RU202886U1 - Flexible mesh - Google Patents

Abstract

The technical solution refers to the polymer industry, mainly to flexible meshes (gratings) made of polymer materials and designed to strengthen slopes and foundations (in this case they are called geogrids or geogrids), and can also be used to strengthen or reinforce in other areas, mainly in construction work and / or structures. A technical problem is the excessive stiffness of the mesh, which made it difficult to lay and approximate the reinforced earth and / or fill surface. Flexible mesh, characterized by the fact that it consists of intersecting longitudinal and transverse elements forming cells of an elongated barrel-shaped shape in plan, mesh nodes are formed at the intersections of longitudinal and transverse elements, along the edges of the longitudinal and transverse elements on both sides of the mesh, edge protruding ribs are made , monolithically interconnected along the edges of the mesh nodes by nodal concave ribs, while at the mesh nodes on both sides there are protrusions, and the longitudinal elements and a smaller thickness in the cross section, compared to the transverse elements, while the longitudinal elements exceed the length of the transverse elements. The technical result is to provide various flexibilities in the longitudinal and transverse directions. 5 p.p. f-ly, 6 dwg

Description

The technical solution relates to the polymer industry, mainly to flexible meshes (gratings) made of polymeric materials and designed to strengthen slopes and foundations (in this case, they are called geogrids or geogrids), and can also be used to strengthen or reinforce in other areas, mainly in construction work and / or structures.

From the prior art geonets are known made by extrusion, having rectangular cells, ribs on longitudinal and transverse elements and protrusions in the mesh nodes, see for example WO 2004094259 A, 04.11.2004; US 5267816 A, 07.12.1993; US 3386876 A 04.06.1968.

Known lamellar element in the form of a grid for reinforcement, separation and drainage of large structures, such as road embankments, contains a lamellar body, which has a lattice structure with main cables and transverse cables stretched along two essentially mutually perpendicular directions. The cables are biaxially oriented with a degree of stretch in the two essentially mutually perpendicular directions, which ranges from 2.8 to 5.5. Main cables, i.e. in the direction of extrusion of the preform forming the plate body, have a substantially quadrangular cross-section and a thickness in the direction perpendicular to the plane of the plate body, which is equal to at least three times the thickness of the transverse cables. The technical result consists in securing the plate element in the ground, ensuring reliable operation and safety during use (RU 2520597, 06/27/2014).

The closest analogue to the claimed technical solution is a flexible lattice (mesh) for construction work and fences with the possibility of layout in a roll containing orthogonally intersecting strands of extruded oriented polyolefin material with the formation of windows and nodes with thickenings at the intersection of the strands, characterized in that the configuration of the windows formed by arcuate lines of the surfaces of the strands and the conjugations of these lines, while the cross-sections of the strands are made in I-shape, and the cross-section of the thickenings is of a drop-like shape. (RU 102015U1, E02D 17/20, 10.02.2011).

The disadvantage of the closest analogue is the complexity of its implementation, namely, the implementation of the I-shaped strands, the thickenings (protrusions in the mesh nodes) are made in a drop-shaped form, which does not provide adhesion to the ground or other base due to the streamlining of this shape and the small contact area with the base on which it is laid grid.

A technical problem is the excessive stiffness of the mesh, which made it difficult to lay and approximate a reinforced earth and / or fill surface, or a reinforced / reinforced structure.

The technical result is to provide various flexibilities in the longitudinal and transverse directions.

The technical result is achieved due to the fact that the flexible mesh, according to the utility model, consists of intersecting longitudinal and transverse elements forming cells of an elongated barrel-shaped shape in plan, at the intersection of longitudinal and transverse elements, mesh nodes are formed, along the edges of the longitudinal and transverse elements with both sides of the mesh have edge, outwardly protruding ribs, monolithically connected to each other along the edges of the mesh nodes by nodal concave ribs, while the mesh nodes on both sides have protrusions, and the longitudinal elements have a smaller thickness in the cross section, compared to the transverse elements, when in this respect, the longitudinal members are longer than the cross members.

The cells are barrel-shaped in plan, preferably rectangular with curved longitudinal sides formed by curved longitudinal sides of the longitudinal elements and fillets at the corners of the cell.

The inner surfaces of the cross members bounded by the ribs are made at least partially curved, preferably in the regions adjacent to the ribs, while the inner surfaces of the longitudinal members bounded by the ribs are flat.

