RU2338026C2 - Trellised slab - Google Patents

Abstract

FIELD: building, road works.

SUBSTANCE: trellised slab in the form of all-in-one, made of plastic by cast under pressure products for strengthening and/or the ground gardening, having formed by cells of a various type cellular structure is described. Between arc-shaped lots (6) of the walls of rosette-like and radial cells (2; 3) an archwise curved in an opposite side in relation to these arc-shaped lots (6) transition (14) is available, in a bending down formed in it (15) is formed a strengthening element which without ledges and swages stabilizes the rosette-like cell (2) from its outer end and the radial cell (3) from its inside. Besides it the arc-shaped lots (6) pass into the wall (4) of the central cell (1) through a strengthening member having the arc-shaped form formed with their internal and exterior sides, accordingly the half moon form, and all walls (4; 6) of the central, rosette-like and radial cells (1; 2; 3), lean on underlayments (8) connected among themselves from the bottom side of a trellised slab.

EFFECT: creation of a slab for strengthening and-or ground gardening.

8 cl, 2 dwg

Description

The present invention relates to a grating plate in the form of a solid, injection-molded plastic product for strengthening and / or landscaping soil having a cellular structure formed by cells of various types, open at the level of a pedestrian or carriageway, with a drainage hole in the base of each cell for water drainage and which is formed by nodal cells and rosette and star cells located around each of them in alternating order, bounded by walls, consisting and from arched sections, while along the edges of the grating plate there are only cut or incomplete nodal and star cells, which, when connected to adjacent grating plates, are supplemented to closed along the perimeter or full cells, and located at the bottom of the grating plate at the level of its base are located in alternating (staggered) order along its mutually opposite sides of the sliding surface, which are designed to connect the lattice plates to each other and each of which is equipped with a fixing ystupom which when combined grid plates engages and engages the opposite wall of the corresponding truncated or incomplete nodal cell.

The lattice plate of the type indicated at the beginning of the description is known from DE 10045814 C1 and is a one-piece, injection-molded plastic product for strengthening and / or greening the soil, having a cellular structure formed by cells of various types. This cellular structure is open at the level of a pedestrian or roadway. In each cell of such a cellular structure, a drainage hole is provided for draining water from the side of its base. At the edges of the grating plate, connecting elements are provided that are designed to connect the grating plates to each other and which are arranged in alternating (staggered) order along its mutually opposite sides. The cellular structure itself is formed by nodal cells and rosette and star cells located alternately around each of them. Along the edges of the grating plate, only cut or incomplete nodal and star cells are located, which, when connected to adjacent grating plates, are supplemented to perimeter or full cells closed. The connecting elements on the cut-off nodal cells are formed by sliding surfaces located at the level of the base of the grating plate, each of which is equipped with a fixing protrusion protruding above it, which, when connecting the grating plates, jumps and hooks onto the wall of the corresponding opposite cut or incomplete nodal cell of the other grating plate. Rosette and star cells are bounded by walls consisting of arched sections connected to each other, which at the points of their connection form a vertical ridge along the protruding inside the rosette cells.

A disadvantage of such a known lattice plate is that the transitions between the arched sections of the walls of the rosette and star cells connecting to each other, as well as the transitions between these arcuate sections and the walls of the nodal cells, are too pointed, and therefore, when passing through the lattice plates in these transitions significant peaks of internal stress, which despite the large wall thickness of the cellular structure can lead to the destruction of the lattice plate.

Another disadvantage of the known lattice plates is that because of their high material consumption, they have a large mass and therefore cause inconvenience during installation, and also require a high consumption of material per square meter used for their manufacture.

Based on the prior art described above, the present invention was based on the task of improving the lattice plate of the type indicated at the beginning of the description in such a way as to almost completely eliminate the occurrence of internal stress peaks at the points of transition of the arcuate sections of the walls to each other and to the walls of the nodal cells despite the implementation of the bounding cell walls of reduced thickness, as well as reduce the mass of grating plates and at the same time increase the efficiency of their manufacture while maintaining and that all the existing benefits of the famous grid plates consisting in the convenience of placing and operating with them.

This problem is solved using the distinguishing features of claim 1 of the claims. Preferred embodiments of the invention are given in the respective dependent claims.

