RU162188U1 - REINFORCING NET OF MULTILAYERED BIOMAT - Google Patents

Abstract

1. The reinforcing mesh of the multilayer biomat, made in the form of a system of polyester warp and weft, bonded to each other at the points of their intersection with a stitching thread to form cells, characterized in that the stitching thread forms a warp knit with the intersection of the warp and weft. 2. Reinforcing mesh according to claim 1, characterized in that the piercing thread forms, at the intersection of the warp and the weft, an interlacing “leotard.” 3. The reinforcing mesh according to claim 1, characterized in that the cells are formed by overlaying the weft on the base.

Description

The utility model relates to the field of agricultural products for the technical restoration of disturbed lands, in particular for restoration of the soil and plant layer, as well as for strengthening and protecting natural and artificial soil surfaces from erosion processes.

Known reinforcing mesh designed for multilayer biomat, made, as a rule, using polyethylene or polypropylene fibers (http://meaplast.ru/proizvodstvo-biomatov/).

The disadvantages of the analogue include the following. As a rule, the mesh size of the reinforcing mesh is 3-5 mm, which is due to the need to achieve high tensile strength properties, since the biomats under consideration are subject to significant tensile loads when used on steep slopes and until the plants grow into the ground. At the same time, the size of seeds traditionally used in biomats is mainly 6-8 mm or more, respectively, in the process of laying the seeds are either on top or under the reinforcing mesh. In the first case, the cover formed by the sprouted plants is uniform, but the connection of the root system with the soil is weak, since the reinforcing mesh impedes its development. In the second case, good penetration of the root system into the soil is ensured, however, the uniformity of the cover is deteriorated, the development of which is prevented by the reinforcing mesh. However, the strength properties of the plastic used do not significantly increase the tensile strength of the reinforcing mesh.

The closest to the claimed technical solution - the prototype - is a reinforcing mesh made in the form of a system of polyester warp and weft threads, impregnated with a bitumen composition and bonded to each other at their intersections and to the substrate with a piercing thread (http://geospan.gexa.ru/ poliefirnaya-setka).

The main purpose of the prototype is to use it as a geogrid, in which the base and weft are very massive and impregnated, due to which the fixation of the cells can be provided with simple firmware.

The disadvantages of the prototype include limited technological capabilities due to the limited scope, for example, the inability to use biomats as a reinforcing mesh, since bitumen impregnation negatively affects plants (seeds, their germination, etc.), and the massiveness of the geogrid, its basis and a duck, which is quite justified when reinforcing, for example, soils or asphalt pavements, is unacceptable in biomats that require minimal weight and size characteristics while ensuring the required strength x (mainly - to break) properties.

The exclusion from the reinforcing mesh according to the prototype impregnation and the use of non-massive warp and weft (with a small amount of polyester fibers) revealed the impossibility of fixing the cells with simple firmware - the piercing thread does not hold, the connection of the weft and the warp is spreading.

Based on the foregoing, the objective of the utility model is to create a reinforcing mesh without impregnation and with a small amount of polyester fibers in the warp and weft, but with reliable cell fixation, suitable for use in multilayer biomats and with increased tensile strength for cell enlargement to ensure good germination.

The technical result is the expansion of the technological capabilities of the reinforcing mesh.

The problem is solved, and the claimed technical result is achieved by the fact that in the reinforcing mesh, made in the form of a system of polyester warp and weft, bonded to each other at the places of their intersection with a stitching thread, the stitching thread forms a warp knit with the intersection of the warp and weft, it is optimal when The piercing thread forms, at the intersection of the warp and the weft, a “leotard” weave, it is advisable when the cells are formed by overlaying the weft on the warp.

The utility model is based on the properties of polyester fiber in relation to the design of the reinforcing mesh, suitable for use in biomat. The properties used include:

- excellent resistance to solvents, including organic, mold, light weather, moths, microorganisms, carpet bug;

- low thermal conductivity and good elasticity;

- the tensile strength of polyester fibers is higher than that of other types of chemical and natural fibers, while they are much lighter;

- resistance to abrasion;

- excellent heat resistance - polyester fibers are superior to most natural fibers in this parameter.