The longitudinal elements in the plan can be made curvilinear-concave inward and have curved ribs, while in the middle part each longitudinal element has a narrowing, and at its ends it has extensions that form between the ribs, at the mesh nodes, platforms for placing the protrusions.

Longitudinal elements can have flat outer and inner surfaces, each longitudinal element is made of variable width and tapers towards its middle part, while the transverse elements are rectilinear in plan and have a curved cross-section with concave outer and inner surfaces.

The protrusions in the mesh nodes can be made elongated and located across the longitudinal elements in the direction of the transverse elements.

The technical solution is illustrated by drawings, which show:

FIG. 1 shows the mesh from the outside (fragment, plan view).

FIG. 2 section a-a in FIG. one.

FIG. 3 section b-b in Fig. one.

FIG. 4 shows the mesh from the inside (fragment, plan view).

FIG. 5 isometric view of a fragment of a grid.

FIG. 6 isometric view of a grid cell (enlarged).

The mesh consists of intersecting longitudinal elements 1 and transverse elements 2, forming cells 3 elongated in the longitudinal direction barrel-shaped in plan form.

It should be borne in mind that the elements that are more extended in the figures illustrating the application of materials, and named in the application longitudinal in the manufacture of the mesh on the technological line are transverse with respect to the longitudinal axial technological line and the manufactured product. That is, during the manufacture of the mesh, the longitudinal elements are directed transversely in the direction of the production line, and in the technological documentation these elements can be referred to as transverse strands. And, accordingly, the same applies to the transverse elements, which are longitudinal strands in relation to the longitudinal centerline technological line, and in the illustrations showing only fragments of the entire product, they are shorter and for clarity of understanding in the application have the conditional name transverse elements.

At the intersections of the longitudinal elements 1 and the transverse elements 2, mesh nodes 4 are formed, along the edges of the longitudinal and transverse elements on both sides of the mesh, edge ribs 5 and 6 protruding outward are made, monolithically interconnected along the edges of the mesh nodes by nodal ribs 6.

Each longitudinal 1 element of the cell 3 has a length L and a greater width B, in comparison with the transverse element of the cell 3, which has a length / and a width L (Fig. 1).

Longitudinal elements 1 can exceed the length (L> 1) of the transverse elements 2, for example, 1.2 times. In addition, the longitudinal elements 1 are at least 1.5 times larger in width (B> L) than the transverse elements 2, and preferably 1.6-2 times.

In this case, each longitudinal 1 element of the cell 3, preferably, has a smaller thickness t in the cross section, compared with the thickness T of the transverse element of the cell 3 (Fig. 2, 3).

The cross members are at least 1.1 times the thickness of the longitudinal members, and preferably 1.25 times.

Projections 7 are made at the mesh nodes on both sides of the mesh.

The protrusions 7 at the mesh nodes are made elongated, preferably rectangular (with rounded edges and edges) or oval-like in plan, and are located transversely (perpendicular to their direction) of the longitudinal elements 1 in the direction of the transverse elements to increase the rigidity and reduce the flexibility of the mesh in the direction of the transverse elements.

The protrusions in the mesh nodes can have an outer surface 9 close to a cylindrical or even cylindrical outer surface and lateral rounded-convex surfaces smoothly conjugated with the outer surface, while the outer and lateral surfaces of each protrusion 8 are also smoothly conjugated with the surfaces of mesh nodes 4 (Fig. 5 , 6).

The cells in plan are made barrel-shaped, preferably rectangular with curved longitudinal sides formed by curved longitudinal sides 11 of the longitudinal elements 1 and fillets 12 at the corners of the cell 3.

The inner surfaces 13 of the cross members 2, delimited by the ribs 6, are at least partially curved, preferably in the regions adjacent to the ribs. The inner surfaces 14 of the longitudinal elements 3, bounded by the ribs 5, are made flat (Figs. 2, 3). This also increases the rigidity of the cross members 2 and increases the flexibility of the longitudinal members 1.

The longitudinal elements have flat outer and inner surfaces 14, each longitudinal element is made of variable width and tapers towards its middle part, while the transverse elements are rectilinear in plan and have a curved, preferably symmetrical, cross-section with concave outer and inner surfaces 13. and transverse elements gives them the necessary tensile strength, while the longitudinal elements are flexible, and the transverse ones are more rigid.