The lattice plate proposed in the invention is primarily distinguished by the fact that only relatively small voltage peaks can occur at the points of transition between the walls of rosette, star and nodal cells. This is achieved due to the fact that at the junction of adjacent arcuate sections of the walls, at least one arcuate reinforcing element is provided to avoid a pointed transition from one section of the wall to another. As a result, the internal rigidity of the cellular structure also increases despite a decrease in the cell wall thickness. The grating plate proposed in the invention has a significantly lower net weight, due to which not only cost savings are ensured, but also the installation of the grating plate is simplified.

Other features of the invention are described in detail in the following description with reference to the accompanying drawings.

Below the invention is described in more detail on the example of one of the variants of its implementation with reference to the accompanying drawings, which show:

figure 1 is a perspective view of a rosette, star and nodal cells according to the prior art and

figure 2 is an enlarged view in plan of a fragment of the invention in the lattice plate formed by rosette, star and nodal cells.

To clarify the essence of the present invention, Fig. 1 shows a perspective view of a fragment of a grating plate known from the prior art, which is a prototype of a grating plate according to the invention. Such a well-known grating plate consists of three different types of open cell structure forming at the ground and carriageway levels, namely: nodal cells 1, 12-sided rosette cells 2 and 12-sided star-shaped cells 3. Walls of 4 nodal cells 1 are part of the walls of 5 rosette cells 2 and star cells 3. In addition, the wall 5 of rosette cells 2 and star cells 3 consists of arcuate sections 6, which at the points of their connection SP form a vertical ridge 7 protruding inside the rosette 2 and one They form a wall of rosette cells 2 and star-shaped cells 3. Rocket-shaped cells 2 and star-shaped cells 3 in a sort of alternating order surround nodal cells 1. Accordingly, each nodal cell 1 simultaneously increases the stiffness of rosette-cells 2 and star-shaped cells 3 at the junction .

Nodal cells 1 are made in the form of hollow cylinders and have supporting surfaces 8 formed in the form of circular segments formed on them at the level of the base BE. These supporting surfaces 8 have a flange 9 which protrudes vertically upward from the base level, which on both sides adjoins the arcuate sections 6 connected to the wall 4 of the nodal cell 1, as a result of which recesses 10 are formed in each socket cell 2 in which water is held and / or fertilizers.

From below, on the arcuate sections 6 with their opposite to the inside side rods 2 protruding from the rosette 2, the support surfaces 11 are formed in the form of circular segments that protrude inside the star cells 3 and transmit lateral forces acting on the ridges 7 to the ground.

The supporting surfaces 11 have a protruding vertically upward shoulder 12, which on both sides of the ridge 7 is adjacent to the arcuate sections 6, as a result of which, with their opposite to each ridge 7 side, one more recess 13 is formed in which water and / or fertilizers.

Figure 2 shows the proposed in the invention the cellular structure formed by rosette, stellate and nodal cells, the walls and arched sections of the walls of which do not have pointed transitions and ridges.

The arcuate sections 6 have at their junction SP (at the intersection line) a smooth transition 14 of an arcuate shape, the bend 15 of which has an inverse curvature with respect to the curvature of the arcuate sections 6. In the bend 15, a planar reinforcing element 16 is formed in cross section, which reduces the curvature transition 14 between the connecting arcuate sections 6. In this case, the stepless and bezig-free reinforcing element 16 of the bend 15 is located on the outside of the wall bounding the corresponding socket cell 2, and from the inner ona wall defining the corresponding stellate cell 3. Bottom, i.e. from the base side, the transition 14 is based on both the protruding and in the cell 2, and in the star cell 3 supporting surface 17, part 17.2 of which, protruding in the cell 2, is substantially less than its part 17.1 protruding in the star cell 3. Availability Such a supporting surface provides an additional increase in bending stiffness 15 and optimal transmission of forces to the ground.

Each of the arcuate sections 6 is connected to the wall 4 of the nodal cell 1 through a reinforcing element 18 formed on the inside of the wall of the outlet cell 2 and from the inside of the wall of the star cell 3. Such reinforcing elements 18 on the wall 4 and the arcuate sections 6 have an arcuate shape, due to which also decreases the curvature of both transitions 19 between the arcuate section 6 and the wall 4 of the nodal cell 1 and the absence of ledges and ridges on them. Such transitions also provide small curvature in the transition section of each other of the two curved sections 6 in the area of the wall 4 of the nodal cell 1.

