RU102222U1 - FLEXIBLE MAT - Google Patents

Abstract

 1. A flexible mat, characterized in that it contains blocks interconnected by at least one rope, and at least one of the blocks of the mat is made in the form of a polygonal volumetric body formed by two truncated pyramids - the upper pyramid and the lower a pyramid with side and upper faces, each of which has a smaller base and is common with an adjacent pyramid, a conditional larger base, while the height of the upper pyramid does not exceed the height of the lower pyramid, and one of the faces, preferably a smaller base the lower pyramid, has a greater degree of roughness compared to a smaller upper base. ! 2. The flexible mat according to claim 1, characterized in that each of the blocks of the mat is made in the form of a polygonal monolithic volumetric body formed by two truncated pyramids, each of which has a smaller base and is common with an adjacent pyramid, conditional larger base, while, in at least one block, the height of the lower pyramid is greater than the height of the upper adjacent pyramid, and the smaller base of the lower pyramid of this block is made more rough than the smaller base of the lower pyramid. ! 3. The flexible mat according to claim 1, characterized in that the numerical value of the perimeter of the smaller base of the lower pyramid is equal to or less than the numerical value of the perimeter of the smaller base of the upper pyramid. ! 4. The flexible mat according to claim 1, characterized in that the numerical value of the area and / or volume V2 of the lower pyramid is greater than the corresponding numerical value of the area and / or volume V1 of the upper pyramid. ! 5. The flexible mat according to claim 1, characterized in that the smaller base of the lower pyramid has a relief and / or microrelief, preferably

Description

The technical solution relates to the field of construction, and in particular to means for protecting various surfaces and bases of natural or artificial origin, including underwater, and can be used in the construction of underwater crossings of pipelines, road construction, protection of bridge supports, shore strengthening, protection of the bottom of water areas ports, construction of temporary flood control structures, protection of crests of dams and dams from erosion during overflow, construction of canals, ditches and drains, protection of the bottom of sedimentation tanks, as well as other economy sectors.

A flexible protective concrete coating is known from the prior art, containing concrete blocks made in the form of double-sided strongly truncated pyramids with a common large rectangular base and interconnected in order and in rows in a single canvas of concrete blocks. Concrete blocks attached to its sides are introduced into the coating, made in the upper part in the form of strongly truncated pyramids, and in the lower part in the form of slightly truncated pyramids with a common large rectangular base, moreover, concrete blocks of both types are interconnected in order and in rows by artificial ropes, which are monolithic in concrete blocks (RU2365702 C1, E02B 3/12, 08/27/2009).

Also known from the prior art is a universal flexible protective concrete coating, which contains concrete blocks made in the form of double-sided truncated pyramids with smaller truncated bases, which are the ends of the concrete blocks on which the recesses are made, and cables connected in series and in rows along other the bases of the pyramids. The bases of the double-sided truncated pyramids of concrete blocks are made rectangular, and the distance between adjacent concrete blocks is determined by the mathematical dependence. The area of the recess opening is more than half the area of the corresponding end face of the concrete block. At the ends of the concrete blocks, cushioning pads are installed. As the cables, kapron ropes monochromatic in concrete blocks (RU2129635 C1, E02B 3/12, 04/27/1999) were used.

In addition, a universal flexible protective concrete coating is known from the prior art, containing concrete blocks interconnected by a monolithic rope, made in the form of two-sided truncated pyramids with a common large rectangular base and with smaller vertices, characterized in that the concrete blocks are asymmetric with respect to the plane of a common rectangular base pyramids (RU2364678C2, Е02В 3/12, 08/27/2008).

The disadvantages of these coatings are their not completely satisfactory adhesion to the base, the possibility of displacement of the coatings under the influence of their own weight or underwater flows, especially on rocky bases, clay bases, slopes.

The task to which the technical solution is directed is to create an effective tool for strengthening underwater surfaces, including those with complex terrain, ensuring the interaction of the mat not only with the relief, but also with the microrelief of the reinforced base, eliminating arbitrary displacements of the mat under the influence of emerging loads, increasing coefficient of friction of the mat as a whole.

