RU45498U1 - MUKHAMETDINOV POLYMERCONTAINER BALLASTING DEVICE (PKBU MK) (OPTIONS) - Google Patents

Abstract

The utility model relates to the construction of pipeline transport and is used when laying underground trunk pipelines in the conditions of the spread of permafrost soils, when laying pipelines in swamps, as well as in irrigated areas. Mukhametdinov’s polymer-container ballasting device (PKBU-MK) contains two containers on the both sides of the pipeline and filled with soil from panels of polymer technical fabric, each of which is equipped with stiffening frames and partitions, as well as power belts, in the eyes of which are placed the runs of stiffening frames, in which the lower power belt and the tanks filled with soil are made in the form of a composite or single, superimposed on the pipeline pipeline, provided with eyes to accommodate longitudinal of stiffness frames, and each partition is fastened with a cloth forming a container and the corresponding upper power belt, while the lower part of each frame relative to the bottom of the trench is placed with a slope towards the pipeline without resting on it and on the ground of the bottom of the trench when filling containers with soil, as well as the impact of the buoyant load on the pipeline, which is ensured by the estimated length of the lower power belt between the eyes for the lower runs of the stiffness frames and the length of the upper power belts, the latter being sewn to lower power belt in its middle part. PKBU-MK increases the reliability of the ballasting of the pipeline and eliminates the possibility of damage to its insulation during construction and operation.

Description

The utility model relates to the construction of pipeline transport and is used when laying underground trunk pipelines in the conditions of the spread of permafrost soils, when laying pipelines in swamps, as well as in irrigated areas.

An analogue of the claimed utility model is known from the prior art — a weighting device for laying an underground pipeline, comprising a pair of containers symmetrically hung on the pipeline and filled with soil, each of which is composed of a rigid frame and a semi-cylindrical container made of flexible material suspended from it (SU 769178 A, 1978, F 16 L 1/06).

The known weighting agent is used for group ballasting of pipelines, while the weighting agents in the group are fastened to the end cross-members of the frames. A disadvantage of the known solution is the increased consumption of material on the end walls of the containers, since both adjacent walls of the containers perform one function — they are separators for the backfill soil.

An analogue of the claimed device is also a pipeline weighting agent, known from patent RU 2164636 C1, 03/27/2001, F 16 L 1/06.

The weighting agent contains a pair of containers, each of which is composed of a rigid flat frame and a semi-cylindrical frame made of a flexible material of a container suspended from it.

The tanks are multisectional along the axis of the pipeline, the sections are separated by intermediate transverse walls and frame spacers.

The containers of the weighting agent are interconnected by a bond imposed on the pipeline — power belts made of flexible material and fixed by ends to the external runs of the frames.

A disadvantage of the known solution is the increased consumption of backfill soil. When weighting agents are installed in the group (with continuous ballasting of the pipeline) under the influence of the backfill of the cloth, the forming containers are deformed and wedge-shaped gaps arise between the neighboring weighting agents in which the ballasting soil of the backfill wakes up.

Known pipeline weighting agent containing a V-shaped pair of concrete blocks suspended on the pipeline by means of power belts and resting the lower part on the bottom of the trench. In each of the blocks a blind cavity was opened, open at the top, creating an additional volume filled with backfill soil (see SU 1710913 A1, 02/07/1992).

A disadvantage of the known solution is the possibility of damage to the insulation of the pipeline, increased consumption of concrete and significant costs in the manufacture of weighting compounds and when transporting them to the place of construction of the pipeline.

Closest to the claimed utility model is the weighting of the pipeline, known from SU 1551930 A1, 03/23/1990. Known weighting agent contains placed symmetrically relative to the longitudinal axis of the pipeline tanks with rigid rectangular frames - frames.

The longitudinal walls of the tanks are suspended from the frames and are made of strips of flexible material.

The weighting compound is equipped with a pair of flexible jumpers forming the walls of the tanks.

