RU2753353C1 - Protective anti-landslide retaining structure and method for erection thereof - Google Patents

Abstract

FIELD: building.

SUBSTANCE: invention relates to the field of environmental protection and ensuring environmental safety of urban areas and the population from erosion and landslide developments. It can be used in creation of territorial plans for the development of recreational areas in regions subject to such natural and technological impact. The technical result is achieved by developing a territory with buildings and structures 1, creating a base and a soil-reinforced mass 2 with location of blocks made as soil-filled shells therein, mounting a soil-filled base-abutment-shell 4 with a soil-filled base-shell 5, a rigid frame 10 and the front wall 9 are installed and fixed with a second attachment unit 11, a soil-filled shell 12 is attached, the upper part thereof is made waterproof and equipped with a water outlet apparatus 15 through the second attachment unit 11 whereto the rigid frame 10 and the front wall 9 are fixed, said frame and wall are fixed with a third attachment unit 16 whereto a soil-filled slab-shell 17 with a rain drainage tray 18 is attached. The upper parts of the soil-filled slab-shell 17 and the soil-filled shell of the base 5 are covered with a polymeric material with seeds 7. One or more reinforcing tapes 19 with a drainage system 20 filled with sorbent 21 and placed in a waterproof shell ring 22 are placed in the soil-reinforced mass 2 in the attachment units 8, 11, 16. The front wall 9 is additionally covered with the polymeric material with seeds 7. All structural elements are made of heterogeneous composite nano-materials. "PINEMA" material is used as the polymeric material with seeds 7.

EFFECT: technical result of the invention is ensured reduction of natural and technological impact on urban and similar settlements due to use of new technological solutions for creation of structures using heterogeneous composite nano-materials.

7 cl, 1 dwg, 1 tbl

Description

The invention relates to the field of environmental protection and ensuring the environmental safety of urban development and the population from erosion and landslide phenomena. It can be used to create territorial plans for the development of recreational zones in areas subject to these natural and technogenic impacts.

A known bank-protecting retaining wall, consisting of tank elements, connecting elements made of trough-shaped forms in the cross-section of the plates, the rear part of the tank and the connecting element with its convex part facing towards the protective coast, and the trough-shaped plates are rigidly connected to each other using bolts passed through the holes left ...

Author's certificate No. 1313943, "Shore protection retaining wall" published on 05/30/1987, IPC Е02В 3/06.

The disadvantage is the complexity of work on the construction of a bank protection retaining wall, incl. and filling containers.

A coastal protection structure is known, consisting of a wave-breaker wall with a visor, the curved surface of which is outlined along a hypocycloid; in the lower part, a protrusion with a height of 1 / 8-1 / 4 of the maximum wave height is made

Copyright certificate No. 669001, "Shore protection structure", published on June 25, 1979, IPC Е02В 3/06.

The disadvantage is the complexity of the construction work.

A ground-reinforced structure of flexible strips is known, containing a protective surface made of flexible material and reinforcing elements attached to it in the form of flexible strips, the reinforcing elements are woven into the protective surface, which is made of interwoven flexible strips, while the free ends of the strips are interconnected in pairs, cut into in the longitudinal direction by an even number of strips with the ends of the reinforcing tapes interwoven and fastening to the anchoring devices either in the form of loops formed by fixing the free end of the tape on the tape itself, or in the form of perforation holes at the free ends of the reinforcing tapes with the formation of strips by a cut along the axis of the holes, and the indicated the strips are laid in a fan, described in RF Patent No. 2181407., "A method for creating soil-reinforced structures from flexible tapes and a device for its implementation", published: 20.04.2002, IPC E02B 3/06.

The disadvantage is that the flexible tapes do not fit snugly enough.

Known retaining structure, taken as a prototype, consisting of blocks, divided into two parts left and anchor, anchor tooth at the base of the structure. The lower anchor parts of the blocks are made in the form of a drainage device, consisting of a return filter and perforation of the shell in the places of contact with the backfill soil, and the outflow of filtration water is carried out through a large-porous backfill, described by Inventor's certificate No. 647391 "Retaining structure", published on February 15, 1979, IPC E02B 3/06.

