RU2326282C1 - Geoboard of polimeric material - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: invention deals with construction of pipelines and may be used for stabilisation of pipeleine trenches and slopes when constructing main pipelines, during road topping as foundation of, for example, service access roads in the process of construction of main pipelines, as well as for protection of the pipeline insulation from the impact made by the tightening weight applied when constructing pipelines underwater or within flooded locations. The cellular structure, filled with curable concrete mixture and equipped with lifting eyes, elements facilitating its fixation to the base and intended for fastening the boards to each other, is composed of flexible straps set on edge. The cellular structure is filled by way of impregnating it with a mixture containing at least polymeric resin and relevant curing compound.

EFFECT: enhancement of flexibility, durability and strength of geoboards; facilitation of erection and installation procedures both in the field environment and under the conditions of stationary base facilities.

8 cl; 3 dwg

Description

The invention relates to the construction of pipeline transport and is used to strengthen the trenches of pipelines, to strengthen the slopes during the construction of trunk pipelines, when paving the device as a base, for example, on technological access roads during the construction of trunk pipelines, and also to protect the insulation of the pipeline from exposure to it cargo or ballast used when laying pipelines, for example, in underwater or irrigated areas.

The prior art flexible concrete slabs "Geosot" (GBP) are known, which are a concrete-filled geogrid - a cellular structure of flexible polymer tapes mounted on the ribs and connected to each other with the arrangement of pressure points in a checkerboard pattern, while the cell walls are perforated or non-perforated and fixed to each other using connecting elements passed through the holes.

The geogrid is made of polyethylene tapes (high density low density polyethylene) by connecting the tapes to each other with linear stitches arranged in a checkerboard pattern. Aggregates of various types of GBS "Geosot" are concrete of various grades depending on the purpose, operating conditions. Polypropylene or polyamide cable serves as additional reinforcement and connection of cells with concrete (see TU 5841004-2293902-2004, Moscow, ZAO Presto-Rus, 2004).

A disadvantage of the known solution is the implementation of a cellular structure of a polymeric material, which requires careful handling when installing GBP in the field. For example, it is forbidden to walk on the laid polymer frame when filling the cells with concrete, which is a significant inconvenience, since it requires working with each plate individually or using special bridges to move workers during filling the cells with concrete. In addition, the polymer material used as a reinforcing material is combustible, the ignition temperature of which is quite low (below 290 degrees C), emits toxic substances during combustion.

Since the cell of known construction is a “rhombus” with curved walls, the known GBP does not have anisotropic properties. To give the cellular structure equal strength and to prevent the loss of concrete "blocks" from the cells, they are reinforced with rows of perpendicularly oriented polymer cables.

Ready-made safety bays laid at the site of the reinforcement work are not designed for the passage of heavy equipment, which significantly limits the area of use of the safety bricks.

Thus, there is the task of creating polymer geoplates (hereinafter referred to as the “geoplite” test) with anisotropic properties, which make it possible to simplify the installation of plates in the field, when workers move along stacked plates. In addition, geoplates should have the necessary strength, wear resistance and impact resistance when moving heavy equipment along them and when exposed to natural factors, for example, when an ice floe affects a shore protection coating.

Achievable technical result is an increase in the strength and wear resistance of geoplots, as well as simplification of installation work in the field and on stationary bases.

This problem is solved in that the polymer geoplite containing a cellular structure, filling its mixture, capable of curing during aging for a given period, cargo loops, fastening elements of the plate to the base and fastening elements of adjacent plates to each other, is made of a set of layers of porous flexible material in this case, to obtain a cellular structure, the specified set, including the edges of the plate, is stitched with longitudinal and transverse lowercase seams with a specified distance between the specified seams, and filling the cellular structure urine is carried out by impregnating it with a mixture containing at least a polymer resin and its hardener.

In particular cases of performing a geoplite, the set of layers of the specified material is pre-bandaged with a set of flexible textile tapes at the locations of the indicated lower seams, the latter are made using ribbons with the formation of loops on the longitudinal and transverse edges of the geoplite, and the elements of fastening the geoplite to the base and the elements of bonding adjacent geoplots are combined and made in the form of loops or eyes placed at the edges of the plate with a given step.