A disadvantage of the known solution is the low ballasting ability of the weighting agent, increased metal consumption, the possibility of damage to the insulation of the pipeline.

The problem solved by the claimed utility model is to increase the reliability of the pipeline ballasting due to the full involvement of the trench backfill and eliminating possible damage to the pipeline insulation by rigid frame elements during construction, operation and repair of the pipeline.

This problem is solved by the fact that the Mukhametdinov polymer container ballasting device (PKBU-MK) contains two containers on the both sides of the pipeline and filled with soil from the panels of polymer technical fabric, each of which is equipped with stiffening frames and partitions, as well as power belts, in the eyes of which runs of the stiffness frames are placed, in which the lower power belt and the tanks filled with soil are made in the form of a single sheet imposed on the pipeline equipped with eyes for placement in x longitudinal runs of the stiffening frames, and each partition is fastened to a container forming a container and the corresponding upper power belt, while the lower part of each frame relative to the bottom of the trench is placed with a slope towards the pipeline without resting on it and on the ground of the bottom of the trench when filling the tanks with soil, and also when the pipeline is exposed to a buoyant load, which is ensured by the estimated length of the lower power belt between the eyes for the lower runs of the stiffness frames and the length

upper power zones, the latter being sewn to the lower power belt in its middle part.

The difference between the claimed utility model is that the lower power belts and the tanks filled with soil are made in the form of a single panel imposed on the pipeline equipped with eyes for placing the lower and upper longitudinal runs of the stiffening frames in them, and each partition is fastened with a panel forming the container and the corresponding upper with a power belt, while the lower part of each frame relative to the bottom of the trench is placed with a slope towards the pipeline without resting on it and the soil of the bottom of the trench when filling the tanks Runt and when subjected to a load line of the ejector, provided that the calculated length of the lower belt force between the eyelets of the lower runs of stiffness and length of upper frames power belts, the latter sewn to the lower belt force in its middle part.

This problem is solved by the embodiment of PKBU-MK, wherein the polymer container ballasting device, containing two containers placed on both sides of the pipeline and filled with soil from the panels of polymer technical fabric, each of which is equipped with stiffening frames and partitions, as well as power belts in the eyes of which longitudinal elements are placed - runs of stiffness frames, in which the lower power belt and the tanks filled with soil are made in the form of a composite; a sheet imposed on the pipeline, provided with eyes to accommodate the runs of the stiffening frames in them, and each partition is fastened to a container forming a container and the corresponding upper and lower power belt, while the lower part of each frame relative to the bottom of the trench is placed with a slope towards the pipeline without resting on it and on the soil of the bottom of the trench at

filling the tanks with soil, as well as when a pushing load is applied to the pipeline, which is ensured by the estimated length of the lower power belt between the eyes for the lower runs of the stiffness frames and the length of the upper power zones, the latter being sewn to the lower power belt in its middle part.

A particular case of the utility model is that the eyes for placing the lower runs of the stiffness frames in them are formed by bent and stitched edges of a fabric made of polymer technical fabric that is applied to the pipeline and forming the lower power belt.

This problem is also solved by the fact that the eyes for placing the upper runs of the stiffening frames in them are formed by the bent and stitched edges of the capacity-forming panels of polymer technical fabric, symmetrically sewn to the panel of the lower power belt.

In addition, this problem is also solved by the fact that the upper power upper power belts are equipped with eyes and are formed by single-layer or folded and stitched in several layers ribbons of polymer technical fabric, and the number of upper power belts of each capacity is at least two.

A particular case of the utility model is that the eyes of a single panel are formed by single-layer or folded into several layers and stitched with tapes of polymer technical fabric sewn to a single panel imposed on the pipeline.

In addition, the eyes for placing the lower longitudinal runs of the stiffening frames in them are formed by the bent edges of the additional cloth made of polymer technical fabric sewn to a single cloth imposed on the pipeline.

In addition, the upper eyes of a single panel are formed by its bent and stitched edges.

