carpets, slopes and the bottom of the pits, pinch the edge sections of the flexible carpets and when backfilling, the flexible carpets fit to the bottom of the pits, in which, to increase the reliability of fixing the pipeline, flexible carpets are preliminarily given symmetrical deflections and fix them with the formation of a pair of design capacity of pockets filled with soil, the latter are placed on both sides of the pipeline.

Symmetrical deflections of flexible carpets are fixed by means of flexible tapes, and filling of flexible carpets is carried out from their ends farthest from the pipeline and symmetrically with respect to the pipeline with elastic extension of flexible carpets. As anchoring elements, cylindrical textile containers placed in the eyes of flexible carpets parallel to the pipeline are used, and in the marginal sections of the flexible carpets, cuts perpendicular to them are made previously to the depth of the eyes to introduce anchoring elements into the eyes of flexible carpets.

The problem is also solved by the fact that in the device for fixing the pipeline containing a flexible carpet, designed for symmetrical laying on the pipeline, each edge section of the flexible carpet is equipped with a carpet fixation element, and to increase the reliability of fixing the pipeline, flexible carpets are made with symmetrical deflections that are fixed with the formation of a pair of design capacity pockets designed to fill them with backfill soil when placing pockets on both sides of the pipeline, while fixing bends formed by flexible strips, the middle of which is fastened to the middle of the flexible carpet, and the ends are fixed to the tapes of flexible carpet edge portions formed along the edges of their deflections pockets. Each edge section of the flexible carpet is equipped with an eyelet and contains an anchoring longitudinal element located in it parallel to the pipeline. Textile containers filled with soil are used as anchoring elements, and at least one cut to the depth of the eyes is made in the marginal sections of each flexible carpet perpendicular to the eyes for the convenience of introducing anchoring elements into the eyes. Flexible tapes are made of one-, two- or multi-layer, and technical fabric is used as the material of the flexible carpet, the elongation of which at break is 15-38%.

The invention is illustrated in graphic material, in which Fig. 1 shows a pipeline laid in a trench and fastened with flexible carpets with a calculated step along the axis of the pipeline; figure 2 is the same as in figure 1, but with a high level of standing water; figure 3 and 4 - land-laid pipeline.

In this case, the positions indicated:

1 - trench;

2 - broadening;

3 - pipeline;

4 - soil backfill;

5 - flexible carpet;

6 - eye;

7 - anchoring element;

8 - pockets;

9 - flexible tape;

10 - inventory pins;

11 - day surface of the soil;

12 - prepared base for the pipeline

13 - soil embankment;

14 - pits;

15 - geotextile gratings

The method in part of the independent claim 1 is as follows. Trench 1 is torn off with broadening 2 on both sides, while the dimensions of the broadening are determined taking into account the diameter of the pipeline 3, the properties of the backfill soil 4 and the mechanical properties of the flexible carpets 5.

Across the pipeline 3 in each pair of broadening 2, lay a piece of flexible carpet 5, with its middle touching the upper generatrix of pipe 3. Each of the edge sections of the flexible carpet 5 is made with an eye 6, into which the anchoring element 7 is passed parallel to the pipeline 3 - a textile container, extended hard item.

To increase the reliability of fixing the pipeline 3 to the flexible carpets 5, symmetrical deflections are preliminarily attached and fixed to form a pair of the design capacity of the pockets 8 filled with soil, which are placed on both sides of the pipeline. In the initial position, the bottom of the pockets 8 does not fit to the bottom of the trench 1.

The preliminary deflections of the flexible carpets 5 are fixed by means of flexible tapes 9, the middle part of which is bonded to the middle of the flexible carpets 5, and the ends of the tapes 9 are fixed on the edge sections of the flexible carpets 5 along the edges of the pockets formed by their deflections 8. The flexible tapes 9 are made of one-, two- or layered.

One of the edge sections of the flexible carpet 5 is fixed on the broadening bottom 2 with inventory pins 10, the flexible carpet 5 is pulled and its other edge section is fixed with the pins 8, while the bottom of the pockets 8 does not fit to the bottom of the trench 1, after which the flexible carpet 5 is covered with soil 4 on a length of 1-1.5 m, providing a fit to the bottom of the pits of the flexible carpet 5 with its preliminary stretching, and filling with soil with each pair of pockets, widenings and trenches lead in the direction of the pipeline and symmetrically relative to the pipeline.