In addition, the set of layers of the specified material is preliminarily strengthened by unilaterally applying flexible textile tapes at the locations of the indicated lowercase seams, which are made along the tapes with the formation of eyes on the longitudinal and transverse edges of the geoplite or with the formation of loops, for which the ends of the tapes are fixed on the opposite side of the set of layers specified material.

This problem is solved by the fact that square, rectangular or rhomboid-shaped cells are formed by flashing longitudinal and transverse lowercase seams of a set of material layers, and the distance between the forming cells of the parallel seams exceeds the plate thickness by 3-10 times, most preferably 4-5 times.

In this case, the tensile strength of the specified set of tapes exceeds the corresponding strength of the stitched and impregnated with a polymer resin set of layers of porous material.

In addition, a set of layers of porous flexible material is provided on one or both sides with a wear-resistant coating layer of permeable or impermeable material capable of adhesion of a set of layers of porous material impregnated with a polymer resin.

The choice of material for manufacture is determined by its accessibility, ease of cutting blanks, good ability to stitch with lowercase joints, and also good physical and mechanical properties, especially strength, flexibility, wear resistance, heat resistance and lack of tendency to rot in difficult conditions. Porosity provides the necessary impregnation of a set of layers of material with a polymer resin

The supply of the geoplate from one or both sides with a wear-resistant coating layer of permeable or impermeable material capable of adhesion of a set of layers of a porous material impregnated with a polymer resin, for example, Armetex type, exceeds the abrasion resistance of the geoplate. The specified material has the necessary abrasion resistance (outer layer), and the inner layer has the ability to absorb polymer resin and, due to adhesion with a set of layers of porous material, eliminates the formation of "tent" voids in the specified set. This, in turn, reduces the water absorption of the geoplite and increases its durability.

If a set of layers of a porous flexible material impregnated with a polymer resin is capable of absorbing tensile forces, then tapes forming loops or eyes are used only to connect adjacent geoplates to each other. Otherwise, a set of tapes is used that reinforce the geoplite and perceive tensile loads.

Each mounting loop is made in the form of loops protruding beyond the edge of the geoplite, providing the possibility of applying external force to the geoplite.

The step between the lower seams, the size of the geoplite cells affect its wear resistance and impact strength.

The invention is illustrated by graphic material, where Fig. 1 shows a cross-section of a geoplite, and Figs. 2, 3 show reinforcement and fastening elements of geoplots to each other.

On the accompanying figures, the positions indicate the following elements of the geoplite:

1 - a layer of flexible porous material;

2 - connecting seams;

3 - flexible tapes;

4 - banding pad;

5 - wear-resistant outer layer;

6 - loop;

7 - eye.

The claimed device is manufactured industrially. Billets of the calculated length are cut from a roll of porous material; it is possible to use industrially produced layers in the form of plates 1 of high-strength fabric.

To create a cellular structure form a set of flat flexible layers 1 - blanks, which are fastened with connecting seams 2 with the formation of cells. The step between the seams 2 and their direction relative to the longitudinal axis of the geoplite define the shape of the cells.

As reinforcing elements, flexible tapes 3 are used from rolled textile material - high-strength fabric. In addition, with insufficient tensile strength, layer 1 is reinforced with banding plates 4 by a set of flexible tapes. Depending on the conditions of use of the geoplite, the set of layers of the porous material can be strengthened by external wear-resistant layers 5, for example, of the Armitex type.

On the longitudinal and / or transverse sides of the specified set of layers 1 of the tapes 3, as well as a set of tapes 4 by stitching, mounting loops (not shown), elements for fixing the plate on its base and elements for fastening the plates together are formed. These elements can be combined and made in the form of loops 6 or eyes 7.

Made of these materials and stitched cellular structures - geoplates have high mechanical strength, durability in operating conditions, as they are not subject to decay, which is important, for example, when protecting a pipeline crossing. When laying geoplots, for example, on the slopes of trenches, ravines, and the banks of water bodies, the ribbons forming the cellular structure along the current load should be oriented.

Neighboring geoplites are connected by cords, polymer cables, passing them through the loops or eyes of adjacent geoplates.

Geoplates are used to strengthen pipeline trenches, to strengthen slopes during the construction of trunk pipelines, when laying pavement as a foundation, for example, on technological access roads during the construction of trunk pipelines, as well as in the form of a cargo or ballast used for laying pipelines in underwater or irrigated areas .

