RU119836U1 - UNDERGROUND PIPELINE COMPENSATION SECTION - Google Patents

Abstract

1. Compensation section of the underground pipeline, including the pipeline, located in the middle part of the sand filler layer in a trench made with gentle slopes, while the sand filler is enclosed in a geomembrane shell with a thickness of 2.0-3.0 mm. ! 2. The compensating section of the underground pipeline according to claim 1, in which drainage is made from gravel material and at least one perforated drainage pipe in the lower part of the sand filler layer. ! 3. The compensation section of the underground pipeline according to claim 1, in which the geomembrane shell is supplemented, on at least one side, with a nonwoven geotextile fabric. ! 4. The compensation section of the underground pipeline according to claim 1, in which the exit of the underground pipeline from the compensation section is made with a cuff made of a geomembrane, hermetically connected to a shell made of a geomembrane. ! 5. The compensation section of the underground pipeline according to claim 1, in which the depth of the trench is more than two outer diameters of the pipeline. ! 6. The compensation section of the underground pipeline according to claim 1, in which the slopes of the trench are made at an angle of 20-50 ° to the bottom of the trench. ! 7. Compensation section of the underground pipeline according to claim 1, made selected from the group: slightly curved, trapezoidal, U-, Z- or L-shaped.

Description

The utility model relates to construction and can be used when laying underground pipelines in areas with increased seismicity, as well as in areas of permafrost.

The utility model can be used in laying production pipelines connecting oil wells with various oil and gas refining facilities, in the construction of trunk pipelines used for pumping oil and oil products from points of their production, refining or storage to places of consumption and in the construction of process pipelines transporting materials and substances of various types, including aggressive, within the same enterprise or between enterprises of the same industry

It is known that even small amounts of oil products when released into water can cause significant damage, not to mention large spills and the possibility of ignition of gases coming from a damaged pipeline.

These circumstances require the absolute reliability of the design of pipelines, ensuring their long-term and trouble-free operation. This task is complicated by the conditions for the construction of pipelines in areas with increased seismicity, areas of permafrost distribution, as well as an increase in the diameters of main pipelines and working pressures in them.

When the soil moves, cracks, discharges, dips and landslides form, sometimes the movement of the soil takes disastrous sizes. In other cases, only small and invisible to the eye deformations of the soil occur without cracking — plastic deformations. At the same time, plastic deformations occur incomparably more often and almost always precede more significant soil movements.

Soil movements cause bending deformation, kink, pipe cut or axial deformation at the points where the pipeline joins tanks, wells, linear valves, various equipment or pipelines of a different direction.

It is known that the greatest impact on the pipeline is exerted by the movement of the soil, the direction of which coincides with the direction of the pipelines, while these fractures are caused by tensile forces arising in the pipelines trapped in the soil.

The values of deformations and stresses in the pipeline are largely determined by the nature of the interaction of the soil and the pipeline, which in turn depends on the design features of the pipeline, the physical and mechanical properties of the soil, the density of the trench backfill, the nature of the transfer of friction forces and other forces transferred from the soil to the pipeline.

Known devices for damping pipeline vibrations under various environmental influences (RU 2220357 C2, 09/10/2003; SU 1827494 A1, 07.15.1993; SU 1682709 A1, 07.10.1991; SU 1828839 A1, 07.23.1993).

A disadvantage of the known devices is a complex material-intensive design, which leads to unjustified costs for their construction.

A known method of laying an underground pipeline (RU 2250409 C1, 04/20/2005). In a known solution, sections of the pipeline with locking nodes are located in channels that are formed from water-permeable soil-erosion-proof containers (KPs), for which a trench of increased width is torn off at the locations of the locking nodes — widenings, within which the walls and the bottom of the trench are lined with sheets of technical fabric , they are installed vertically in at least one tier of the control box, the pipeline is laid on sliding supports installed with a calculated pitch - soil-filled container devices (GUK), before fill the trench with soil by blocking the channel from above with a power membrane equipped with anchoring elements, while the width of the KP row and its height are not less than the diameter of the pipeline, and a clearance is created between the outer surface of the locking nodes or pipeline and the inner surface of the specified channel, and filling the trench will be introduced symmetrically from longitudinal relative to the pipeline edges of the power membrane to the pipeline.

