RU183402U1 - Erosion protection coating - Google Patents

Abstract

The proposed technical solution relates to the field of construction and is intended to strengthen and protect soil surfaces, for example slopes of soil planning embankments, roads and railways, as well as quarries, dry slopes of earth dams, etc. from erosion processes by quickly restoring the soil and plant layer. An anti-erosion coating is proposed that contains the lower 1 and upper 2 layers bonded together, mixtures of 3 plant seeds, organic fertilizers and water-retaining additives, characterized in that the upper layer is made of synthetic fibers resistant to biodegradation laid with the formation of a grid with embossed bulges in the form of staggered equidistant hollow mesh hemispheres 4 with the formation of support surfaces between them 5 for bonding the upper layer with the lower layer made of biodegradable non-woven material, which during the laying of fibers during its manufacture includes mixtures of plant seeds, organic fertilizers and water-retaining additives. The service life and effectiveness of the proposed anti-erosion coating are achieved by using in the design all the advantages of anti-erosion coatings from biodegradable materials for growing grass cover and from materials resistant to biodegradation To strengthen and protect the ground surface, and performing on the mesh surface of embossed protuberances retaining soil on the surface anti-erosion coating during germination of grass. 7 c.p. f-ly, 2 Fig.

Description

The proposed technical solution relates to the field of construction and is intended to strengthen and protect soil surfaces, for example, slopes of soil planning embankments, roads and railways, as well as quarries, dry slopes of earth dams, etc. from erosion processes by quickly restoring the soil and plant layer.

Known anti-erosion coating of the geomat type, made in the form of a honeycomb structure of a non-woven geotextile, hardened by fitting and stitched seams of flexible strips installed on the ribs and interconnected by linear stitches arranged in a checkerboard pattern

(see RF Patent No. 2180030, class E02D 17/20, 2001)

The flexible strips this device is made of are non-woven fabric tapes and are made primarily of high-strength synthetic fibers. The discrete porous structure of the strips provides low material consumption and high permeability of the structure. When performing reinforcement work, the geomat is installed on a pre-planned and compacted slope surface and stretched into working condition.

The use of this material allows you to well strengthen the soil surface.

However, the natural grass cover growing through the cells is not sufficient to prevent soil erosion.

It is also known, another anti-erosion coating of the biomat type, containing, bonded to each other, the lower and upper layers, plant seeds and mixtures of organic fertilizers and water-retaining additives.

(see RF Patent No. 2321982, class A1C 1/04, 2006)

In this device, the upper and lower canvases mainly consist of natural fibers, which, when biodegradable, form a nutrient medium for plants, and the middle layer, in addition to plant seeds, additionally contains a nutrient mixture consisting of fertilizers, plant growth stimulants and soil-forming additives.

The use of this coating can effectively prevent soil erosion due to the intensive development of vegetation.

However, this coating does not allow to strengthen soil surfaces, especially on slopes.

The task solved by this development is the creation of an anti-erosion coating that combines the advantages of geomats and biomats.

The technical result of the development is to increase the effectiveness of anti-erosion coating.

This result is achieved by creating an anti-erosion coating containing the lower and upper layers bonded to each other, a mixture of plant seeds, organic fertilizers and water-retaining additives, while the upper layer is made of biodegradation-resistant synthetic fibers laid with a mesh with embossed bulges in the form of staggered the order of equidistant hollow mesh hemispheres with the formation of supporting surfaces between them for bonding the upper layer with the lower layer made of iorazlagaemogo nonwoven fabric, in which during ulozhenija fibers incorporated in its manufacture a mixture of plant seeds, organic fertilizers and humectants additives.

It should be noted that the top layer may be made of polyamide, polyester or polypropylene fibers or a mixture of these fibers.

In addition, the lower layer can be made of interconnected biodegradable natural fibers of flax or mixed fibers with the addition of natural or synthetic fibers with a predominant content of flax in the mixed fiber.

Moreover, during the laying of the fibers in the manufacture of non-woven material, it can be mixed with seeds of perennial and annual herbs in an amount of 60-100 g / m ² , and a mixture of organic mineral fertilizers and water-retaining additives in an amount of 20-40 g / m ² .

It is advisable to fasten the upper and lower layers in a needle-punched manner.

It is possible to fasten the upper and lower layers by thermo-gluing in the process of forming a three-dimensional network structure on a substrate from the lower layer.

It is also possible to fasten the upper and lower layers by heat bonding with rolling the bottom layer of the sheet with a roller to the supporting surfaces on the mesh surface, preheated to the softening temperature of the mesh material.

In addition, it is possible to bond the upper and lower layers using quick-drying water-based glue.

Improving the effectiveness of the proposed anti-erosion coating is achieved through the use in the design of all the advantages of anti-erosion coatings from biodegradable materials for growing grass and materials resistant to biodegradation to strengthen and protect soil surfaces, as well as by performing on the mesh surface relief bumps that hold the soil on the surface of the anti-erosion coating in the process of germination of herbs.

In FIG. 1 - shows the erosion control coating in the context; in FIG. 2 is a view A in FIG. one.

The anti-erosion coating (Fig. 1) contains the lower 2 and upper 1 layers bonded to each other, plant seeds and a mixture of 3 organic mineral fertilizers and water-retaining additives. The upper layer is made of synthetic fibers, laid with the formation of a network with embossed bulges in the form of staggered hollow mesh hemispheres 4 arranged in a checkerboard pattern (Fig. 2), between which flat mesh supporting surfaces 5 are formed, and the lower layer is made of non-woven material, in which during fiber laying during its manufacture, seed mixtures of perennial and annual herbs are included.