The disadvantage is the development of areas prone to erosion and landslide processes, requiring significant costs for their construction and disposal of surface waters.

Known technology for the construction of a retaining structure, taken as a prototype, including tearing off the trench with the laying of elastic panels and backfill with soil. After that, a drainage device is made with block stacking. The technology of erection of the retaining structure is described in the author's certificate No. 647391 "Retaining structure", published on February 15, 1979, IPC Е02В 3/06.

The disadvantage is the development of areas prone to erosion and landslide processes, requiring significant costs for their construction and disposal of surface waters.

The objective of this invention is to create a protective anti-landslide retaining structure and a method for its construction from erosion and landslide processes in the territories, contributing to the development of regions and ensuring the protection of the population and structures from the effects of natural and man-made processes.

The technical result of the invention is to ensure the reduction of natural and man-made impacts on urban and similar settlements, through the use of new technological solutions for the creation of structures using heterogeneous composite nanomaterials.

The technical result in terms of the structure is achieved due to the fact that the protective anti-landslide retaining structure, including the developed area with buildings and structures, the base, with the blocks located on it, contains a soil-reinforced array, with blocks located in it, made as soil-filled shells, and the base as a soil-filled shell-stable-base, with a soil-filled shell with a base, made of heterogeneous composite nanomaterials, moreover, in the lower part of the soil-filled shell of the base there is a roughness, and its upper part is covered with a polymer material with seeds, the soil-filled shell, the base is connected by the first attachment point with the front wall made made of heterogeneous composite nanomaterials and fixed on a rigid frame, through the second attachment point it is connected to a soil-filled shell made of heterogeneous composite nanomaterials filled with a sand-crushed stone mass with the addition of orbents and equipped in the lower part with a filter frame with a roughness, and its upper part is made waterproof and equipped with a device for discharging water through the second attachment point, and through the third attachment point, the front wall is connected to a soil-filled shell-plate with a rain drainage tray made of heterogeneous composite nanomaterials , the upper part of the soil-filled shell-slab is covered with a polymeric material with seeds, in the first, second and third attachment points one or more reinforcement belts made of heterogeneous composite nanomaterials are placed. located at an angle of 20-60 ° to the surface of the soil-reinforced massif, and at the ends of each armolent 9 in the soil-reinforced massif there is a drainage system filled with a sorbent and placed in a waterproof shell, the length of the soil-filled shell is made equal to or greater than the length of the soil-filled shell-slab, the front wall additionally covered with polymeric material with seeds.

The material "PINEMA" is used as a polymeric material with seeds.

The territory to be developed includes areas of greening of the environment.

The technical result in terms of the method is achieved due to the fact that in the method of erecting a protective anti-landslide retaining structure, which consists in equipping a territory with buildings and structures, they create bases, with blocks on it, and also create a soil-reinforced array, with blocks made, as soil-filled shells, a soil-filled shell-stable-base is mounted on the base, with a soil-filled shell with a base made of heterogeneous composite nanomaterials, the lower part of the soil-filled shell of the base is made with a roughness, and its upper part is covered with a polymer material with seeds, the soil-filled shell is connected to the first an attachment point to which a rigid frame is reinforced and a front wall made of heterogeneous composite nanomaterials are fixed with a second attachment point, to which a soil-filled shell made of heterogeneous composite nanomaterial is attached ov, fill it with a sand-crushed stone mass with the addition of sorbents and provide roughness in the lower part, and its upper part is made waterproof and equipped with a device for releasing water through a second attachment point, to which a rigid frame and a front wall are reinforced, they are fixed with a third attachment point, to which a soil-filled shell-slab with a rainwater drainage tray made of heterogeneous composite nanomaterials is attached, the upper part of the soil-filled shell-slab is covered with a polymer material with seeds, in the first, second and third attachment points, one or more reinforcements of heterogeneous composite nanomaterials are placed at an angle of 20-60 ° to the surface of the soil-reinforced massif, and at the ends of each armolent in the soil-reinforced massif there is a drainage system, which is filled with a sorbent and placed in a waterproof shell, the front wall is additionally covered with a polymer material with seeds, and a soil-filled shell, are performed along a length equal to or greater than the length of the soil-filled shell-slab.