Depending on the function assigned to the structural layer, made on the basis of geoplates, the requirements for its cellular three-dimensional structure are determined with respect to geometric dimensions, material, structural elements, tension forces of the ribbons forming the "geogrid". In addition, depending on the purpose of the geoliths, certain requirements are imposed on the cell filler - polymer resin.

The height of the geogrid cells used in non-rigid pavements should be selected based on the strength of the pavement structure, but not less than 152 mm. A cellular structure with a wall height of at least 76 mm should be used at the base of the prefabricated coating, for example, the reinforcing shore of a reservoir.

When filling the cells with polymer resin, the role of the “geogrid” from a set of flexible tapes is reduced to ensuring the creation of a block structure that helps to increase the strength and wear resistance of the temperature crack resistance of the structure, for example, if it is used at the base of an asphalt concrete pavement.

It is possible to use geoplots to protect the insulation of pipelines of underwater crossings as protective means for isolating the pipeline when using ballasting devices of various types.

The design and materials of the geoplates provide a reliable and fixed position of the pipeline during its construction and during the period of operation allow protecting the pipeline insulation from damage.

Elements of fixation of geoplots on the basis eliminate the displacement of the cellular structure, prevent the displacement of the filling material from its cells, which is especially important when building the coating on loamy and clay soils.

The implementation of the reinforcing "geogrid" from a set of flexible tapes in the form of a three-dimensional spatial cellular structure, the cells of which are filled with polymer resin, provides the necessary elasticity and the ability to restore shape without breaking if dynamic loads are applied to the geoplite.

The dimensions of the geoplite are selected for reasons of ease of transportation and installation and are preferably equal: in the transport position, the length of the geoplate is 2-2.5 m, and the width is 1.0-1.5 m.

The height of the volumetric cellular structure is selected from the condition of ensuring the necessary thickness of the elastic layer, high-quality impregnation of the layers in these cells and the optimal ratio of strength properties and weight of the geoplate.

The claimed invention allows to increase the bearing capacity of the coating, for example, the slopes of the trench, the shore of the reservoir, made on the basis of geoplates, including the repeated application of a local shock moving load. One of the advantages of this design is that it simplifies the process of mounting the coating on the base.

Claims (8)

1. Polymer geoplite containing a cellular structure, filling its mixture, capable of curing during aging for a given period, cargo loops, fastening elements of the plate to the base and fastening elements of adjacent plates to each other, characterized in that the plate is made of a set of porous flexible layers material, in order to obtain a cellular structure, the specified set, including the edges of the plate, is stitched with longitudinal and transverse lowercase seams with a specified distance between the specified seams, and filling the cellular structure about uschestvlyayut its impregnation with a mixture containing at least a polymer resin and its hardener. 2. Geoplite according to claim 1, characterized in that the set of layers of the specified material is bandaged preliminarily longitudinally and transversely with a set of flexible textile tapes at the locations of the indicated lowercase seams, the latter are made on tapes with the formation of loops on the longitudinal and transverse edges of the geoplate. 3. Geoplite according to claim 2, characterized in that the fastening elements of the geoplite to the base and the fastening elements of adjacent geoplates are combined and made in the form of loops or eyes placed at the edges of the slab with a given step. 4. Geoplite according to claim 1, characterized in that the set of layers of the specified material is pre-strengthened by unilaterally applying flexible textile tapes at the locations of the indicated lowercase seams, which are made on tapes with the formation of eyes on the longitudinal and transverse edges of the geoplite or with the formation of loops, the ends of the tapes are fixed on the opposite side of the set of layers of the specified material. 5. Geoplite according to claim 1, characterized in that square, rectangular or diamond-shaped cells are formed by stitching longitudinal and transverse lowercase seams of a set of material layers. 6. Geoplite according to claim 1, characterized in that the distance between the forming cells of the parallel seams exceeds the thickness of the plate by 3-10 times, most preferably 4-5 times. 7. Geoplite according to claim 1 or 2, characterized in that the tensile strength of the specified set of tapes exceeds the corresponding strength of the stitched and impregnated with a polymer resin set of layers of porous material. 8. Geoplite according to claim 1, characterized in that the set of layers of porous flexible material is provided on one or both sides with a wear-resistant coating layer of permeable or impermeable material capable of adhesion of a set of layers of porous material impregnated with a polymer resin.

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