Longitudinal elements 1 in plan are made curvilinear-concave inward and have curved ribs, while in the middle part each longitudinal element 1 has a narrowing 15 (Fig. 1), which also provides the flexibility of the lattice in the longitudinal direction.

In this case, the longitudinal elements 1 in plan at their ends have extensions 16, which, together with the extensions 17 of the ends of the transverse ribs, form between the ribs in the nodes of the geogrid the platform for placing the protrusions 8.

Oblong protrusions 7, as well as ribs 5, 6 and 7 are located symmetrically on both sides of the nodes 4 of the mesh.

The protrusions are made convex and oval-like or oval in plan, or pyramidal, in the form of a truncated pyramid, with rounded edges, the upper base of which forms a platform for contact with the base, on which, preferably, corrugation 18 is made. more durable, better adhesion to materials in contact with the mesh, and at the same time does not interfere with the increase in the flexibility of the mesh due to rounding of the protrusions.

The device can be made from a polymeric polyolefin material, for example, polyethylene, or from polyvinyl chloride, by cutting into a polymeric cloth to form window cells with the formation of ribs and stretching it in a heated state to the required dimensions, providing the necessary parameters of rigidity and flexibility of the mesh in various directions.

The length L of the longitudinal element may be equal to the length l of the transverse element, but may be greater. The length L of the longitudinal element is from 1.5 to 5.0 cm, for example, 3.6 cm, while the length l of the transverse element is from 1.5 to 4.5 cm, for example, 3.3 cm. Moreover, the thickness t of the longitudinal element is 0.8-2.0 mm, for example - 1.0 mm, and the thickness T of the transverse element is 1.0 - 2.7 mm, for example - 1.25 mm.

When strengthening the soil slope or embankment, the device is mounted as follows. The mesh is rolled from top to bottom along the slope of the slope or embankment, orienting the longitudinal elements 1 in the direction of the slope, which allows, due to the flexibility of the longitudinal elements, approximate the surface of the slope, embankment or other inclined and / or embossed base in the longitudinal direction, while the stiffness of the transverse elements gives the shape to the reinforced base. In this case, the mesh is laid down by the protrusions 7 on which the corrugation 18 is made (Fig. 4).

Using various indicators of the rigidity and flexibility of the mesh in the longitudinal and transverse directions, it is also possible in landscape design, forming the desired shape of the relief from several meshes.

In building structures, the mesh can be used as a building envelope, for example, at a construction site, as well as a reinforcing or reinforcing layer. Its high strength and flexibility, provided due to the declared design features, allows you to easily adapt the flexible mesh to specific conditions of use while maintaining all the strength properties of the mesh.

Thus, the claimed technical result is achieved and the arsenal of technical means that solve this problem is expanded.

Claims (6)

1. Flexible mesh, characterized by the fact that it consists of intersecting longitudinal and transverse elements that form cells of an elongated barrel-shaped in plan shape, mesh nodes are formed at the intersections of longitudinal and transverse elements, along the edges of the longitudinal and transverse elements on both sides of the mesh, edge protruding outward ribs, monolithically interconnected along the edges of the mesh nodes by nodal concave ribs, while protrusions are made in the mesh nodes on both sides, and the longitudinal elements have a smaller cross-sectional thickness compared to the transverse elements, while the longitudinal elements exceed the transverse ones in length elements. 2. Flexible mesh according to claim 1, characterized in that the cells are barrel-shaped in plan, preferably rectangular with curved longitudinal sides formed by curved longitudinal sides of the longitudinal elements and fillets at the corners of the cell. 3. Flexible mesh according to claim 1, characterized in that the inner surfaces of the transverse elements bounded by the ribs are made at least partially curvilinear, preferably in the regions adjacent to the ribs, while the inner surfaces of the longitudinal elements bounded by the ribs are flat ... 4. Flexible mesh according to claim 1, characterized in that the longitudinal elements in the plan are curvilinear-concave inward and have curved ribs, while in the middle part each longitudinal element has a narrowing, and at its ends it has extensions that form between the ribs, at grid nodes, platforms for placing protrusions. 5. Flexible mesh according to claim 1, characterized in that the longitudinal elements have flat outer and inner surfaces, each longitudinal element is made of variable width and tapers towards its middle part, while the transverse elements are rectilinear in plan and have a curved cross-section with concave external and internal surfaces. 6. Flexible mesh according to claim 1, characterized in that the projections at the mesh nodes are elongated and located across the longitudinal elements in the direction of the transverse elements.

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