The material "PINEMA" is used as a polymeric material with seeds.

Operations for the formation of a protective anti-landslide retaining structure alternate with filling and ramming the bulk soil to the required height of the retaining structure.

On the territory being developed, greening zones of the environment are equipped.

Heterogens are systems containing more than one phase.

Heterogeneous composite nanomaterials are systems consisting of nanomaterials of different composition or origin, dissimilar parts, divided into 3 classes.

matrix system, which consists of a continuous phase (matrix) and a dispersed phase (discrete particles);

compositions with fibrous fillers;

compositions having a reciprocal structure of two or more continuous phases.

Heterogeneous composite nanomaterials for shell structural elements can have different specified properties: elasticity, durability, preservation of data of specified shapes (initial, design).

Composite nanomaterials have common properties: environmental friendliness, safety, reliability, elasticity, flexibility, durability, preservation of the original shape, however, each of them can carry additional properties, for example, provide the least friction between elements (tribological properties), greater rigidity and elasticity (additives lithium powder, etc.), create protective properties for the purification of contaminated water (sorption), etc. They acquire these properties at the stage of manufacturing (technology) of their production and can be combined into a single object while maintaining a common function (general properties) that can interact in various environments (water, air, solid and liquid pollution, etc.). Examples of composite materials and their characteristics that ensure the functioning of the proposed technical solution are shown in the table

Changing the properties of these materials at the points of application of the resultant forces and maximum stresses is possible due to polymer nanomaterials with shape memory, i.e. having the ability, after removing the load, to return to its original state without residual deformations. Combinations of bentonite mats made of geotextile with polystyrene foam with sorption properties and other modern composite materials can be used as nanomembranes with sorption properties.

Composite nanomaterials proposed for use are given in:

- PNST 2013-2017 “Nanomaterials. Nanomodified protective mixtures. Technical requirements and test methods "

- GOST R 50583-93 "Composite polymer materials"

- GOST 33742-2016 "Interstate standard. Polymer composites "

FIG. 1 shows a longitudinal section along the axis of a protective anti-landslide retaining structure.

1 - developed area with buildings and structures;

2 - soil-reinforced massif;

3 - slip line;

4 - soil-filled shell-stable-base

5 - soil-filled shell base;

6 - roughness;

7 - polymeric material with seeds;

8 - the first attachment point;

9 - front wall;

10 - rigid frame;

11 - the second attachment point;

12 - soil-filled shell;

13 - sand and crushed stone mass with the addition of sorbents;

14 - roughness;

15 - water outlet device;

16 - third attachment point;

17 - soil-filled shell-slab;

18 - shower tray;

19 - arm tape;

20 - drainage system;

21 - sorbent;

22 - waterproof shell;

23 - plantings;

24 - soil;

25 - base.