In the particular case of the implementation of the device, the rigid frames are provided with additional transverse reinforcing elements and are made of collapsible tubular elements with the possibility of longitudinal connection of the device frames during group use of weighting agents for ballasting the pipeline.

For the longitudinal connection of the frames during group ballasting of the pipeline, the longitudinal sides of the frames of rigidity are equipped with embedded elements-inserts with the possibility of their fixation during group ballasting of the pipeline.

In the particular case of the device, the spacer elements of each stiffening frame are pre-stressed with a curved shape, with a calculated bend in a plane parallel to the longitudinal axis of the pipeline.

The implementation of the upper power belts in the form of multilayer and stitched tapes with eyes located on the outer (upper) longitudinal sides - runs of stiffness frames, increases the reliability of fixing the device to the pipeline.

The presence of the end walls of the containers bonded to the upper power belts and a single panel increases the reliability of ballasting due to a more complete filling of the device volume with soil and eliminates the rash of backfill soil through the ends of the weighting agent.

Tubular elements of the frame of the stiffness frames provide ease of assembly, especially when the group ballasting of the pipeline, for which in the cavity of the longitudinal elements of the adjacent frames of rigidity - runs injected mortgages and fix them.

The utility model is illustrated by graphic material, where in Fig. 1 the claimed device is shown, in Fig. 2 and Fig. 3 is a cross-sectional view of variants of the textile part of PKBU-MK (partitions are not shown), and the positions respectively indicate:

1 - pipeline;

2 - soil backfill;

3 - capacity PKBU-MK;

4 - framework rigidity;

5 - partitions;

6 - upper power zones;

7 - lower power belt;

8 - trench;

9 - upper longitudinal sides - run of the stiffness frames;

10 - lower (inner) longitudinal sides - run frames of stiffness;

11 - eyes;

PKBU-MK contains two filling tanks 2 located on both sides of the pipeline 1, filled with soil, 3 containers made of polymeric technical fabric panels. Each of these containers 3 is equipped with stiffening frames 4 and partitions 5, as well as, respectively, the upper and lower power belts 6 and 7.

In the particular case of the implementation of PKBU-MK, the stiffening frames are pre-stressed by giving them a curved shape,

with the calculated bend of each frame of rigidity in a plane parallel to the longitudinal axis of the pipeline. The convexity of each stiffening frame is directed towards the day surface.

The upper power zones are provided with eyes and are formed by single-layer or folded in several layers ribbons of polymer technical fabric, and the number of upper power zones of each capacity is at least two. The upper power zones are sewn to the lower power zone in its middle part.

The lower power belt 7 and the containers 3 filled with soil are made in the form of a single panel imposed on the pipeline equipped with eyes 11 for placing longitudinal runs 9, 10 of stiffness frames 4 in them, and each partition - the end wall is fastened with a single panel forming the container and the corresponding upper power belt 6.

The bottoms of tanks 3, partitions 5, power belts 6, 7 are made of a flexible material panel - polymer technical fabric.

The end walls of the tanks are made in the form of partitions 5 sewn into the bottoms of the tanks and sewn with the upper power belts 6, which eliminates the filling of soil from the tanks.

Rigid frames 4 are made collapsible from tubular elements with the possibility of longitudinal connection of the device frames when group using PKBU-MK for ballasting the pipeline.

In the embodiment PKB-MK, the lower power belt 7 and the tanks 3 filled with soil are made in the form of a composite, superimposed on the pipeline pipeline, provided with eyes 11 for placement of runs 9,

10 frames of rigidity 4, and each partition 5 is bonded to the container forming the container and the panel of the lower power belt. A particular case of the utility model is that the eyes for placing the lower runs of the stiffness frames in them are formed by bent and stitched edges of a fabric made of polymer technical fabric that is applied to the pipeline and forming the lower power belt.

