RU2314666C1 - Method for pre-sowing preparing of plant seeds - Google Patents

Abstract

FIELD: agriculture, in particular, plant growing.

SUBSTANCE: method involves pressing powder of biocompost or peat having particle sizes less than 2.5x2.5 mm, or mixture of said powders for producing container with blind cavity; placing seed of farm medicinal, garden or decorative crop into cavity of container thus produced; pressurizing cavity containing seed so as to reduce volume of forming substance used for pressurizing of said cavity by 1.5-1.8 times; during pressing procedure, maintaining moisture content of powder of forming biologically digested substance within 12-14% and imparting shape of truncated cone to cavity containing seed, said cone having generatrix arranged at an angle of 20-35 deg to axis of cavity and smaller base oriented inward of container.

EFFECT: improved retention and germination of seeds due to seed encapsulation and provision for optimal pre-sowing preparation of plant seeds.

3 cl, 2 dwg

Description

The invention relates to the field of agriculture, namely to the field of crop production, and can be used for containerization of seeds of agricultural crops, as well as garden, medicinal and ornamental plants before planting in the ground. In addition, the method can find application in growing seedlings of fruit, coniferous and other tree species.

In the framework of the present invention, the term “containerization” means placing a seed of a plant in a specially made container for planting in the soil, the purpose of which is to protect the seed from damage and supply them with nutrients from the moment of germination after planting in the soil.

The term "biocontainer" means a container, the material of which contains mainly biologically assimilable by the plant substances, including organic and inorganic nutrients, biologically active substances and other components that contribute to the intensive growth and development of plants. Adhesives and binders are not part of the biocontainer material.

A known method of pre-sowing preparation of plant seeds, according to which a polymer layer is applied to the seed, which forms a protective capsule around the seed (French application No. 2459587, CL A01C 1/06, op. 1980).

The disadvantage of this method is the difficulty in breathing the seed when stored in a capsule, as well as the restriction of nutrients from the soil at the initial moment of plant growth, as well as due to the slow destruction of the polymer capsule in the soil. At the same time, the composition of the capsule itself lacks any nutrients and biologically active substances, which delays the development of the plant after planting in the soil.

Closest to the claimed one is a method of pre-sowing preparation of plant seeds, including the formation of a two-layer biocontainer by pressing from a formative biologically assimilable substance, the formation of a cavity for it in the seed, the placement of the seed in the cavity of the biocontainer, pressing the cavity with the seed in the biocontainer (RF patent No. 2264698, cl. A01C 1/06, op. November 27, 2005).

In the known method, as a form-forming biologically assimilable substance of the outer shell, a mixture of biocompost is used in an amount of up to 80% by weight of the total bio-container, complex mineral fertilizer ("amofoska" or "nitrophoska") in an amount of up to 4% by weight of the total bio-container, the binder is carboxymethyl cellulose in an amount of up to 5.9% by weight of the total bio-container, water sorbent - microgranules of polyacrylic gel in an amount of up to 1.0% by weight of the total bio-container, trace elements and biologically active substances, including cobal molybdenum, boron, zinc, magnesium, as well as salts of gibberellic acid, phenoxyacetic acid, succinic acid, in an amount up to 0.1% by weight of the total bio-container, with the addition of a filler - expanded perlite.

The composition of the inner shell includes the above components, but without mineral salts and water sorbent, while the biocompost is up to 85% by weight of the total bio-container.

From the first feed hopper, the mixture for the outer shell of the biocontainer is dosed into the first matrix of the rotor device mounted on the table of the rotor device rotating around a vertical axis. Then the table of the rotor device is rotated by 45 ° and the first profiled punch produces a cavity in the material of the outer shell to the size of the inner shell of the biocontainer. Then the table of the rotor device is rotated another 45 ° and from the second feed hopper the material for the inner shell of the biocontainer is metered into the same matrix of the rotor device. Then, after the next step-by-step rotation of the table of the rotary device by 45 °, the second profiled punch forms a cavity in the material of the inner shell of the biocontainer for grain, for example, corn. Then, after turning, the corn grain is dosed into the matrix from the seed hopper. Then, after turning the table of the rotary device, the inner spherical biocontainer with a diameter of 20 mm is molded using the third profiled punch. Next, they carry out the next step-by-step rotation of the table of the rotor device and form the outer shell of the biocontainer (40 mm in diameter) with the fourth profiled punch. Then, after turning the table from the matrix with the help of a pusher, the lifting and delivery of the formed bio-container to the collection is carried out. The prepared bio-containers are dried and sent to the warehouse.