The supporting surfaces 8, on which the wall 4 of the nodal cell 1 and the arcuate sections 6 of the wall of the socket cell 2 rests, as well as the supporting surface 17, on which the transition 14 between the arcuate sections 6 of the wall of the socket cell 2 rests, pass into each other, and therefore all the walls and the arcuate sections of the walls of the outlet cell 2 rest on a continuous supporting surface, which provides a more efficient distribution of the forces acting on the grating plate and their transfer to the ground.

The walls and arcuate sections of the walls of the star cells 3 also rely on essentially interconnected supporting surfaces 8 and 17, which provides a more uniform transfer of forces acting on the grating plate to the ground.

The presence of a zigzag wall with small curvature of the transition into each other of the walls and arched sections of the walls of the nodal cells 1, rosette cells 2 and star cells 3 in combination with practically continuous supporting surfaces in the wall zone can significantly reduce the wall thickness of the grating plates while maintaining their high rigidity.

For better adhesion of the grating plate to the ground, rosette cells located in the corners of the grating plate in extreme positions along the length of its short and long edges RB are provided with bottom crossbars 20 with holes 21 for nails not driven into the ground. In addition, such cross members 20, since they connect transitions 14 from below, increase the rigidity of the corner sections of the grating plates.

The method of interconnecting a plurality of rectangular mesh plates consisting of nodal cells 1, socket cells 2 and star cells 3, as well as stacking them, corresponds to the prior art and therefore does not require detailed consideration.

Claims (8)

1. A lattice plate in the form of a solid, injection-molded plastic product for strengthening and / or planting soil, having a cellular structure formed by cells of various types, open at the level of a pedestrian or carriageway, with a drainage opening in each cell for drainage water and which is formed by nodal cells and rosette and star cells located around each of them in alternating order, bounded by walls consisting of arcuate sections, at along the edges of the grating plate there are only cut or incomplete nodal and star cells, which, when connected to adjacent grating plates, are supplemented to closed along the perimeter or full cells, and from the bottom along the edges of the grating plate at the level of its base are arranged in alternating order along its mutually opposite sides of the sliding surface, which are designed to connect the lattice plates to each other and each of which is equipped with a locking protrusion, which when connecting the lattice lit. engages and engages the opposite wall of the corresponding truncated or incomplete nodal cells, characterized in that between the arcuate portions (6) and walls sockets stellate cells (2; 3) there is an arc (14) curved in the opposite direction with respect to these arcuate sections (6), in which a reinforcing element (16) is formed by bending (15), which without ledges and zigs stabilizes the rosette cell (2) with its outer sides and a star cell (3) on its inner side, arched sections (6) pass into the wall (4) of the nodal cell (1) through a reinforcing element (18) formed on their inner and outer sides, having an arcuate shape, respectively, the shape of a crescent, and all walls (4; 6) nodal, roses accurate and stellate cells (1; 2; 3) are supported on interconnected with the lower side lattice plate support surfaces (8; 17). 2. The lattice plate according to claim 1, characterized in that the arcuate transition (14) on the lower side of the lattice plate is provided with a supporting surface (17) protruding inside the socket cell (2) and inside the star cell (3), which increases the rigidity of the corresponding socket and stellate cell (2; 3). 3. The lattice plate according to claim 2, characterized in that the protruding inside the star cell (3) part (17.1) of the supporting surface is substantially larger than the protruding part (17.2) protruding inside the rosette cell (2). 4. The grating plate according to claim 3, characterized in that the nodal cells (1) are provided with supporting surfaces (8) located on the lower side of the grating plate, which are connected to parts (17.1; 17.2) of the supporting surface of the rosette and star cells. 5. Lattice plate according to one of claims 1 to 4, characterized in that all the supporting surfaces (8; 17) are made in the form of circular segments. 6. The lattice plate according to one of claims 1 to 4, characterized in that the supporting surfaces (8; 17) are provided with auxiliary elements protruding from below towards the ground for stacking the lattice plates covering the supporting surfaces (8) of the nodal cells ( one). 7. The grating plate according to one of claims 1 to 4, characterized in that the supporting surfaces (8) of the nodal cells (1) located directly along the short edges (RB) of the grating plate have a slightly larger area than the supporting surfaces (8) nodal cells located directly along the long edges of the grid plate. 8. The grating plate according to claim 1, characterized in that the rosette cells (2) located in the corners of the grating plate in extreme positions along the length of its short and long edges (RB) are provided with cross members on the lower side of the grating plate (20), each of which has an opening (21) for a nail driven into the ground and which from the underside of the grating plate connect the opposite transitions (14) between the arcuate sections (6), increasing their rigidity.

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