The pins 10 remove and complete the filling of the broadening 2 with soil 4. Under the weight of the filling soil, the flexible carpet 5 is pre-stretched to ensure that the flexible carpet 5 fits to the bottom of the broadening 2 and trench 1.

Preliminary stretching of flexible carpets creates an additional pipeline loading force, which is especially important in conditions of an irrigated trench during the first 3-5 years of pipeline operation, when the backfill soil was not caked and its ballasting ability was reduced.

The implementation of the broadening with the slope of the bottom towards the pipeline provides a close to vertical position of the carpet branches adjacent to the pipeline, which creates favorable conditions for the carpet branches to stretch and allows additional holding vertical forces to be applied to the pipeline when stretching the flexible carpets.

Performing broadening with a slope of the bottom from the pipeline allows you to increase the thickness of the layer of backfill soil over the edge sections of the flexible carpet and thus increase the pinch force in the soil. The choice of the option to tilt the bottom of the pit depends on the diameter of the anchoring elements, on the degree of watering of the trench and the type of backfill soil.

Performing cuts in the longitudinal edges of the carpet material perpendicular to the eyes to their entire depth facilitates the insertion of anchoring elements into the eyes, especially when the carpet width is significant, when linearly several anchoring elements, e.g. textile containers, are placed in each eye along the entire width of the flexible carpet.

As a material of flexible carpets use technical fabric from polyamide or polyester materials. The specified fabric is delivered rolled with a maximum width of 3 m. If necessary, the panels, depending on the type of material, are sewn with a transverse or longitudinal patch seam. These materials have an elongation at break of 18-38%.

Preliminary stretching for these materials, respectively, is 30-50% of their relative elongation at break and does not exceed the estimated operational elongation of flexible carpets.

For example, to fix a pipeline with a diameter of 1420 mm in a 2.6 m deep waterlogged trench, flexible carpets 6 × 9.8 m in size are required, and the length of a pair of broadening is 7.5 m. The crushing ability of the soil depends on its type, moisture and the thickness of the backfill layer, that is, from deepening carpet material.

As a result of the studies, it was found that the maximum adhesion force of carpet material to the ground when deepening technical fabric

per 1 m, kg / sq. m:

- sand of natural humidity 1200 - waterlogged sand 550 - clay in a refractory state 1350 - clay in a viscoplastic state 400

It was found that the indicated adhesion forces of the technical fabric of flexible carpets and soil increase in proportion to the depth of the carpet material and when the backfill layer thickness is 2 m, the above values increase by 2 times.

The use of a textile container as an anchoring element many times increases the resistance to pulling carpet material from the backfill soil under the influence of the buoyancy force of water or during operational movements of the pipeline, since the anchoring element has a significant frontal resistance surface with pulling force. In addition, currently the technology for manufacturing textile containers is well mastered and they are widely used in the construction of trunk pipelines as ballasting or supporting elements.

A variant of the method of laying the pipeline in a trench with a high level of standing water according to the independent claim 6 of the formula is as follows. Trench 1 is opened with the formation of pairs of broadens symmetrical with respect to the axis of the trench located at a calculated distance from each other 2. To increase the reliability of fixing the pipeline 3 in the flooded trench, 1 pair of trenches symmetrical with respect to the axis of the trench and the pipeline broadening 2 trenches are torn to a depth not exceeding the water level in the trench . To increase the reliability of fixing the pipeline 3 to the flexible carpets 5, symmetrical deflections are preliminarily attached and fixed to form a pair of the design capacity of the pockets 8 filled with soil, which are placed on both sides of the pipeline. In the initial position, the bottom of the pockets 8 does not fit to the bottom of the trench 1.

Before overlapping with flexible carpets 5, the pipeline 3 is fused or laid in the flooded trench 1. For its immersion and laying on the bottom of the trench, as an anchoring element 7, in broadening, cylindrical textile containers filled with soil are placed in the eyes of the pipeline parallel to the pipeline.