In the particular case of performing PKBU-MK, the eyes for placing the upper runs of the stiffening frames in them are formed by the bent and stitched edges of the capacity-forming panels of polymer technical fabric, symmetrically sewn to the panel of the lower power belt.

When the ballasting of the pipeline, the stiffening frames are inclined, do not contact the lower longitudinal sides of the runs with the pipeline, with the bottom of the trench, which is provided by the estimated length of the lower power belt between the eyes for the lower runs of the stiffness frames and the length of the upper power zones.

The longitudinal edges of a single flexible panel, forming containers, envelope the lower runs of the stiffness frames and are fastened to the longitudinal sides, upper relative to the pipeline, by the stiffness frames. In this case, the distance between the upper and lower eyes of a single / composite flexible panel exceeds the distance between the upper and lower runs of the stiffening frames, as a result of which the calculated volume of the tank is formed. In addition, the perimeter of each partition 5 (end wall) exceeds the corresponding curvilinear perimeter, made up by the edge of the lower power belt,

capacity and the upper power belt, which increases the volume of tanks filled with soil.

In the upper corners of the frames, the eyes of the upper power belts are fixed, for which the upper eyes of the single / composite flexible panel come together to form folds of the specified panel.

If there are more than two power belts for each tank, then the intermediate eyes of the power belts are placed in cutouts made in the upper longitudinal edge of a single panel.

Tanks 3 PKBU-MK are symmetrically placed relative to pipeline 1. Runs of stiffeners located along the pipeline, as well as their cross members, are made of tubular elements. This embodiment of the stiffness frames simplifies their transportation and installation.

The stability of the PKBU-MK on the pipeline is ensured by the size of the upper power belt, as well as the estimated length between the eyes for the lower runs of the stiffness frames, due to which the stiffness frames do not contact their lower runs with the pipeline and the soil of the bottom of the trench.

The tanks PKBU-MK are filled with soil sequentially, preferably symmetrically, which prevents the tanks from skewing relative to the pipeline. The load bending in the plane of the stiffening frames is compensated by their prestress due to the specified design bending of the stiffening frames.

In group use of PKBU-MK, up to four weighting agents are used in a group to ballast a pipeline, while the number of groups per kilometer of pipeline is from 40 to 50.

A special case of laying a pipeline is the implementation of trenches of increased depth, which is typical for icy soils in the North. Since the trench has an increased depth relative to the recommended SNiP, the parts of the ballasting device - PKBU-MK protruding above the upper generatrix of the pipeline do not affect the increase in the volume of earthwork. In this case, it is advisable to use PKBU-MK with an increased size of tanks for ballasting soil, for which the transverse elements of the stiffening frames perform an increased length. When ballasting, the upper longitudinal elements of the frames of rigidity are located above the upper generatrix of the pipeline by 10-20 cm. In this case, it is permissible to touch the upper runs of the frames of rigidity and the walls of the trench.

In the claimed utility model PKBU-MK, to reduce material consumption and ensure central application of load capacitances are made in the form of "parachute membranes" symmetrically positioned relative to the pipeline, stretched over the forming elements - stiffening frames.

The main bearing element - the bottom of the containers, being membranes, work only in tension. The resistance to pulling the pipeline out of the soil when exposed to operational loads is the sum of the mass of the soil column (cone or bulging cylinder) above PKBU-MK.

The utility model is technological in manufacturing, with low dead weight and simple assembly, it is convenient for transportation and installation on the pipeline, and also effective in laying and operating pipelines in various climatic conditions.

Mukhametdinov’s polymer-container ballasting device (PKBU-MK) improves the reliability of pipeline ballasting and eliminates the possibility of damage to its insulation during construction and operation.