A protective anti-landslide retaining structure, includes a developed area with buildings and structures 1, a soil-reinforced array 2, subject to landslide processes, divided by a slip line 3, base 25, with blocks located on it, made as soil-filled shells. The base 25 is made as a soil-filled shell-abutment-base 4, provided to prevent shear of the soil-filled base 5. The soil-filled shell-abutment-base 4 and the soil-filled shell base 5 are made of heterogeneous composite nanomaterials. In the lower part of the soil-filled shell of the base 5, a roughness 6 is made, which retards the movement of the soil-filled shell of the base 5 under loads, and its upper part is covered with a polymer material with seeds 7, which germinating play the role of holding the soil-reinforced massif 2. The soil-filled shell of the base 5 is connected by the first attachment point 8 with the front wall 9, made of heterogeneous composite nanomaterials and fixed on a rigid frame 10, through the second attachment point 11 is connected to the soil-filled shell 12 made of heterogeneous composite nanomaterials filled with sand-crushed stone mass with the addition of sorbents 13, ensuring the stability of the soil-reinforced array 2, design shape and environmental safety, and provided with a roughness 14 in the lower part, and its upper part is made waterproof and equipped with a water outlet 15 through the second attachment point 11, and through the third attachment point 16, the front wall 9 s is connected to the soil-filled shell-slab 17 with a rain drainage tray 18 laid in front of it, made of heterogeneous composite nanomaterials, the upper part of the soil-filled shell-slab 17 is covered with a polymer material with seeds, in the first 8, second 11 and third 16 attachment points one or more armolents 19, made of heterogeneous composite nanomaterials and located at an angle of 20-60 ° to the surface of the soil-reinforced array 2, and at the ends of each armolenta 19 in the soil-reinforced array 2 there is a drainage system 20 filled with sorbent 21 and placed in a waterproof shell 22, which protects against technogenic impacts. The drainage system 20 provides the minimum moisture capacity of the soil-reinforced array 2. The length of the soil-filled shell 12 is made equal to or greater than the length of the soil-filled shell-slab 17, the front wall 9 is additionally covered with a polymer material with seeds 7. The material "PINEMA" is used as a polymer material with seeds 7. The territory under development 1 includes zones of greening of the environment-planting 23 and is located on a natural foundation-soil 24.

The protective anti-landslide retaining structure works as follows. Under the influence of a load on the territory being developed with buildings and structures and when it is threatened by a landslide process, arm bands 19 come into operation, which hold the front wall 9. Arm bands 19, soil-filled shell 12, soil-filled shell-slab 17, soil-filled shell base 5, soil-filled shell- abutment-base 4 connected to attachment points 8, 11 and 16 do not allow the soil-reinforced array 2 to move.

When overflowing from the storm drainage tray 18 with surface or man-made waters, the provided drainage system 20, filled with a sand-crushed stone mass with the addition of sorbents 21, and placed in a waterproof shell 22, which allows collecting drainage water, protects against man-made influences, comes into operation. The upper part of the soil-filled shell 12 is made waterproof and equipped with a device 15 through which water is discharged through the second attachment point 11. When the load on the front wall 9 is applied, the arm bands 19 and the soil-filled shell-plate 17 come into operation, the soil-filled shell base 5, the soil-filled shell - anchorage-base 4, keeping the entire protective anti-landslide system in working position.

A method of erecting a protective anti-landslide retaining structure, which consists in equipping a territory with buildings and structures 1 and creating a soil-reinforced array 2. First, blocks made as soil-filled shells are placed on the prepared base 25, a soil-filled shell-abutment-base 4 is mounted on the base, with a soil-filled shell base 5, made of heterogeneous composite nanomaterials, the lower part of the soil-filled shell of the base 5 is made with a roughness 6, and its upper part is covered with a polymer material with seeds 7, the soil-filled shell of the base 5 is connected to the first attachment point 8, to which the rigid frame 10 and the front wall are reinforced 9, made of heterogeneous composite nanomaterials, is fixed with a second attachment point 11, to which a soil-filled shell 12, made of heterogeneous composite nanomaterials is attached, is filled with a sand-crushed stone mass with the addition of sorbents 1 3 and provided in the lower part with a roughness 14, and its upper part is made waterproof and provided with a water discharge device 15 through the second attachment point 11, to which the rigid frame 10 and the front wall 9 are reinforced, then they are fixed with the third attachment point 16, to which they are attached the soil-filled shell-slab 17 with a rain drainage tray 18 made of heterogeneous composite nanomaterials, the upper part of the soil-filled shell-slab 17 is covered with a polymer material with seeds 7, in the first 8, second 11 and third 16 attachment points, one or more reinforcements 19 are placed, located at an angle of 20-60 ° to the surface of the soil-reinforced array 2, and at the ends of each armolenta 19 in the soil-reinforced array 2 there is a drainage system 20, which is filled with a sorbent 21 and placed in a waterproof shell 22, the front wall 9 is additionally covered with a polymer material with seeds 7 , and the soil-filled shell 12 is made along a length equal to or greater for and no soil-filled shell-slab 17. Operations for the formation of a protective anti-landslide retaining structure alternate with filling and ramming soil 24 to the required height of the retaining structure.