Before the edge sections of the flexible carpets 5 are pinched, each of the edge sections is pulled with tension fixation with the inventory pins 10. Preliminary design stretching of the flexible carpets is carried out when filling pockets, broadening and trench with soil while immersing the pipeline. At the same time, the pipeline and flexible carpets fit to the bottom of the trench, and the soil is filled with soil of each pair of pockets, broadening and trench in the direction of the pipeline and symmetrically with respect to the pipeline. The conditions for filling pockets and broadening, extraction of inventory pins and the final filling of the trench are similar to the conditions of a variant of the method for laying a pipeline according to independent claim 1 of the claims.

A variant of the method of surface laying of the pipeline according to the independent claim 11 of the formula is as follows. After the route is prepared, the pipeline is laid on the day surface of the soil 11 or on the base 12 prepared on it, while the lower generatrix of the pipeline 3 has a mark at the level of the day surface or higher if the pipeline is laid on the soil cushion-base 12. Fastening in the design position of the pipeline is carried out by dumping embankment 13.

To increase the reliability of securing the pipeline on irrigated areas, pits 14 are opened in the soil previously at a calculated distance from each other and symmetrically relative to the pipeline. The distance between the pits in a pair is not more than the diameter of the pipe 3 and not less than the width of its bed.

It is possible to extract one pit with a bulldozer of a length equal to the sum of the lengths of the pits 12 and dumping in the middle of the base 12 for pipeline 3.

Transverse 3 overlap the pipeline 3, its base and the bottom of the sumps with flexible carpets, for which a segment of the flexible carpet 5 is laid, with its middle touching the upper generatrix of the pipeline 3. To increase the reliability of the pipeline 3, the flexible carpets 5 are pre-attached with symmetrical deflections and fix them with formation pairs of the design capacity of the pockets filled with soil 8, which are placed on both sides of the pipeline. In the initial position, the bottom of the pockets 8 does not fit to the bottom of the pits 14.

Each of the edge sections of the flexible carpet 5 is made with an eye 6, into which an anchoring element 7, for example a textile container, is passed parallel to the pipe 3. One of the edge sections of the flexible carpet 5 is fixed at the bottom of the sumps 14 with inventory pins 10, the flexible carpet 5 is pulled and fixed with its other edge section with the pins 10, after which the flexible carpet 5 is covered with soil 4 over a length of 1-1.5 m, which ensures fit to the slopes and the bottom of the pit pits 8 of the flexible carpet 5 with its preliminary stretching, and filling each pair of pockets, pits with soil and filling the embankment 13 lead in the direction of the pipeline and symmetrically with respect to the pipeline. The pins 10 are removed and the filling of the pits 14 with the soil of the embankment 13 is completed.

Under the weight of the backfill soil and the embankment soil, the flexible carpet 5 is pre-stretched to ensure that the flexible carpet 5 adheres to the slopes and bottom of the pits 14.

The working conditions of flexible carpets, backfill soil, the choice of materials and fastening elements of the pipeline are similar to those specified in the embodiment of the method of laying the pipeline in an irrigated trench.

A variant of the method of surface laying of the pipeline according to the independent claim 16 of the formula is as follows. After the route is prepared, the pipeline is laid on the day surface of the soil 9 or on the base 12 prepared on it, while the lower generatrix of the pipeline 3 has a mark at the level of the day surface or higher, if the pipeline is laid on an earth cushion - the base 12. Fastening in the design position of the pipeline 3 is carried out by filling the soil embankment 13. The pipeline 3, its base and the day surface of the soil 9 are previously transversely blocked by laying sections of the flexible carpet 5, with the middle of each touching The main component of the pipeline 3. To increase the reliability of fixing the pipeline 3 to the flexible carpets 5, symmetrical deflections are preliminarily attached and fixed to form a pair of calculated capacity of the pockets 8 filled with soil, which are placed on both sides of the pipeline. In the initial position, the bottom of the pockets 8 does not adhere to the surface of the soil 11.

Each of the edge sections of the flexible carpet 5 is made with an eye 6, into which an anchoring element 7, for example a textile container, is passed parallel to the pipe 3.

