RU222890U1 - Multilayer soil biomat - Google Patents

Abstract

The utility model relates to agriculture, namely to coatings intended to create anti-erosion protection of soil surfaces, as well as the creation of soil and vegetation cover on slopes, slopes and embankments. The purpose of the claimed utility model is to achieve such a technical result as increasing the reliability of a multilayer soil biomat. This goal is achieved as follows: a multilayer soil biomat in the form of a layered structure, which is a combination of a shell made of upper and lower layers of biodegradable fabric connected to each other, and a filler in the form of a substrate, which is fertile soil with plant seeds, characterized by the fact that it has rectangular in shape, the lower and upper layers of the fabric are inextricably connected at the edges and additionally connected by transverse inextricable joints that form a series of oblong cells, the thickness of the soil biomat ranges from 0.04 m to 0.12 m, and a biodegradable woven fabric is used as the fabric. The multilayer soil biomat is made from environmentally friendly materials, is easy to use, and ensures the restoration of the lost soil layer with plants. Can be used to create or restore a natural landscape.

Description

The utility model relates to agriculture, namely to coatings intended to create anti-erosion protection of soil surfaces, as well as the creation of soil and vegetation cover on slopes, slopes and embankments.

A biomat is known (patent RU 155393, published 10.10.2015), containing two layers of spunbond, between which is fixed a peat nutrient mixture prepared from peat with 45-60% moisture content with the addition of dolomite flour, urea, double superphosphate, and potassium chloride. The length of the biomat is chosen to be up to 10 m, width - up to 1.5 m, thickness - 0.006-0.008 m

However, the known technical solution has low reliability, in particular due to the use of non-woven fabrics and a thin fertile layer.

The closest known is a multilayer peat mat (application RU 2015117890, published on November 27, 2016), which is a multilayer, at least three-layer structure made of decomposing non-woven fabrics made of natural fibers placed between the layers and layers of moisture-retaining filler bonded to them in in the form of peat and an additional component, characterized in that the additional component is added to at least one of the filler layers, and as an additional component a soil mixture with plant seeds or a natural or artificial adsorbent is used, selected depending on the function of the mat, respectively, as a biomat or absorbent mat, while the layers of sheets with filler are connected by needlepunching sequentially layer by layer.

However, a disadvantage of the known design is also low reliability, in particular due to the use of non-woven fabrics.

The purpose of the claimed utility model is to eliminate the identified drawback in order to achieve a technical result - increasing the reliability of the multilayer soil biomat.

This goal is achieved as follows: a multilayer soil biomat in the form of a layered structure, which is a combination of a shell made of upper and lower layers of biodegradable fabric connected to each other, and a filler in the form of a substrate, which is fertile soil with plant seeds, characterized by the fact that it has rectangular in shape, the lower and upper layers of the fabric are inextricably connected at the edges and additionally connected by transverse inextricable joints that form a series of oblong cells, the thickness of the soil biomat ranges from 0.04 m to 0.12 m, and a biodegradable woven fabric is used as the fabric.

A multilayer soil biomat, in particular, can be characterized by the fact that the continuous connection is made by stitching.

A multilayer soil biomat, in particular, can be characterized by the fact that the continuous connection of the web is adhesive.

A multilayer soil biomat, in particular, can be characterized by the fact that the continuous connection is made with riveting.

A multilayer soil biomat, in particular, can be characterized by the fact that an inextricable connection is made with paper clips.

A multilayer soil biomat, in particular, can be characterized by the fact that the weave of the woven fabric threads is linen.

A multilayer soil biomat, in particular, can be characterized by the fact that the weave of the woven fabric threads is satin.

A multilayer soil biomat, in particular, can be characterized by the fact that burlap is used as a biodegradable fabric.

A multilayer soil biomat, in particular, can be characterized by the fact that a fabric made of cotton fibers of plant origin is used as a biodegradable fabric.

A multilayer soil biomat, in particular, can be characterized by the fact that a fabric made of jute fibers of plant origin is used as a biodegradable fabric.

A multilayer soil biomat, in particular, can be characterized by the fact that a fabric made of flax fibers of plant origin is used as a biodegradable fabric.

A multilayer soil biomat, in particular, can be characterized by the fact that a sheet of coconut fibers of plant origin is used as a biodegradable sheet.

A multilayer soil biomat, in particular, can be characterized by the fact that the density of the substrate ranges from 700 to 1300 kg/m ³ .

A multilayer soil biomat, in particular, can be characterized by the fact that the cell width is 0.4 ± 0.12 m.

A multilayer soil biomat, in particular, can be characterized by the fact that the cell length is 1.2 ± 0.36 m.

