RU2151843C1 - Lattice for localization of material - Google Patents

Abstract

FIELD: construction, applicable in highway engineering, particularly, in construction of pavement base course, as well as for reinforcement and protection against erosion of ground slopes, canals, facings and water-development works. SUBSTANCE: lattice is made of flexible strips installed on ribs and interconnected through spaces by seams with formation of a volumetric cellular structure at expansion, the sections of flexible strips between the seams, which at expansion form cell walls, are made at least with one concave and/or convex and/or concave-convex section forming a hollow member. EFFECT: formation of a block structure with a reliable engagement of blocks with one another, enhanced service life of pavement. 4 cl, 5 dwg

Description

 The invention relates to the construction and can be used in the construction of roads, namely, in the construction of the base of pavement, as well as to strengthen and protect against erosion of soil slopes, channels, facings and hydraulic structures.

 A known lattice for the localization of material - soil and concrete (application EP 0378309, MKI E 02 D 17/20, 1990), including many plastic strips located on the same line and fastened together at certain intervals, and these strips are stretched across the width form a single mesh lattice. On elongated plastic strips in the areas between the seams, which when stretched form the cell walls, many holes are made. During the construction of the pavement base, the gratings are pre-stretched to the working position, fixed with anchors, then the building material is laid in cells, then, depending on the building material, soil compaction or cement concrete is laid.

 The achievement of the required technical result in the specified invention is hindered by the construction of the lattice for localizing the material with holes, while using this design, the formation of bonds between the formed blocks of pavement occurs through the holes between the cells, these connections with time under the influence of the workload during operation are destroyed and not formed related block structure.

 Known strip used for the construction of roads (US patent N 1988269, NKI 404/27, 1927), having concave sections forming hollow structural elements. The achievement of the required technical result in the specified invention is hindered by the construction in the form of separate strips.

 Known block cladding system for controlling erosion (US patent N 4875803, NKI 405/16, 1989), consisting of separate blocks interconnected by combining protrusions made on one of the walls of one block, in a cavity made on one of the walls of the adjacent block, with the formation of a cellular hexogonal structure. The achievement of the required technical result in the specified invention is hampered by the construction in the form of separate blocks and, as a result, the high complexity and complexity of the construction.

 Closest to the proposed invention (prototype) is a geogrid - a lattice for localizing the material used in a flexible multilayer coating (RF patent N 2044813, MKI E 01 C 5/00, 5/20, 1995), made of flexible strips installed on the ribs and interconnected at intervals by seams with the formation of a tensile volumetric cellular structure. Moreover, the walls of each geogrid are made corrugated and each cell of the geogrid has valves in the form of notches in the walls, oriented by the axis of rotation of the valve petal parallel to the plane of tension of the geogrid. The valves are opened automatically when the geogrid is stretched due to the elastic properties of the material and the presence of a bridge in the valve base. The achievement of the required technical result in the specified invention is hampered by the design of the lattice for localizing the material with the valves, while using this design, the formation of links between the formed blocks of pavement occurs through open valves between the cells, these connections with time under the influence of the workload during operation are destroyed, although the reinforcing geogrid remains, and its valves to some extent provide the connection between the blocks, but the destruction of the bonds between the blocks ekaet to form random cracks, which deteriorates the base of the pavement.

 The task to which the claimed invention is directed is to create a lattice structure for localizing the material, which ensures the formation of a block structure with reliable meshing of blocks between each other in the manufacture of a cement-concrete base or a base from crushed-sand mixture treated with cement.

 The technical result achieved by the implementation of the invention is expressed in an increase in the durability of the pavement due to an increase in the distribution capacity of the pavement layer, consisting of a lattice for localizing the material and the material having tensile (bending) strength, by increasing the area of the load transfer to adjacent blocks, moreover, under the action of the workload during operation, the created tongue-and-groove bonds between the blocks are not destroyed, the likelihood of cracking character-temperature in the coating layer.

 To achieve the above technical result in the lattice for the localization of material made of flexible strips installed on the ribs and interconnected at intervals by seams with the formation of a tensile volumetric cellular structure, sections of flexible strips in the spaces between the seams, which when stretched form the cell walls, perform with at least one concave and / or convex and / or concave-convex section forming a hollow structural element. This section forming the structural element can be made by extrusion or by pressing.

 In the particular case of the invention, the hollow structural element may have a rectangular, or triangular, or circular, or oval shape in cross section parallel to the surface of the flexible tape, and its edges can be rounded. In the particular case of the invention, the length of the specified hollow structural element, in cross section on the surface of the flexible tape, is not more than 0.25 of the length of the cell wall, and the width is not more than 0.5 of the width of the flexible strip.

