RU89881U1 - GABION GRID WEIGHT LIFT COVERING "GSU-KO" - Google Patents

Abstract

1. The gabion mesh weighting device comprising a couple connected by a web, preferably from a metal mesh, or assembled on it and having loading covers equidistant from the longitudinal axis of the pipeline, containers of rectangular cross section from a double torsion metal mesh with hexagonal cells forming hinges with three degrees of freedom, providing flexibility and the flexibility of the design of the weighting agent for longitudinal and transverse movements of the pipeline, and each container is filled with stone material scrap fraction 80-200 mm with its center of mass located below the longitudinal axis of the conduit to achieve the effect of the female pipe. ! 2. The gabion mesh weighting material covering according to claim 1, characterized in that each container has a separation diaphragm, the planes of which are parallel to the longitudinal axis of the pipeline, and the lid of each container is located on the side opposite to the canvas and is fixed in the corners and around the perimeter of the container with a tie wire attached to the top of the sides of the container and to its diaphragms. ! 3. Gabion mesh weighting material covering according to claim 1, characterized in that the porosity coefficient of the stone material of the weighting material during manual installation is 0.25, and the fill factor of each container is 1.05.

Description

The proposed technical solution relates to the field of construction and repair of pipelines and can be used for ballasting laid in trenches made in slightly bearing soils that do not have the necessary clamping ability.

The closest known one is the gabion mesh weighting material, laid on the pipeline through a protective mat, including a rectangular box filled with bulk ballast material, formed from a double-torsion steel mesh with hexagonal cells, divided by jumpers from the mesh transversely spaced at regular intervals with reinforcement wire around the perimeter, the height of which is equal to the height of the longitudinal and transverse sides of the box, and having a lid of mesh, fixed to the sides or to orts and lintels characterized in that the bulk ballast material when it is placed in the box is uniformly located over the box area with at least 5% excess of the level of the sides and the height of the lintels, the front and rear longitudinal sides of the box are formed from the mesh of the box bottom by bending it and tied by a continuous length of wire at least along the length of one side of the lintel to the ends of the lintels with a capture of the wire of their reinforcement, and the sides and lintels are equipped with pairs of lifting loops offset from their center to the edges, comb m the jumpers when laying the device on the pipeline are oriented along its longitudinal axis, and the protective mat has a length exceeding the diameter of the pipeline (No. 65166U1, 2007).

The technical task of the proposed solution is to ensure the possibility of maintaining the design position of the pipeline for the entire period of its operation by stabilizing the position of the weighting material located on it by ensuring the maximum possible coverage of the pipeline surface and the fit of the corrugated mesh surface.

This is ensured by the fact that the gabion mesh weighting material covering has a pair connected by a web, preferably of a metal mesh, or of containers of rectangular cross section made of double-section metal mesh with hexagonal cells forming hinges with three degrees of freedom assembled on it and having loading covers equidistant from the longitudinal axis of the pipeline providing flexibility and design of the weighting agent with longitudinal and transverse movements of the pipeline, with each container filled with stone material of a fraction of 80-200 mm with the location of its center of mass below the longitudinal axis of the pipeline to achieve the effect covering the pipeline. Each container has a separation diaphragm, the planes of which are parallel to the longitudinal axis of the pipeline, and the lid of each container is located on the side opposite to the canvas and is fixed in the corners of the container with a tie wire attached to the top of the sides of the container and to its diaphragms. And the porosity coefficient of the stone material of the weighting agent during manual installation is 0.25, and the fill factor of each container is 1.05. - These parameters ensure the preservation of the shape of the container during operation, and the size of the fraction is selected from the condition of limiting the deformation of the walls of the container.

Figure 1 shows the wire frame of the GSU-KO weighting agent in the assembly process;

Figure 2 shows the GSU-KO weighting agent in the design position at the bottom of the trench;

Figure 3 shows the installation diagram of the GSU-KO weighting agent on the pipeline in the trench, the first stage, in the process of pointing to the pipeline;

Figure 4 shows the installation diagram of the GSU-KO weighting agent on the pipeline in the trench, the second stage, during installation on the pipeline;

Figure 5 shows the weighting with mounting loops.