A multilayer soil biomat, in particular, can be characterized in that the density of the biodegradable web is from 180 to 320 g/m ² .

A multilayer soil biomat, in particular, can be characterized by the fact that lawn grass seeds are used as seeds.

A multilayer soil biomat, in particular, can be characterized by the fact that it additionally contains mineral fertilizers.

A multilayer soil biomat, in particular, can be characterized by the fact that it additionally contains organic fertilizers.

A multilayer soil biomat, in particular, can be characterized by the fact that it additionally contains humus.

A multi-layer soil biomat, in particular, can be characterized by the fact that it additionally contains compost.

A multilayer soil biomat, in particular, can be characterized by the fact that it additionally contains humates.

A multilayer soil biomat, in particular, can be characterized by the fact that it additionally contains soil microorganisms.

The multilayer soil biomat can be characterized in particular by the fact that it additionally contains a hydrogel.

A multilayer soil biomat, in particular, can be characterized by the fact that between the elongated cells there is space for the exchange of moisture, solutions of useful substances, and biological material.

A multi-layer soil biomat may in particular be characterized in that it further comprises a drainage layer, wherein the drainage layer may be placed under the substrate, and the drainage layer and the substrate may be separated by an additional layer of fabric.

A multilayer soil biomat, in particular, can be characterized by the fact that the top layer of the canvas is less dense than the bottom.

The essence of the claimed utility model is illustrated by drawings, where

in fig. 1 shows a general view of the claimed product;

in fig. 2 is a side view;

in fig. 3 is a sectional view;

in fig. Figure 4 schematically shows an example of stacking finished products;

in fig. 5 shows an example of the use of the proposed product;

where the numbers indicate:

1. Continuous connection at the edges

2. Transverse continuous connection

3. Cell

4. Top layer

5. Bottom layer

6. Substrate

7. Plant grains

8. Drainage layer

9. Additional separation layer

The presented multilayer soil biomat is structured as follows.

The biomat is a structure consisting of a shell in the form of upper (4) and lower (5) layers connected to each other. Inside the shell there is a layer of substrate, which is fertile soil (6) with plant grains (7).

The presented multilayer soil biomat is used as follows.

The claimed utility model relates to reclamation structures and is intended for landscaping, strengthening slopes, restoring land that has lost its fertile layer as a result of degradation of the natural ecological layer, and so on. Structures of this type known from the prior art do not possess the necessary qualities. In particular, many roll structures do not have a sufficient amount of substrate necessary, for example, for reliable seed germination in difficult climatic conditions, on predominantly rocky soils, with no fertile layer. As a result of seed germination and natural decomposition of such a biomat, the amount of nutrients for the seeds turns out to be insufficient, and restoration of the natural natural layer is impossible. The objective of this utility model is to create a reliable soil biomat that provides high biological efficiency.

The biological effectiveness of the biomat is assessed primarily in the similarity of the seeds and their further rooting. The use of designs with low reliability can lead, for example, to a violation of the integrity of the biomat before it is put into operation; low reliability may be a consequence of the inability to achieve predetermined properties. The biological effectiveness of a biomat is related to its reliability, since the more effective the biomat is in maintaining plant life, the less likely it is that problems will arise with the growth and development of plants. A reliable biomat must provide optimal conditions for plants, such as proper humidity and nutrition. If the biomat does not provide sufficiently effective support for plant life, this can lead to problems with their growth and development. Thus, the biological effectiveness of a biomat and its reliability are closely related.

In order to increase the reliability of the proposed biomat, a durable structure is created, which is based on a rectangular shape with a contoured continuous connection at the edges (1). Creating a strong connection prevents the substrate from falling out, for example as a result of long-term transportation. Additional strength of the structure is given by a number of strong, inextricable joints along the length (2), as a result of which oblong cells (“sleeves”, 3) are formed. Elongated cells divide the biomat into several compartments, in each of which the substrate is placed. This design, in addition to increasing strength, ensures uniform distribution of the substrate over the entire area of the biomat. At the same time, the reliability of uniform seed growth and the creation of a dense fertile layer with a developed, distributed root system are ensured.

Woven fabric is used as a fabric. Woven fabric is produced by weaving threads at right angles, so it has an orderly, durable structure. Unlike woven materials, non-woven materials are produced by mechanically bonding fibers and have a chaotic, disordered structure. Thus, the use of woven fabric in the proposed design provides increased reliability.