It was experimentally found that, since polyester fibers have an extremely low coefficient of friction, due to the small friction of the polyester fibers against each other when forming a reinforcing mesh by simple weaving, it is practically impossible to stabilize the relative position of the warp and weft, i.e. the cells "walk", arbitrarily decreasing and increasing, which impedes the solution of the task.

As noted above, fixing the cells with simple firmware is also ineffective - the firmware thread does not hold, the connection of the weft to the base spreads.

The solution to neutralize the effect of these factors was to bond the warp and weft to each other at the points of their intersection with the piercing thread so that the piercing thread forms a reliable weave with the intersection of the warp and weft.

The selected solution is based on an analysis of the properties of various weaves performed on standard machine tool equipment:

- cross-knit weaves are characterized by high extensibility and elasticity, good loosening, elasticity. Such weaves are preferred in the manufacture of upper, linen, hosiery;

- warp knit webs (such as chain, tights, satin) are less elastic, practically do not open due to the fact that the formation of loops in the weave does not occur sequentially by bending one thread, but simultaneously from a system of threads.

Accordingly, a reliable weave in relation to the claimed object was the basic knitting weave (http://alcala.ru/bse/izbrannoe/slovar-P/P11866.shtml). At the same time, it was experimentally established that the interweaving of tights is optimal from the point of view of reliability-material consumption (see ibid.). Technologically warp knitting is more convenient to perform when the intersections are equally formed by laying a weft on the base, without weaving them.

The possibility of using the claimed reinforcing mesh, unlike the prototype, as part of the biomat is fully confirmed experimentally, while the operation of the utility model is practically no different from the work of the analogue (http://meaplast.ru/proizvodstvo-biomatov/) - the reinforcing mesh is placed in place in a multilayer biomat. At the same time, with increased cell sizes of the reinforcing mesh, the biomat demonstrates excellent root system penetration into the soil and cover density - up to 15-20% higher than that of the analogue. In addition, due to the elasticity and elasticity of the claimed reinforcing mesh, there is a more dense adherence to soil irregularities than that of the prototype, which also improves the quality characteristics of the biomat, which are determined by the qualitative indicators of the reinforcing mesh, due to its better "adhesion" to the soil.

The foregoing allows us to state that the task is to create a reinforcing mesh without impregnation and with a small amount of polyester fibers in the warp and weft, but with reliable cell fixation, suitable for use in multilayer biomats and with increased tensile strength for cell enlargement to ensure good germination, it was solved, and the claimed technical result - the expansion of the technological capabilities of the reinforcing mesh - was achieved.

The analysis of the claimed technical solution for compliance with the conditions of patentability showed that the characteristics indicated in the formula are essential and interconnected with the formation of a stable set of necessary features, unknown at the priority date from the prior art and sufficient to obtain the claimed technical result.

Thus, the above information indicates the fulfillment of the following set of conditions when using the claimed technical solution:

- an object embodying the claimed technical solution, when implemented, relates to the field of agricultural products for the technical restoration of disturbed lands, in particular for restoration of the soil and plant layer, as well as for strengthening and protecting natural and artificial soil surfaces from erosion processes;

- for the claimed object in the form described in the utility model, the possibility of its implementation using the methods and methods described above or known from the prior art on the priority date has been confirmed;

- the object embodying the claimed technical solution, when implemented, is able to ensure the achievement of the technical result perceived by the applicant.

Therefore, the claimed object meets the criteria of patentability "novelty" and "industrial applicability" under applicable law.

Claims (3)

1. The reinforcing mesh of the multilayer biomat, made in the form of a system of polyester warp and weft, bonded to each other at the points of their intersection with a stitching thread to form cells, characterized in that the stitching thread forms a warp knit with the intersection of the warp and weft. 2. The reinforcing mesh according to claim 1, characterized in that the piercing thread forms, at the intersection of the warp and the weft, a “leotard” weave. 3. The reinforcing mesh according to claim 1, characterized in that the cells are formed by overlaying the weft on the base.