One of the edge sections of the flexible carpet 5 is fixed on the day surface of the soil 11 with inventory pins 10. The flexible carpet 5 is pulled and secured to its other edge section with the pins 10, after which the flexible carpet 5 is covered with embankment soil 13 over a length of 1-1.5 m from the anchoring elements 7. Soil filling each pair of edge sections of the flexible carpet 5, its pockets 8 are in the direction of the pipeline 3 and symmetrically relative to the pipeline 3 to create symmetrical forces in the branches of the flexible carpet 5, additionally loading the pipeline 3.

The pins 10 remove and complete the filling of the soil embankment 13. Under the weight of the soil of the embankment, the flexible carpet 5 is pre-stretched to ensure that the flexible carpet 5 adheres to the soil surface.

In the considered option of laying the pipeline, it is possible to use shortened flexible carpets with the placement of anchoring elements in the slopes of the embankment. The additional force created by stretching the flexible carpets, loading the pipeline, ensures a stable position of the pipeline until the natural compaction of the embankment soil.

To prevent exposure of anchoring elements due to possible erosion and subsequent destruction of the embankment, geotextile gratings 15 (geogrids) filled with soil should be used to strengthen it. The geogrid 15 is a honeycomb structure made of textile material with hexagonal cells, which are formed when stitching in a staggered manner parallel ribbons spaced paired seams.

When constructing the pipeline according to the previously mentioned options, a device for securing the pipeline is used, containing a segment of flexible carpet imposed symmetrically on the pipeline, each parallel to the pipeline, the edge section of which is provided with an eye and contains an anchoring longitudinal element placed in it parallel to the pipeline. Cylindrical textile containers filled with soil are used as anchoring elements. In the marginal sections of the flexible carpet perpendicular to the eyes, at least one cut is made to the depth of the eyes to facilitate the insertion of textile containers into the eyes. The cuts of the eyes allow the introduction into each of them of textile containers located in a line with a considerable width of flexible carpets. To increase the reliability of fixing the pipeline, flexible carpets are made with symmetrical deflections, which are fixed with the formation of a pair of design pockets capacity, designed to fill them with backfill soil when placing pockets on both sides of the pipeline. The deflection was fixed by means of flexible tapes, the middle part of which is fastened to the middle of the flexible carpets, and the ends of the tapes are fixed on the edge sections of the flexible carpets along the edges of the pockets formed by their deflections.

As a material of a flexible carpet, a technical fabric with a relative elongation at break of 15-38% is used.

The textile container is made in the form of a soft container filled with soil, the length of which exceeds its diameter. The tank has an end loading sleeve and load-lifting loops fixed to the tank shell symmetrically to the longitudinal axis. The tank shell is formed by fastening the transverse edges of the panel with a connecting seam. The lower and upper ends are formed of panels fastened by their curved edges with a shell.

Thus, as a result of the jamming of the edge sections of flexible carpets with backfill soil, it is possible, due to the preliminary stretching of the flexible carpets, to create an additional force that loads the pipeline, which is especially important in conditions of flooding the pipeline during the first 3-5 years of its operation, when the backfill soil did not caking and it ballasting ability reduced.

Claims (21)