Burlap can be used as a woven fabric, as it is a rough and durable fabric. Burlap is usually made from thick yarn with a plain weave of threads from various fibers, which makes it durable and reliable, to ensure the reliability of the claimed utility model. Yarn for burlap can be made from coarse (hard bast) fibers of plant origin, for example: jute, flax, coconut, cotton, kenaf, rope, hemp and the like. The plant origin of the fibers ensures high biocompatibility with plant seeds and substrate, ensuring high efficiency of the biomat. Over time, these materials are processed into fertilizers containing plant nutrients, which further increases biological efficiency. Thus, the use of biodegradable woven material increases the strength and therefore reliability of the biomat design, while simultaneously facilitating seed germination (through the spaces between weaves).

To ensure reliability, the substrate must have a certain density and strength. Thus, in a number of experiments it was found that when the substrate density is less than 700 kg/m ³ , a loose layer is obtained. As a result of the germination of the root system, deformation of the biomat occurred, since the growth of roots created a significant bending load on the biomat. As a result, the initially laid structure of a number of biomats was destroyed, and restoration of the fertile layer was unsatisfactory. When the substrate density exceeded 1300 kg/ ^m3 , a dense layer was created in which it was difficult for plant seeds to fully develop, and low germination was observed. The optimal values that create a dense soil layer that retains its shape and location after laying and germination of seeds are substrate density values from 700 kg/m ³ to 1300 kg/m ³ . These values also show the most optimal moisture retention to ensure plant life.

At the same time, an important parameter is the thickness of the soil layer. Thus, with a biomat thickness of less than 0.04 m, the internal fertile layer was not enough for the growth and development of plants. As a result of natural processes, such as weathering and leaching of the soil, the fertile layer became significantly poorer, which over time led to the loss of a significant part of the plants. With an increase in the thickness of the biomat, the mass of the internal fertile layer increased, as a result of which the load on the joints of the structure increased, and with biomat thicknesses of more than 0.12 m, frequent destruction of integrity was observed as a result of transportation or when installation conditions were not met. Thus, as a result of a number of experiments, the optimal values of the substrate were established for the reliability of the biomat, expressed in its biological effectiveness; for this, the following parameters must be observed: the density of the substrate should be from 700 to 1300 kg/m ³ , with a thickness of the biomat from 0.04 m to 0.12 m.

Also, the reliability parameters of the proposed design can be influenced by the dimensions of the formed oblong cell. Thus, during the experiments, the optimal cell size was identified: width 0.4 ± 0.12 m, length - 1.2 ± 0.36 m. If the cell width is less than the declared one, difficulties arise in placing a substrate layer of the required thickness (more than 0. 04 m), capable of providing a stable fertile layer. With a larger cell width, the substrate could lose its shape, causing it to clump and disrupt the structure of the biomat. Exceeding the declared cell length increased the massiveness of the structure, which in turn negatively affected the connections. Reducing the cell length reduced the biological efficiency in the case of a single application of the biomat (due to the insufficient volume of the fertile layer).

In addition, a parameter that affects the reliability of the proposed design is the density of the fabric. Thus, when the density of the web is less than 180 g/ ^m2 , the claimed design is unreliable, and the risk of rupture of the web during the manufacture, transportation and installation of the biomat increases. When the density of the fabric exceeds 320 g/ ^m2 , the germination of plants decreases due to the material being too dense. Canvas with a density from 180 g/ ^m2 to 320 g/ ^m2 allows it to be stretched, creating a durable structure that retains the specified properties.

Firmware can be used to connect webs and form oblong cells. The stitching provides a continuous seam that ensures that the substrate is held securely and tightly within the biomat. For example, specialized sewing threads 210LSh PL can be used as threads. In addition, an adhesive connection can be used as a permanent connection. The adhesive connection is easily absorbed into the canvas, due to which it provides high glue consumption, but guarantees the formation of a reliable connection. Also, the formation of cells and the connection of the sheets can be done by connecting the sheets with a paper clip. Paper clips are a rigid and reliable connector, ensuring high strength of the connection point and the entire structure as a whole. Or, a rivet connection can be used as a permanent connection - a permanent connection of canvases using rivets. The rivet connection is strong and durable, which undoubtedly increases the reliability of the product as a whole.

The declared parameters of the biomat are most suitable for seeds of lawn grasses, for example, such as: perennial ryegrass, meadow clover, alfalfa, brome, meadow bluegrass, orchard grass, sweet clover and others. The optimal average size of lawn grass seeds is 5-12 mm in length and 1-3 mm in width with a seed consumption of about 2 kg/m ³ of fertile soil. The specified lawn grasses showed the highest yield, and the specified seed parameters provided high biological efficiency in combination with the other declared parameters of the biomat.