The invention is illustrated by drawings, where
in FIG. 1 shows the shape of the lattice cells for localization of the material in a stretched form (top view);
in FIG. 2. shows a section AA of FIG. 1;
in FIG. 3 shows the cell wall of the lattice for material localization (side view B);
in FIG. 4 shows a lattice for localizing the material when folded;
in FIG. 5 shows the connection of two loosely connected adjacent blocks when using the present invention.

 The lattice for the localization of the material 1 is made of flexible strips 2 mounted on the ribs and interconnected at intervals 3 by sutures 4 with the formation of tensile bulk cellular (honeycomb) structure. The sections 3 of the flexible strips 2 between the seams 4, which, when stretched, form the cell walls, are made with at least one convex and / or concave and / or convex-concave section 5, forming hollow structural elements. In one of the particular cases of execution, as shown in the figures, the sections 3 of the flexible strips 2 between the seams 4, which when stretched form the cell walls, are made with two convex sections 5 forming hollow structural elements. Each hollow structural element 5 is made in such a way that it is convex relative to one side of the flexible strip 2, while it is concave relative to the other side (i.e., on the one side of the flexible strip 2, this structural element forms a depression, and on the opposite, a protrusion) . The wall thickness of the hollow structural element 5 is comparable in thickness to the thickness of the flexible strips of which the lattice is made to localize the material. In one of the particular cases of the invention, the hollow structural element 5 can be made with a cross section parallel to the surface of the flexible strip, rectangular, and its edges can be rounded. The length a of the element 5 can be 0.25 of the length of the cell wall, and the width b is 0.5 of the width of the flexible strip 2. The hollow structural element 5 of a convex-concave shape can be hemispherical or have an ellipse shape in cross section parallel to the surface of the flexible strip , or a triangle, or a rhombus, or a square.

 During the construction of the pavement base, the lattice for localizing the material is stretched to the working position, fixed with anchors, then the building material 1 (cement concrete or cement-treated mineral material) is laid in cells. Upon hardening, a block structure is formed, while tongue-to-groove type bonds are formed between the blocks (Fig. 5). When the building material 1 hardens due to the hollow structural element extruded into the cell wall, the blocks are formed in such a way that a protrusion 6 forms on one of the two adjacent blocks, which enters the cavity 7 formed by the same hollow structural element in the adjacent block. In this case, the hollow structural element 5 of the lattice performs not only the form-forming function, but also performs the function of laying between the engagement elements of adjacent blocks.

 Thus, when using the proposed lattice to localize the material during the construction of the pavement base, the specified base, on the one hand, has a block structure, on the other hand, has a system of reliable connections between blocks, which are quite reliable during operation.

 The resulting bonds between the blocks increase the distribution capacity of the pavement layer by increasing the area of the load transfer from the block to neighboring blocks, and under the action of the workload during operation, the created tongue-and-groove bonds between the blocks are not destroyed. The likelihood of thermal cracking in the overlying layer made of monolithic material is also reduced.

 Block structures made using the proposed lattice for material localization can also be used to strengthen slopes, hydraulic structures and channels.

 The use of the proposed lattice for the localization of the material allows to increase the service life of pavement by 1.5-2 times in comparison with the standard design.

 The design of the lattice for localizing the material is made by known methods from known materials. Flexible strip 2 lattice can be made of polymeric materials, interconnected by ultrasonic welding. Hollow structural elements 5 can be performed on flexible strips 2 by extrusion using a press, molding or fastening of finished hollow structural elements to holes made in flexible strip 2, by welding with the formation of sections of flexible strips between the seams, which when stretched form the cell walls , convex, and / or concave, and / or concave-convex sections.

Claims (4)

 1. The lattice for localizing the material, made of flexible strips installed on the ribs and interconnected at intervals by seams with the formation of a tensile volumetric cellular structure, characterized in that the portions of the flexible strips between the seams, which, when the lattice is stretched, form the cell walls, are made with at least one concave and / or convex and / or concave-convex section forming a hollow structural element.  2. The lattice for localizing the material according to claim 1, characterized in that the hollow structural element is made by extrusion or pressing.  3. The lattice for localizing the material according to claim 1, characterized in that the hollow structural element is made in the cross section of a rectangular, or triangular, or round, or oval shape, and its edges are rounded.  4. The lattice for localizing the material according to claim 3, characterized in that in the section on the plane of the flexible strip the length of the rectangular hollow structural element is not more than 0.25 of the length of the cell wall, and the width is not more than 0.5 of the width of the flexible strip.

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