The problem is solved due to the fact that the flexible mat contains blocks interconnected by at least one rope, and at least one of the blocks of the mat is made in the form of a polygonal volumetric body formed by two truncated pyramids - the upper pyramid and lower pyramid, each of which has one smaller base and common with the adjacent pyramid, conditional larger base, while the height of the upper pyramid does not exceed the height of the lower pyramid, and the smaller base of the lower pyramid has a greater degree of havoc, compared with a smaller upper base.

Each of the blocks of the mat can be made in the form of a polygonal monolithic volumetric body formed by two truncated pyramids, each of which has a smaller base and is common with an adjacent pyramid, a conditional larger base, while in at least one block the height of the lower pyramid is greater than the height the upper adjacent pyramid, and the smaller base of the lower pyramid of this block is made more rough than the smaller base of the lower pyramid.

The numerical value of the perimeter of the smaller base of the lower pyramid is equal to or less than the numerical value of the perimeter of the smaller base of the upper pyramid.

The numerical value of the area and / or volume V _{2 of the} lower pyramid is preferably greater than the corresponding numerical value of the area and / or volume V _{1 of the} upper pyramid.

A smaller base of the lower pyramid may have a microrelief, preferably of an aperiodic profile.

The roughness of the smaller base of the lower pyramid may be due to its arbitrary aperiodic profile.

The degree of roughness can be characterized by at least one of the parameters, including Ra, Rz, Rmax, Sm, S, tp, where

Ra is the arithmetic mean deviation of the profile;

Rz is the height of the profile irregularities at ten points;

Rmax is the highest profile height;

Sm is the average pitch of irregularities;

S is the average step of the local protrusions of the profile;

tp - the relative bearing length profile, where p - value profile section level, wherein, preferably, that at least one of the parameters of the smaller base of the roughness profile, for example, the arithmetic mean roughness Ra _{of n} in its absolute numerical value exceeds the corresponding parameter, for example, Ra _{in the} profile of the upper base.

The truncated pyramids of the three-dimensional body are interconnected, mainly monolithically or inextricably.

The blocks are preferably made of concrete or polymer concrete.

It is preferable that at least one rope is at least partially monolithic inside the volumetric bodies of the blocks.

The blocks are mainly made of a cured inorganic binder, for example, cement, sealed with water.

An astringent may include at least two components.

The binder preferably includes a small and / or medium and / or coarse aggregate of various fractions, such as sand and / or gravel and / or crushed stone.

The bulk body of the block can be reinforced by means of reinforcement and / or dispersed reinforcement.

Truncated pyramids of blocks can be made trihedral, tetrahedral or polyhedral.

At least one rope may be made of metal material and / or organic material and / or composite material.

At least one rope is made of artificial material, for example, of at least one polymer, for example, polyamide and / or polypropylene and / or polyester.

The breaking load of at least one rope is preferably at least 1000 kgf.

Preferably, the polymer is polypropylene or polyethylene or a polymer mixture of two or more substances.

The polymer may contain an additive to protect against the action of ultraviolet radiation, for example, a carbon additive.

The angle α of inclination of the faces of the upper pyramid may be at least 10 degrees, and preferably not less than 25 degrees to the conventional larger base, while the angle β of inclination of the faces of the lower pyramid may be at least 15 degrees, and preferably not less than 25 degrees to conditional larger base.

At least one edge of at least one of the pyramids, the volumetric body is rounded or semi-covalent or zovaulen.

Preferably, at least one rope has outlets forming mounting loops extending beyond the extreme blocks of the mat.

The mat may include at least one block whose height is less than the height of the remaining blocks.

A mat can include at least two types of blocks in which volumetric polygonal bodies are formed by pyramids with different numbers of faces, for example, one type of blocks is formed by tetrahedral pyramids, and the other by five-sided pyramids.