Claims (19)

1. Polymer container ballasting device, containing two containers placed on both sides of the pipeline and filled with soil from panels of polymer technical fabric, each of which is equipped with stiffening frames and partitions, as well as power belts, in the eyes of which are placed the frames of stiffness, characterized in that the lower power belt and the tanks filled with soil are made in the form of a single panel imposed on the pipeline equipped with eyes for placement of longitudinal runs of stiffness frames in them, and Each partition is fastened with a cloth forming a container and the corresponding upper and lower power belt, while the lower part of each frame relative to the bottom of the trench is placed with a slope towards the pipeline without resting on it and on the ground of the bottom of the trench when filling containers with soil, as well as when acting on the pipeline buoyancy load, which is ensured by the estimated length of the lower power belt between the eyes for the lower runs of the stiffness frames and the length of the upper power zones, the latter being sewn to the lower forces th belt in its middle part. 2. The device according to claim 1, characterized in that the upper power zones are formed by single-layer or folded in several layers and stitched ribbons of polymer technical fabric. 3. The device according to claim 1, characterized in that the number of upper power zones of each capacity is at least two. 4. The device according to claim 1, characterized in that the eyes of a single panel are formed by single-layer sewn to it or folded into several layers and stitched with tapes of polymer technical fabric. 5. The device according to claim 1, characterized in that the eyes for placing the lower longitudinal runs of the stiffening frames therein are formed by the bent edges of the additional fabric made of polymer technical fabric, sewn to a single panel applied to the pipeline. 6. The device according to claim 1, characterized in that the upper eyes of a single panel formed by its bent and stitched edges. 7. The device according to claim 1, characterized in that the stiffening frames are provided with additional transverse reinforcing elements. 8. The device according to claim 1, characterized in that the spacer elements of each stiffening frame are pre-stressed - curved in shape, with a calculated bend in a plane parallel to the longitudinal axis of the pipeline. 9. The device according to claim 1, characterized in that the stiffening frames are made collapsible. 10. The device according to claim 1 or 9, characterized in that the longitudinal sides of the frames of rigidity are provided with embedded elements-inserts with the possibility of their fixation in group ballasting of the pipeline. 11. Polymer container ballasting device, containing two containers placed on both sides of the pipeline and filled with soil from panels of polymer technical fabric, each of which is equipped with stiffening frames and partitions, as well as power belts, in the eyes of which are placed the frames of stiffness, characterized in that the lower power belt and the tanks filled with soil are made in the form of a composite panel imposed on the pipeline equipped with eyes to accommodate the runs of stiffness frames in them, and each the partition is fastened with a container forming a container and the corresponding upper and lower power belts, while the lower part of each frame relative to the bottom of the trench is placed with a slope towards the pipeline without resting on it and on the soil of the bottom of the trench when filling the tanks with soil, as well as when the pipeline is exposed to ejection load, which is ensured by the estimated length of the lower power belt between the eyes for the lower runs of the stiffness frames and the length of the upper power zones, the latter being sewn to the lower power jar in the middle portion. 12. The device according to p. 11, characterized in that the upper power zones are formed by single-layer or folded into several layers and stitched ribbons of polymer technical fabric. 13. The device according to p. 11, characterized in that the number of upper power zones of each capacity is at least two. 14. The device according to p. 11, characterized in that the eyes for placing the lower runs of the stiffness frames in them are formed by bent and stitched edges of a fabric made of polymer technical fabric applied to the pipeline and forming the lower power belt. 15. The device according to claim 11, characterized in that the eyes for placing the upper runs of the stiffness frames therein are formed by the bent and stitched edges of the container-shaped panels of polymer technical fabric, symmetrically sewn to the panel of the lower power belt. 16. The device according to p. 11, characterized in that the stiffness frames are provided with additional transverse reinforcing elements. 17. The device according to claim 11, characterized in that the spacer elements of each stiffening frame are pre-stressed - curved in shape, with a calculated bend in a plane parallel to the longitudinal axis of the pipeline. 18. The device according to p. 11, characterized in that the stiffening frames are made collapsible. 19. The device according to claim 1 or 18, characterized in that the longitudinal sides of the frames of rigidity are provided with embedded elements-inserts with the possibility of their fixation during group ballasting of the pipeline.