1. The method of laying the pipeline, which consists in extracting the trench with the formation at the calculated distance from each other of pairs of trenches symmetrical with respect to the pipeline, broadening the trench, laying the pipeline in it, transverse overlapping of the pipeline with the flexible carpets and the bottom of the trench at the locations of the broadening, pinching of the edges of the flexible carpets, reverse backfilling of the trench and pits with ensuring the fit of flexible carpets to the bottom of the pits and trenches, characterized in that to increase the reliability of fixing the pipeline to flexible carpets they re-attach symmetrical deflections and fix them with the formation of a pair of design capacity of pockets filled with soil, which are placed on both sides of the pipeline. 2. The method according to claim 1, characterized in that the bottom of the broadening of the trench is performed with a calculated slope away from the pipeline. 3. The method according to claim 1, characterized in that the bottom of the broadening of the trench is performed with a calculated slope towards the pipeline. 4. The method according to claim 1, characterized in that the symmetrical deflections of the flexible carpets are fixed by means of flexible tapes. 5. The method according to claim 1, characterized in that the broadening is carried out from the ends farthest from the pipeline and symmetrically relative to the pipeline with elastic extension of the flexible carpets. 6. The method of laying the pipeline, which consists in extracting the trench with the formation of trench broadening symmetrical with respect to the pipeline, laying the pipeline, transverse overlapping of the pipeline with the flexible carpets and the bottom of the trench at the location of the broadening, pinching the edges of the flexible carpets and back filling the trench with the fit of the pipeline and flexible carpets to the bottom of the trench, characterized in that to increase the reliability of securing the pipeline in the bypass In this broadening trench, trenches are torn to a depth not exceeding the water level in the trench, before the pipeline is covered with flexible carpets, they are fused or laid in a flooded trench, and to increase the reliability of fixing the pipeline, flexible carpets are pre-attached with symmetrical deflections and fixed with the formation of a pair of design capacity filled with soil pockets that are placed on both sides of the pipeline. 7. The method according to claim 6, characterized in that the bottom of the broadening of the trench is performed with a calculated slope away from the pipeline. 8. The method according to claim 6, characterized in that the bottom of the trench broadening is performed with a calculated bias towards the pipeline. 9. The method according to claim 6, characterized in that the symmetrical deflections of the flexible carpets are fixed by means of flexible tapes. 10. The method according to claim 6, characterized in that the broadening is carried out from their ends farthest from the pipeline and symmetrically with respect to the pipeline with elastic extension of the flexible carpets. 11. The method of laying the pipeline, which consists in laying the pipeline on the day surface of the soil or on a foundation prepared on it, securing it in the design position of the pipeline with a filling of the soil embankment, characterized in that to increase the reliability of securing the pipeline on irrigated areas, symmetrically arranged ones are torn off before laying the pipeline in the soil relative to the axis of the pipeline sumps, overlap the pipeline transversely with flexible carpets, slopes and the bottom of the pits, pinch the edge sections of the flexible carpets and during backfill, flexible carpets fit to the bottom of the pits, characterized in that to increase the reliability of fixing the pipeline, flexible carpets are pre-attached with symmetrical deflections and fixed with the formation of a pair of design capacity of pockets filled with soil, the latter are placed on both sides of the pipeline. 12. The method according to claim 11, characterized in that the bottom of the pits is performed with a calculated slope away from the pipeline. 13. The method according to claim 11, characterized in that the bottom of the pits is performed with a calculated bias towards the pipeline. 14. The method according to claim 11, characterized in that the symmetrical deflections of the flexible carpets are fixed by means of flexible tapes. 15. The method according to claim 11, characterized in that the broadening is filled up from their ends farthest from the pipeline and symmetrically relative to the pipeline with elastic elongation of the flexible carpets. 16. The method of laying the pipeline, which consists in laying the pipeline on the day surface of the soil or on a foundation prepared on it, securing it in the design position of the pipeline with a filling of the embankment, characterized in that to increase the reliability of securing the pipeline on the flooded sections, the pipeline is transversely symmetrically transverse to the pipeline by flexible carpets and soil surface, pinch the edge sections of flexible carpets, and to increase the reliability of fixing the pipeline to flexible carpets Attach symmetrically deflections and fix them with the formation of a pair of design capacity of pockets filled with soil; the latter are placed on both sides of the pipeline. 17. The method according to clause 16, characterized in that the symmetrical deflections of the flexible carpets are fixed by means of flexible tapes. 18. The method according to clause 16, characterized in that the filling of the flexible carpets is carried out from their ends farthest from the pipeline and symmetrically with respect to the pipeline with elastic extension of the flexible carpets. 19. A device for securing a pipeline, comprising a flexible carpet intended for laying on the pipeline, each edge portion of which is provided with a carpet fixation element, characterized in that, to increase the reliability of the pipeline fixing, the flexible carpets are made with symmetrical deflections that are fixed with the formation of a pair of design pockets capacity, designed to fill them with backfill soil when placing pockets on both sides of the pipeline, while the deflection is fixed by means of flexible tapes, with ednyaya of which is fastened to the middle of the flexible carpet, and the ribbons attached to the edge portions of the flexible carpet along the edges formed their deflections pockets. 20. The device according to claim 19, characterized in that the flexible tape is made one, two or multi-layer. 21. The device according to claim 19, characterized in that the technical fabric is used as the material of the flexible carpet, the elongation of which at break is 15-38%.

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