The technical result is to ensure the overall flexibility of the mat due to the execution of its blocks in the form of volumetric bodies made up of truncated pyramids, the thickness of which decreases from a larger conditional base to smaller ones, and connecting them with at least one flexible rope, which allows the blocks, together with flexible ropes, freely rotate relative to each other, also allowing slight displacement of the blocks of the mat in height, while providing increased adhesion (mechanical adhesion) and friction coefficient the lower parts of the blocks with the bottom due to the increase in the surface area of the lower pyramids and the fulfillment of the lower rough edge, which also ensures the stability of the mat as a whole and the absence of its displacements and fluctuations under the influence of variable and constant movements of water masses - underwater currents of tides, low tides, and terrain random entanglement working parts of construction equipment, etc., for the height H ₁ of the pyramid does not exceed the upper height H ₂ the bottom of the pyramid and the pyramid faces, preferably made rounded, as well as increasing the transformable and adaptability of the mat to the terrain or the bottom surface ..

The technical solution is illustrated by drawings, illustrating a particular case of the device and in no way limiting other possible forms of its execution, within the framework of the formula.

Figure 1 shows a separate block (isometric view).

Figure 2 shows an enlarged fragment of a rough aperiodic profile of the smaller base of the lower pyramid.

Figure 3 shows an enlarged fragment of a rough aperiodic profile of the smaller base of the lower pyramid

Figure 3 shows an enlarged fragment of a smaller base of the upper pyramid.

Figure 4 shows a flexible mat in plan (top view).

Figure 5 shows a fragment of a flexible mat laid on the bottom surface (side view).

Figure 6 shows a fragment of a flexible mat laid on the bottom surface and the pipeline (side view).

7 shows a fragment of a flexible mat laid on the bottom surface and the pipeline with blocks of different heights (side view).

On Fig shows an isometric view of the mat.

The flexible mat 1 contains blocks 2, interconnected by at least one rope 3, each of the blocks 2 of the mat 1, made in the form of a polygonal volumetric body 4, formed by two truncated pyramids - the upper pyramid and the lower pyramid 5 and 6, respectively. The upper and lower pyramids 5 and 6 have smaller bases 7 and 8, respectively, as well as one common with the adjacent pyramid, the conditional base 9. The smaller bases 7 and 8 are the upper and lower faces of the volumetric polygonal volumetric block of the block, respectively. In this case, the height H _{2 of the} lower pyramid is greater than or equal to the height H _{1 of the} lower pyramid 6 (Н _2≥ H ₁ ), and the smaller base 8 (lower face of the block) of the lower pyramid has a greater degree of roughness compared to the smaller upper base 7 (upper face block).

The height H _{2 of the} lower pyramid 6 is mainly greater than the height H _{1 of the} upper adjacent pyramid 5, with preferably equal perimeters of the smaller base of the pyramids, which provides a larger free volume V ₃ between adjacent pyramids compared to the upper pyramids 5. 6. The presence of a larger free volume V ₃ when laying the mat allows to place it in large irregularities 10, 11 or the bottom surface of the terrain, and objects 12 such as logs or stones, etc., that increases the adaptability of the mat and the degree of mechanical adhesion to the relief IU tnosti or bottom surface of the reservoir, which also contributes to a large area of the outer surface of the bottom of the pyramid.

Moreover, the implementation of the upper pyramid of a smaller volume and with a smaller external surface area allows to increase their streamlining and reduce the impact of bottom currents 14 and movements of 15 water masses, as well as the likelihood of accidental engagement of parts of the working bodies (not shown conditionally) of construction equipment, which also contributes to rounding of the ribs pyramids 5.

The roughness of the lower bases of the lower pyramids also contributes to the mechanical adhesion of the mat to the bottom surface, which is especially important on "slippery" bases, for example, rocky and / or clay (figure 5), or on surfaces with a slope (not shown conditionally).

The roughness of the smaller base of the lower pyramid is due to the microrelief on it or an arbitrary aperiodic profile of this base, which is achieved by the manufacturing technology of the flexible mat. The degree of roughness is characterized by at least one of the parameters, including Ra, Rz, Rmax, Sm, S, tp, where Ra is the arithmetic mean deviation of the profile;

Rz is the height of the profile irregularities at ten points;

Rmax is the highest profile height;

Sm is the average pitch of irregularities;

S is the average step of the local protrusions of the profile;

tp is the relative reference length of the profile, where p is the value of the profile section level.