To increase the biological efficiency of a multilayer soil biomat, mineral and organic fertilizers, humus, compost, humates, and soil microorganisms can be used in the substrate, which increases soil fertility. To prevent the substrate from drying out and increase biological efficiency in arid climates, various moisture-retaining components, for example, hydrogel, can be used. In cases where biomat is used in a humid climate, drainage can be used to increase its biological efficiency (8). Drainage removes excess moisture, preventing roots from rotting. To do this, a drainage layer is placed under the substrate. In some cases, to increase reliability, so that drainage does not mix with the fertile layer with seeds, the drainage layer and the substrate can be separated by an additional layer of canvas (9).

In some cases, a design with different upper and lower layers of fabric shell may be used. For example, for some seed varieties, a less dense top layer can be used to facilitate seedling germination. At the same time, a denser bottom layer is applied, providing moisture retention and more reliable protection of young roots. Thus, by combining various upper and lower layers, high biological efficiency is achieved.

Thus, the use in the claimed utility model of a multilayer structure in the form of upper and lower layers of fabric made of biodegradable woven material firmly connected to each other at the edges, with additional strong connections along the length, with a total thickness of 0.04 m to 0.12 m, allows you to achieve the claimed technical result - reliability.

The multilayer soil biomat is made from environmentally friendly materials, is easy to use, and ensures the restoration of the lost soil layer with plants. Can be used to create or restore a natural landscape.

Claims (29)

1. Multilayer soil biomat in the form of a layered structure, which is a combination of a shell of upper and lower layers of fabric connected to each other and a filler in the form of a substrate, which is fertile soil with plant seeds, characterized in that it has a rectangular shape, lower and upper layers the canvases are inextricably connected at the edges and additionally connected by transverse inextricable joints, forming a series of oblong cells, the thickness of the soil biomat ranges from 0.04 m to 0.12 m, and a biodegradable woven fabric is used as the canvas. 2. Multilayer soil biomat according to claim 1, characterized in that the continuous connection is made by stitching. 3. Multilayer soil biomat according to claim 1, characterized in that the continuous connection of the canvas is adhesive. 4. Multilayer soil biomat according to claim 1, characterized in that the continuous connection is made with riveting. 5. Multilayer soil biomat according to claim 1, characterized in that the continuous connection is made with paper clips. 6. Multilayer soil biomat according to claim 1, characterized in that the weave of the woven fabric threads is linen. 7. Multilayer soil biomat according to claim 1, characterized in that the weave of the woven fabric threads is satin. 8. Multilayer soil biomat according to claim 1, characterized in that burlap is used as a biodegradable fabric. 9. Multilayer soil biomat according to claim 1, characterized in that a fabric made of cotton fibers of plant origin is used as a biodegradable fabric. 10. Multilayer soil biomat according to claim 1, characterized in that a fabric made of jute fibers of plant origin is used as a biodegradable fabric. 11. Multilayer soil biomat according to claim 1, characterized in that a fabric made of flax fibers of plant origin is used as a biodegradable fabric. 12. Multilayer soil biomat according to claim 1, characterized in that a canvas made of coconut fibers of plant origin is used as a biodegradable canvas. 13. Multilayer soil biomat according to claim 1, characterized in that the density of the substrate ranges from 700 kg/m ³ to 1300 kg/m ³ . 14. Multilayer soil biomat according to claim 1, characterized in that the cell width is 0.4±0.12 m. 15. Multilayer soil biomat according to claim 1, characterized in that the cell length is 1.2±0.36 m. 16. Multilayer soil biomat according to claim 1, characterized in that the density of the biodegradable fabric is from 180 g/ ^m2 to 320 g/ ^m2 . 17. Multilayer soil biomat according to claim 1, characterized in that lawn grass seeds are used as seeds. 18. Multilayer soil biomat according to claim 1, characterized in that it additionally contains mineral fertilizers. 19. Multilayer soil biomat according to claim 1, characterized in that it additionally contains organic fertilizers. 20. Multilayer soil biomat according to claim 1, characterized in that it additionally contains humus. 21. Multilayer soil biomat according to claim 1, characterized in that it additionally contains compost. 22. Multilayer soil biomat according to claim 1, characterized in that it additionally contains humates. 23. Multilayer soil biomat according to claim 1, characterized in that it additionally contains soil microorganisms. 24. Multilayer soil biomat according to claim 1, characterized in that it additionally contains a hydrogel. 25. Multilayer soil biomat according to claim 1, characterized in that between the elongated cells there is space for the exchange of moisture, solutions of useful substances and biological material. 26. Multilayer soil biomat according to claim 1, characterized in that it additionally contains a drainage layer. 27. Multilayer soil biomat according to claim 26, characterized in that the drainage layer is placed under the substrate. 28. Multilayer soil biomat according to claim 26, characterized in that the drainage layer and the substrate are separated by an additional layer of fabric. 29. Multilayer soil biomat according to claim 1, characterized in that the top layer of the canvas is less dense than the bottom.