The disadvantage of this method is the low preservation of seeds prepared by this method, and as a consequence of this, low germination and slow development of plants. This is because the mixture for pressing the outer and inner shells of the biocontainer contains a binder in its composition - carboxymethyl cellulose, which, when storing the biocontainer, makes it difficult for the seed to breathe, which is accompanied by the absorption of oxygen, the release of carbon dioxide, heat and moisture. If breathing of seeds is difficult, their preservation is reduced and germination is reduced. In the future, plants grown from such seeds lag behind in development and have lower yields. At the same time, when a seed is placed in a bio-container freshly prepared by a known method, its moisture content sharply increases, because a binder is a water soluble compound. With increased humidity, a sharp increase in the respiration of the seed occurs, leading to a multiple increase in the expenditure of the seed's own nutrients and, accordingly, to a decrease in its germination. Therefore, a freshly made container, together with the seed enclosed in it, has to be intensively dried, thereby stressing the seed.

Another disadvantage is the high probability of damage to the seed when pressing the container. Another disadvantage of this method, due to the use of an adhesive substance - carboxymethyl cellulose when pressing the biocontainer, is the destruction of the biocontainer in the soil too slow, which leads to a delay in seed awakening, a later emergence of the sprout on the soil surface, and a slower plant development.

In addition, the known method due to the presence of sequential operations to create a part of the outer shell of the biocontainer, the formation of the first cavity (cavity) in it, the creation of part of the inner shell of the biocontainer, the formation of the second cavity (cavity) in it, the formation of the remaining parts, first the inner and then and the outer shell is complicated, and therefore unnecessarily energy intensive.

The inventors were tasked with creating a method of pre-sowing preparation of plant seeds by their containment, which, on the one hand, would not have aggressive, damaging effects on the seed during its processing and would create the most comfortable conditions when storing the treated seed. On the other hand, the task was to create such a method of containerization of seeds, which would ensure optimal conditions for the germination of seeds and the development of plants after planting bio-containers in the ground.

The technical result achieved by the claimed method is to improve the preservation of the seed and increase its germination by improving the humidity and respiration conditions of the seed during storage, as well as by eliminating stress in the form of moisture and subsequent drying of the treated seed, eliminating damage to the seed during pressing cavity, in ensuring a faster disintegration of the biocontainer into separate parts in moist soil with the effect of concomitant cultivation of the soil due to a significant the expansion of the biocontainer when it swells under conditions of high humidity. At the same time, a simplification of the method is achieved by reducing the pressing operations and moving the container from one processing position to another, which can significantly increase the number of produced bio-containers, since the process can be fully automated.

The specified technical result is achieved by the fact that in the method of pre-sowing preparation of plant seeds, including the formation of a biocontainer by pressing from a formative biologically assimilable substance, the formation of a blind cavity for it in the seed, the placement of the seed in the cavity of the biocontainer, as well as the pressing of the cavity with the seed in the biocontainer, as formative biologically assimilable substances using biocompost powder or peat powder with a particle size of not more than 2.5 × 2.5 mm or a mixture of these powders s, pressing the biocontainer is carried out with a 2 ... 4-fold decrease in the volume of the formative biologically assimilable substance and combine it in time with the formation of a cavity for the seed in the biocontainer, pressing the cavity with the seed is carried out with a 1.5 ... 1.8-fold decrease the volume of the forming substance used to press the cavity.

The specified result is also achieved by the fact that the moisture content of the powder of the biologically assimilable forming substance during pressing is maintained within 12 ... 14%.