At least one of the parameters of the roughness profile of the smaller base. preferably, the arithmetic mean deviation of the Ra profile in its absolute numerical value exceeds the corresponding profile parameter of the upper base (Fig. 3).

The blocks are made of concrete or polymer concrete, while the truncated pyramids of the volumetric bodies of 4 blocks are connected together in one piece or inseparably, and the rope 3 is monolithic inside the volumetric bodies of 4 blocks with the exception of connecting the blocks of the rope parts.

The monolithic concrete from which blocks 2 are made is prepared according to traditional technologies from an inorganic binder, for example, Portland cement, sealed with water, as well as fine medium or large aggregate - sand, gravel, gravel, etc.

To improve their physical and mechanical properties, cast concrete can be reinforced with reinforcement and / or dispersed reinforcement, made of a multi-component binder, equipped with additives or additives, etc.

Truncated pyramids of blocks in the most preferred embodiment are regular and tetrahedral. However, it is possible to make pyramids with a different number of faces.

The rope 3 connecting the blocks 2 is preferably made of a polymer, such as polyamide, polypropylene or polyester. To increase the resistance of the rope 3 to the effects of UV radiation, freezing and thawing cycles, alkaline exposure to hardening monolithic concrete, it can be made of a multicomponent polymer mixture, for example, a mixture of polyethylene and polypropylene and / or contain protective additives. So, for example, to protect against UV radiation, the polymer material from which the ropes are made may contain a carbon additive such as carbon black or carbon black.

For reliable connection of the blocks with each other and the perception of external loads, the maximum breaking load of the rope should be at least 1000 kgf, and preferably about 5000 kgf.

The angle α of the inclination of the faces of the upper pyramid is not less than 10 degrees, and preferably not less than 25 degrees to the conventional larger base, while the angle β of the inclination of the faces of the lower pyramid is not less than 15 degrees, and preferably not less than 25 degrees to the conventional larger base. The implementation of the faces with the indicated slope to the conditional common base of the pyramids allows for transformability and adaptability to the relief of the surface to be protected, to ensure the protection of underwater objects and communications, for example, pipelines 16 by approximating their surface (Fig. 5).

To ensure transportation and movement of the mat, the rope has outlets forming mounting loops 17 that extend beyond the extreme blocks 18 of the mat 1.

A flexible mat may include blocks whose height is less than the height of the remaining blocks to increase the free volume under the blocks (Fig.7). To increase the flexibility of the mat or the degree of approximation of the surface, the mat can include voluminous polygonal bodies formed by pyramids with different numbers of faces. For example, one type of mat can be formed by tetrahedral pyramids, and the other by five-sided pyramids (not shown conditionally), or within one mat there can be several types of blocks.

The operation of the device is as follows.

A flexible mat is laid on a protected object, a protected or reinforced surface, orienting it with smaller, rougher bases of the lower pyramid of blocks down towards the object or base. Due to the flexibility of the mat provided by the inclined faces of the truncated pyramids of the blocks and the ropes connecting them, the mat approximates the surface of the base or object, while part of the unevenness of the relief is placed in free space and the mat engages with the base. Additional mechanical adhesion to the base and / or object provides the roughness of the bases. Mats protect surfaces from erosion and destruction, can carry a significant vertical load.

Together, the listed features of the claimed technical solution make it possible to obtain a reliable and easy-to-use and manufacture tool for protecting and equipping various types of surface and underwater surfaces.

Claims (25)