The material "PINEMA" is used as a polymeric material with seeds 7.

On the territory being developed, they equip zones of greening of the environment, plantings 23.

Claims (7)

1. Protective anti-landslide retaining structure, including a developed area with buildings and structures, a base with blocks located on it, characterized in that it contains a soil-reinforced massif with blocks located in it, made as soil-filled shells, and the base as a soil-filled shell-stable-base, with a soil-filled shell with a base, made of heterogeneous composite nanomaterials, moreover, in the lower part of the soil-filled shell of the base there is a roughness, and its upper part is covered with a polymer material with seeds, the soil-filled shell base is connected by the first attachment point with the front wall made of heterogeneous composite nanomaterials and fixed to rigid frame, through the second attachment point is connected to a soil-filled shell made of heterogeneous composite nanomaterials filled with sand-crushed stone mass with the addition of sorbents and equipped in the lower part with a filter frame with roughness, and its upper part is made waterproof and equipped with a device for water discharge through the second attachment point, and through the third attachment point, the front wall is connected to a soil-filled shell-slab with a rain drainage tray made of heterogeneous composite nanomaterials, the upper part of a soil-filled shell-slab covered with a polymer material with seeds, in the first, second and third attachment points there are one or more reinforced tape made of heterogeneous composite nanomaterials, located at an angle of 20-60 ° to the surface of the soil-reinforced massif, and at the ends of each reinforced tape in the soil-reinforced massif there is a drainage system filled with a sorbent and placed in a waterproof shell, the length of the soil-filled shell is made equal to or greater than the length of the soil-filled shell-slab, the front wall is additionally covered with a polymer material with seeds. 2. Protective anti-landslide retaining structure according to claim 1, characterized in that the material "PINEMA" is used as a polymeric material with seeds. 3. Protective anti-landslide retaining structure according to claim 1, characterized in that the territory being developed includes areas of greening of the environment. 4. A method of erecting a protective anti-landslide retaining structure, which consists in equipping an area with buildings and structures, creating a base, with blocks on it, characterized in that they create a soil-reinforced array, with blocks in it, made as soil-filled shells, on the basis of a soil-filled shell-stable-base, with a soil-filled shell base, made of heterogeneous composite nanomaterials, the lower part of the soil-filled shell of the base is made with roughness, and its upper part is covered with a polymer material with seeds, the soil-filled shell is connected to the first attachment point, to which a rigid frame is reinforced and the front wall, made of heterogeneous composite nanomaterials, is fixed with a second attachment point, to which a soil-filled shell made of heterogeneous composite nanomaterials is attached, filled with a sand-crushed stone mass with added with sorbents and provide a roughness in the lower part, and its upper part is made waterproof and equipped with a device for releasing water through the second attachment point, to which a rigid frame and front wall are reinforced, they are fixed with a third attachment point, to which a soil-filled shell-plate with a rainwater drain is attached a tray made of heterogeneous composite nanomaterials, the upper part of the soil-filled shell-slab is covered with a polymer material with seeds, in the first, second and third attachment points, one or more reinforced tape made of heterogeneous composite nanomaterials are placed, located at an angle of 20-60 ° to the surface of the soil-reinforced massif , and at the ends of each armolent in a soil-reinforced massif there is a drainage system, which is filled with a sorbent and placed in a waterproof shell, the front wall is additionally covered with a polymer material with seeds, and the soil-filled shell is made along a length equal to or greater than the length of the soil floor removable shell-slab. 5. A method of erecting a protective anti-landslide retaining structure according to claim 4, characterized in that the material "PINEMA" is used as a polymeric material with seeds. 6. A method of erecting a protective anti-landslide retaining structure according to claim 4, characterized in that the operations to form a protective anti-landslide retaining structure alternate with filling and ramming the bulk soil to the required height of the retaining structure. 7. A method of erecting a protective anti-landslide retaining structure according to claim 4, characterized in that green zones of the environment are equipped on the territory being developed.

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