Anti-erosion coating is made as follows.

The bottom layer 2 of non-woven material is made from interconnected biodegradable natural fibers of flax or mixed fibers with the addition of natural or synthetic fibers with a predominant content of flax in the mixed fiber. Non-woven material is made in one of the known ways, when the weaving transducer repeatedly folds the webs removed from the carding machine and forms a multilayer fibrous web of a certain width and surface density with a transversely oriented arrangement of fibers, which are laid in layers with a surface density in the range of 150-450 g / m ² . With a decrease in the indicated density, it is difficult to maintain the shaping of the material, and with an increase, problems with seed germination can occur. Separate layers of fibrous canvas are interconnected by means of a needle punching machine. The compacted fibrous canvas from this roll enters the slat conveyor, during which along the surface of the canvas by means of two metering devices evenly distributed mixtures of 3 seeds of perennial and annual herbs in an amount of 80 g / m ² (with an accuracy of ± 25%), i.e. . 60-100 g / m ² , and a mixture of organic fertilizers and water-retaining additives in an amount of 30 g / m ² (with an accuracy of ± 30%), i.e. 20-40 g / m ² . Thus, their retention in the composition of the coating during its transportation and installation is ensured. Layers of nonwoven material are interconnected by means of a needle punching machine. The top layer 1 in the form of a mesh is made from biodegradation resistant synthetic fibers. These include, in particular, polyamide, polyester or polypropylene fibers, or mixtures of these fibers, widely used in industry. The mesh is made by extrusion. Viscous molten polymers are passed through small extruder dies, forming thin molded structures, which are then randomly intertwined. Using a molding shaft with hemispherical recesses with a diameter of 12 ± 5 mm, embossed bulges are formed on the grid in the form of staggered, equally spaced from each other at a distance of 10 ± 5 mm hollow mesh hemispheres 4 between which flat mesh supporting surfaces are formed 5. Hemisphere dimensions and the thickness of the layers may vary depending on the geometry and agrotechnical features of the surface on which the coating is laid. On the supporting surfaces, the bottom layer of a nonwoven material with a filler is attached to the grid with a needle-punched, or other equivalent known method. Other ways of connecting the coating layers to each other along the supporting surfaces are: bonding using quick-drying water-based glue, which is used carboxymethyl cellulose (CMC), which is applied to the supporting surface; thermal bonding with the rolling of the non-woven fabric panel with an unheated roll to the supporting surfaces previously preheated to the melting temperature of the material of which the mesh is made; thermal bonding with the nonwoven material of the lower layer during the manufacturing process of the mesh at the softening temperature of the material of the synthetic fibers of which it is made.

The finished anti-erosion coating in the form of a roll is delivered to the place of operation, laid on the surface of the reinforced slope so that the fibrous canvas with the seeds of grass and organic fertilizers included in its structure comes into contact with the soil surface, and is dusted with soil 2-3 cm. Non-woven material containing flax fiber already decomposes by 100% in the second year of operation, which eliminates any possible obstacles to the growth of herbs. While the mesh fabric of biodegradation resistant synthetic fibers still serves to strengthen and protect the ground surfaces. In this case, embossed bulges in the form of staggered, equidistant hollow mesh hemispheres hold the soil on the mesh surface during the germination of grasses.

The design of the proposed anti-erosion coating allows you to combine high anti-erosion characteristics of the product with high efficiency of work on the restoration of disturbed lands.

Claims (8)

1. An anti-erosion coating containing the lower and upper layers bonded together, mixtures of plant seeds, organic fertilizers and water-retaining additives, characterized in that the upper layer is made of biodegradation-resistant synthetic fibers laid with a mesh with embossed bulges in the form of staggered the order of equidistant hollow mesh hemispheres with the formation of supporting surfaces between them for bonding the upper layer with the lower layer made of biodegradable non-woven fabric rial, in which, during the laying of fibers during its manufacture, mixtures of plant seeds, organic fertilizers and moisture-retaining additives are included. 2. Anti-erosion coating according to claim 1, characterized in that the top layer is made of polyamide, polyester or polypropylene fibers or a mixture of these fibers. 3. Anti-erosion coating according to claim 1, characterized in that the lower layer is made of interconnected biodegradable natural fibers of flax or mixed fibers with the addition of natural or synthetic fibers with a predominant content of flax in the mixed fiber. 4. Anti-erosion coating according to claim 1, characterized in that during the laying of the fibers during the manufacture of the nonwoven material, it contains a mixture of seeds of perennial and annual herbs in an amount of 60-100 g / m ² and a mixture of organomineral fertilizers and water-retaining additives in an amount of 20 -40 g / m ² . 5. Anti-erosion coating according to claim 1, characterized in that the upper and lower layers are bonded with a needle-punched method. 6. Anti-erosion coating according to claim 1, characterized in that the upper and lower layers are bonded by thermo-bonding in the process of forming a three-dimensional network structure on a substrate from the lower layer. 7. Anti-erosion coating according to claim 1, characterized in that the upper and lower layers are bonded by heat bonding with the lower layer of the sheet rolled up to supporting surfaces on the mesh surface, previously heated to the softening temperature of the mesh material. 8. Anti-erosion coating according to claim 1, characterized in that the upper and lower layers are bonded using quick-drying water-based glue.

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