1. A flexible mat, characterized in that it contains blocks interconnected by at least one rope, and at least one of the blocks of the mat is made in the form of a polygonal volumetric body formed by two truncated pyramids - the upper pyramid and the lower a pyramid with side and upper faces, each of which has a smaller base and is common with an adjacent pyramid, a conditional larger base, while the height of the upper pyramid does not exceed the height of the lower pyramid, and one of the faces, preferably a smaller base the lower pyramid, has a greater degree of roughness compared to a smaller upper base. 2. The flexible mat according to claim 1, characterized in that each of the blocks of the mat is made in the form of a polygonal monolithic volumetric body formed by two truncated pyramids, each of which has a smaller base and is common with an adjacent pyramid, conditional larger base, while, in at least one block, the height of the lower pyramid is greater than the height of the upper adjacent pyramid, and the smaller base of the lower pyramid of this block is made more rough than the smaller base of the lower pyramid. 3. The flexible mat according to claim 1, characterized in that the numerical value of the perimeter of the smaller base of the lower pyramid is equal to or less than the numerical value of the perimeter of the smaller base of the upper pyramid. 4. The flexible mat according to claim 1, characterized in that the numerical value of the area and / or volume V _{2 of the} lower pyramid is greater than the corresponding numerical value of the area and / or volume V _{1 of the} upper pyramid. 5. The flexible mat according to claim 1, characterized in that the smaller base of the lower pyramid has a relief and / or microrelief, preferably of an aperiodic profile. 6. The flexible mat according to claim 1, characterized in that the roughness of the smaller base of the lower pyramid is due to its arbitrary aperiodic profile. 7. The flexible mat according to claim 1, characterized in that the degree of roughness is characterized by at least one of the parameters, including Ra, Rz, Rmax, Sm, S, tp, where Ra is the arithmetic mean deviation of the profile; Rz is the height of the profile irregularities at ten points; Rmax is the highest profile height; Sm is the average pitch of irregularities; S is the average step of the local protrusions of the profile; tp is the relative reference length of the profile, where p is the value of the profile section level, and at least one of the profile roughness parameters of the smaller base, for example, the arithmetic mean deviation of the profile Ra _n exceeds its corresponding absolute value, for example, Ra _in profile upper base. 8. The flexible mat according to claim 1, characterized in that the truncated pyramids of the three-dimensional body are interconnected monolithically or inextricably. 9. The flexible mat according to claim 1, characterized in that the blocks are made of concrete or polymer concrete. 10. The flexible mat according to claim 1, characterized in that at least one rope is at least partially monolithic inside the volumetric bodies of the blocks. 11. The flexible mat according to claim 1, characterized in that the blocks are made of a cured inorganic binder, such as cement, sealed with water. 12. The flexible mat according to claim 1, characterized in that the astringent includes at least two components. 13. The flexible mat according to claim 1, characterized in that the binder includes a small and / or medium and / or large aggregate of various fractions, such as sand and / or gravel and / or crushed stone. 14. The flexible mat according to claim 1, characterized in that the volumetric body of the block is reinforced by means of reinforcement and / or dispersed reinforcement. 15. The flexible mat according to claim 1, characterized in that the truncated pyramids of the blocks are trihedral and / or tetrahedral and / or polyhedral. 16. The flexible mat according to claim 1, characterized in that at least one rope is made of metal material and / or organic material and / or composite material. 17. The flexible mat according to claim 1, characterized in that at least one rope is made of artificial material, for example, of at least one polymer, for example polyamide and / or polypropylene and / or polyester. 18. The flexible mat according to claim 1, characterized in that the breaking load of at least one rope is at least 1000 kgf. 19. The flexible mat according to claim 17, wherein the polymer is polypropylene, or polyethylene, or a polymer mixture of two or more substances. 20. The flexible mat according to claim 17, wherein the polymer contains an additive for protection against the action of ultraviolet radiation, for example, a carbon additive. 21. The flexible mat according to claim 1, characterized in that the angle α of inclination of the faces of the upper pyramid is not less than 10 °, and preferably not less than 25 ° to a conventional larger base, while the angle β of inclination of the faces of the lower pyramid is not less than 15 °, and preferably at least 25 ° to a conventional larger base. 22. The flexible mat according to claim 1, characterized in that at least one edge of at least one of the pyramids, the volumetric body is rounded, or semi-covalent, or zauovlen. 23. The flexible mat according to claim 1, characterized in that at least one rope has outlets forming mounting loops extending beyond the extreme blocks of the mat. 24. The flexible mat according to claim 1, characterized in that the mat includes at least one block whose height is less than the height of the remaining blocks. 25. The flexible mat according to claim 1, characterized in that it includes at least two types of blocks in which volumetric polygonal bodies are formed by pyramids with different numbers of faces, for example, one type of blocks is formed by tetrahedral pyramids and the other five-sided pyramids.