The indicated result is also achieved by the fact that the cavity for the seed in the biocontainer gives the shape of a truncated cone with a generatrix located at an angle of 20 ... 35 ° to the axis of the cone, and a smaller base facing the inside of the biocontainer.

The drawings show the design of the biocontainer used in the implementation of the claimed method. Moreover, figure 1 shows a biocontainer at the stage of pressing its preform and forming a deaf cavity under the seed in it, and figure 2 shows a fully formed biocontainer.

The biocontainer used in the implementation of the inventive method comprises a biocontainer blank 1, for example a spherical shape, with a blind cavity 2 (FIG. 1) made therein to receive the seed 3 (FIG. 2) of the plant, the sealing element 4, in 3 parts removed from the seed which contains mineral elements and biologically active and nutrients 5. The density of the material of the sealing element 4 is 1.1 ... 2.6 the density of the material of the workpiece 1 of the bio-container. The blind cavity 2 is made in the form of a truncated cone with a generatrix 6 located at an angle α = 20 ... 35 ° to the axis of the cone, and a smaller base 7 (in a particular case, having a hemispherical shape) facing the inside of the bio-container.

The claimed method is as follows.

A form-forming biologically assimilable substance is prepared to form a bio-container. As a form-forming biologically assimilable substance, any substance is used, on the one hand, capable of being a biologically assimilated plant after awakening the seed (in the presence of sufficient moisture) and, in part, after processing by soil microorganisms, and, on the other hand, capable of decreasing the volume of the pressing process to acquire the desired shape and mechanical strength (i.e., to undergo shaping), and also to preserve them during prolonged exposure to conditions that are optimal to ensure dormancy of the seeds of the respective plants.

As such a substance can be used crushed to a powdery form with particle sizes of not more than 2.5 × 2.5 mm and dried to a state of flowability, biocompost, peat (mainly horse) or a mixture thereof in a proportion, which, in the particular case, is determined by selecting the best compressibility index. The presence of natural impurities in the forming biologically assimilable substance is allowed. However, in its pure form, biocompost, or peat, or a mixture thereof makes up at least 97% of the mass of the formative biologically assimilable substance (in terms of dry matter) used in pressing the biocontainer. Additional application of any binders (gluing) substances is not allowed, since such substances impede the achievement of the claimed technical result, because impair seed germination and slow down the subsequent development of plants.

To obtain biocontainers, a rotary-type apparatus with a horizontal rotary worktable is used, similar in design to the apparatus described in RF patent No. 2264698. A cylindrical glass with a matrix installed in it, having a concave (for example, hemispherical) work surface, corresponding, for example, to the lower half of the surface of a future bio-container, is fixed on a rotary working table. Previously or simultaneously with the pressing process, a biologically assimilable form-forming substance is prepared, for example, in the form of a powder of a biocompost crushed to a particle size of 2.5 × 2.5 mm or in the form of a powder of a peat crushed to the same particle size (mainly peat) or as a mixture of these powders (for example, 15 ... 35% is peat powder, and the rest is biocompost powder). The glass is uniformly, without the formation of voids, filled with a formative biologically assimilable substance in a volume 2 ... 4 times the volume of the obtained preform 1 biocontainer. Optimal for pressing the biocontainer is the humidity of the formative biologically assimilable substance 12 ... 14%. After that, a form-forming biologically assimilable substance is pressed (with preliminary partial pressing of this substance or without preliminary pressing) with a punch having a surface shape corresponding, for example, to the upper half of the surface of a future bio-container. It can also be a hemispherical surface, but unlike the prototype, this surface additionally contains a protrusion tapering to its end, for example, in the form of a truncated cone with a generatrix located at an angle of 20 ... 35 ° to the axis of the cone. Thus, in one stroke of the punch, a biocontainer blank 1 was obtained having the desired external shape and already containing cavity 2, for example, having the shape of a truncated cone with a generatrix 6 located at an angle of 20 ... 35 ° to the axis of the cone and a smaller base 7 ( in a particular case, a hemispherical shape) facing the inside of the bio-container. This ensures greater uniformity of the properties of the already compressed biocontainer material compared to the prototype, which guarantees better storage conditions for the plant seed in it, primarily in terms of temperature and humidity conditions, as well as respiration conditions. However, by combining in time the operations of forming the biocontainer itself and forming the cavity 2 for the seed, the overall process time is reduced. Pressing can be both percussive (when using, for example, a crank press), and smooth: a punch moves slowly at 70 ... 85% of its path (elastic deformation of the pressed material occurs in this section) and accelerated by 10 ... 15 times on the final segment of its path (when using a hydraulic press with a controlled pressing speed), the forces of intermolecular interaction of the components of the pressed material are manifested. The pressing pressure is set in the range of 70 ... 120 kg / cm ² . After the process is completed, the punch is removed from the glass and the installation desktop is rotated to a new position. In this position, a seed 3 of a plant is preliminarily prepared (for example, dried and treated with biologically active substances) along a guide tube in a blind cavity of a biocontainer.