GSU-KO weighting agent is a small-height structure made of two containers 1, rectangular in cross section, having lids 2, on a single sheet 3 (bottom) of containers 1 (containers are located at the edges of the sheet) with individual lids filled with stone material of fraction 80-200 mm The containers are made of double torsion metal mesh with hexagonal cells. The dimensions of the wire frame GSU-KO (see figure 1) are characterized by the following parameters: A - the length of the bottom, m; In - the width of the bottom, m; C is the thickness of the weighting agent, m; H is the length of the container m, (which is a container for ballast stone material); L is the length of the connecting web, m .. The above parameters are assigned depending on the diameter and characteristics of the ballasted pipeline.

As the ballast material of the GSU-KO weighting compound, natural stone material is used, which has the necessary strength, frost resistance and water resistance. The stone material may be rolled up (river stone) or torn (quarry stone or crushed stone). The porosity coefficient (k _pore ) of the ballast material of the GSU-KO weighting material during manual laying of stone material should be 0.25. When filling the weighting agent, the volume of ballast material (stone) GSU-KO must be increased by 5% in excess of the volume of each container 1 (filling factor k _zp = 1.05), because partial self-compaction of ballast material during construction and installation works is possible.

The assembly and filling of the GSU-KO weighting agent is carried out at the site of preparation of the weighting material for installation, first a wire frame is formed from prefabricated billets, then the containers 1 are filled with ballast material (stone fraction 80-200 mm). After filling the GSU-KO weighting material, a cover 4 of material similar to wire frame 1 is installed. The cover is fixed in the corners of the wire frame and is tied to the top of the sides and diaphragms with a tie wire.

To protect the insulating coating of the pipeline 5 from the effects of the connecting fabric 3 and containers 1 of the GSU-KO weighting material, lining mats (protective mats) should be used 6. The base and slopes of the trench 7 should be planned so that the GSU-KO weighting material is in the design position in accordance with figure 2.

The installation of GSU-KO weighting agents on the pipeline 5 (see FIGS. 2, 3) is made in assembled and filled form using the volume (eight-point) traverse 8. Installation of the weighting agents on the pipeline must be done carefully, without jerking and swinging, to exclude the possibility of insulation damage the pipeline. For the installation of the GSU-KO weighting agent on the pipeline, installation of mounting loops 9 made of reinforcing steel evenly around the perimeter of the weighting containers 1 is provided (see Fig. 4). At the same time, double torsion of the wire mesh ensures the integrity, strength and uniform distribution of loads, prevents unwinding in the event of a mesh break. The ballasting ability of GSU-KO is achieved by the load distributed along the upper generatrix of the pipe. A container from the specified mesh performs a consolidating role, while having some mobility, which allows you to maintain the design position of the GSU-KO with longitudinal and transverse movements of the pipeline.

Claims (3)

1. The gabion mesh weighting device comprising a couple connected by a web, preferably from a metal mesh, or assembled on it and having loading covers equidistant from the longitudinal axis of the pipeline, containers of rectangular cross section from a double torsion metal mesh with hexagonal cells forming hinges with three degrees of freedom, providing flexibility and the flexibility of the design of the weighting agent for longitudinal and transverse movements of the pipeline, and each container is filled with stone material scrap fraction 80-200 mm with its center of mass located below the longitudinal axis of the conduit to achieve the effect of the female pipe. 2. The gabion mesh weighting material covering according to claim 1, characterized in that each container has a separation diaphragm, the planes of which are parallel to the longitudinal axis of the pipeline, and the lid of each container is located on the side opposite to the canvas and is fixed in the corners and around the perimeter of the container with a tie wire attached to the top of the sides of the container and to its diaphragms. 3. Gabion mesh weighting material covering according to claim 1, characterized in that the porosity coefficient of the stone material of the weighting material during manual installation is 0.25, and the fill factor of each container is 1.05.