Known compensation section of the underground pipeline for areas with active seismotectonic zones (RU 2271889 C2, 12/10/2004), which is the closest to the claimed solution. The compensation section is a pipeline placed in a trench made with gentle slopes. The depth of the trench is 2.5-4 of the outer diameter of the pipeline, while the pipeline is located in the middle of the sand filler layer filling the trench to a height of at least two outer diameters of the pipeline, and washed river sand of medium size or large, not containing, is used as a sand filler dusty or clay fractions or coarse admixture.

Known devices provide a reduction in the impact of soil movements on the pipeline, however, they do not provide reliable isolation from underground water (including capillary rise) falling into the filling of the pipeline, and localization of the spill of transported products in case of damage to the pipeline.

The claimed utility model solves the problem of ensuring the possibility of soil displacement relative to the compensation section of the pipeline without significant deformation and destruction of the pipeline, and also provides a uniform water-thermal regime and stability of the soil of the base under the pipeline.

The technical result is to increase the operational reliability of the pipeline.

The specified technical result is achieved by the compensation section of the underground pipeline, including the pipeline, located in the middle part of the sand filler layer in a trench made with gentle slopes, while the sand filler is enclosed in a shell made of geomembrane with a thickness of 2.0-3.0 mm.

In the lower part of the sand filler layer, drainage of gravel material and at least one perforated drainage pipe can be made.

The geomembrane casing may be supplemented, at least on one side, with a geotextile non-woven fabric.

The exit of the underground pipeline from the compensation section can be performed with a cuff from the geomembrane sealed to the sheath of the geomembrane.

The depth of the trench can be more than two external diameters of the pipeline, the slopes of the trench can be made at an angle of 20-50 ° to the bottom of the trench.

The compensation section can be made selected from the group: slightly curved, trapezoidal, U-, Z- or L-shaped.

Practice has shown that under the conditions of possible external influences and the stresses and ground displacements caused by them, the best conditions for the redistribution and equalization of stresses arising in the pipeline ensure that the tilt slopes of the trench to the bottom from 20 to 50 ° are fulfilled. Moreover, reducing the angle below 20 ° is impractical, due to the increase in the volume of earthwork. At an angle of more than 50 °, the compensatory properties of the trench with the appropriate action do not allow avoiding the appearance of pipeline deformations, which can lead to its destruction during operation or to rupture with significant soil movements.

Sand filler can fill the trench to a height of at least two outer diameters of the pipeline. As a sand filler, washed river sand can be used.

Placing the pipeline in a layer of sand filler creates conditions for the "mobility" of the pipeline. The uniformity of the spatial distribution of stresses in the pipeline is ensured by the gentle slopes of the trench and the placement of the pipeline in the middle of the sand filler layer.

The rest of the upper part of the trench can be filled with soil or sand over the entire height of the trench.

The pipeline may be made of metal or plastic, or a combination thereof.

The geomembrane shell provides isolation of the filler from moisture and localization of the spill of transported products in case of damage to the pipeline.

The invention is illustrated by drawings.

Figure 1 shows a cross section of the compensation section with the pipeline located in it. The pipeline (1) is placed in a trench (2), the sand filler (3) is enclosed in a shell made of geomembrane (4).

Figure 2 - shows the exit of the underground pipeline from the compensation section, made with a cuff (5) from the geomembrane.

Claims (7)

1. The compensation section of the underground pipeline, including the pipeline, located in the middle part of the layer of sand filler in a trench made with gentle slopes, while the sand filler is enclosed in a shell made of geomembrane with a thickness of 2.0-3.0 mm 2. The compensation section of the underground pipeline according to claim 1, in which in the lower part of the sand filler layer drainage is made of gravel material and at least one perforated drainage pipe. 3. The compensation section of the underground pipeline according to claim 1, in which the shell of the geomembrane is supplemented, at least on one side, with a geotextile non-woven fabric. 4. The compensation section of the underground pipeline according to claim 1, in which the exit of the underground pipeline from the compensation section is made with a cuff of the geomembrane sealed to the sheath of the geomembrane. 5. The compensation section of the underground pipeline according to claim 1, in which the depth of the trench is more than two outer diameters of the pipeline. 6. The compensation section of the underground pipeline according to claim 1, in which the slopes of the trench are made at an angle of 20-50 ° to the bottom of the trench. 7. The compensation section of the underground pipeline according to claim 1, made selected from the group: slightly bent, trapezoidal, P-, Z- or L-shaped.