The table is rotated to a new position, in which cavity 2 and the space above it are filled with a biologically assimilable form-forming substance, the amount of which is selected in such a way as to provide a 1.5 ... 1.8-fold decrease in its volume during pressing. A punch with a hemispherical working surface is used to press in cavity 2 with a biologically assimilable substance. As a result, a sealing element 4 is formed, which prevents the seed 3 from falling out of the cavity 2 and at the same time provides improved air and moisture exchange of the seed with the environment due to the fact that it has a lower density compared to the density of the rest of the biocontainer material. When filling the cavity 2 with a formative biologically assimilable substance in its third part, the farthest from the seed 3, it is possible to place additional biologically active and nutrient substances 5 (for example, in the form of granules or powder). As biologically active substances, microbial biological preparations can be used, in particular organic bioregulators with fungicidal properties, microbial insecticides, biostimulants, bio-products, etc.

The depth of the cavity 2 for the seed is chosen so that its bottom surface (with a conical shape of the cavity - the smaller base 7 of the cone) is located from the outer surface of the biocontainer at a distance L of 0.1 ... 0.25 of the total height H of the biocontainer in the direction axis of the cavity 2. This achieves a decrease in the force exerted on the seed 3 when pressing the cavity 2. This effect is especially pronounced with the conical shape of the cavity 2, since the pressing forces are partially redistributed to the side walls of the cavity 2.

The installation desktop is rotated to a new position, in which the formed biocontainer is ejected from the matrix. Rotate the table to its original position. After that, the matrix is ready for pressing a new bio-container. The cycle is repeated.

The seeds prepared in the described manner in bio-containers are stored in a warehouse under conditions corresponding to the optimal conditions for storing seeds. The composition of the biocontainer material (without the use of adhesives or other binders) provides the best moisture conditions and respiration of the seed during storage, and thereby higher germination of seeds prepared by the claimed method.

At the onset of the planting season, biocontainers with seeds are planted in moist soil. Since the biocontainer material does not contain adhesives or other binders, it quickly absorbs moisture from the soil, intermolecular interaction forces are torn, and under the action of elastic forces, the biocontainer increases its volume by 2 ... 4 times over several hours and gradually collapses. This ensures a kind of cultivation of the soil around the seed, and biologically assimilable substances contained in the material of the biocontainer are more quickly absorbed by the plant, ensuring its accelerated development.

Claims (3)

1. The method of pre-sowing preparation of plant seeds, including the formation of a bio-container by pressing from a formative biologically assimilable substance, the formation of a blind cavity for it in the seed, placing the seed in the cavity of the bio-container, pressing the cavity with the seed in the bio-container, characterized in that as the formative biologically absorbable substance use biocompost powder or peat powder with particle sizes not exceeding 2.5 × 2.5 mm or a mixture of these powders, pressing the biocontainer from 2 ... 4 -fold reduction in the volume of the forming biologically assimilable substance and combine it in time with the formation of a cavity for the seed in the biocontainer, pressing the cavity with the seed is carried out with a 1.5 ... 1.8-fold decrease in the volume of the forming substance used for pressing. 2. The method according to claim 1, characterized in that the moisture content of the powder of the formative biologically assimilable substance during pressing is maintained within 12 ... 14%. 3. The method according to claim 1, characterized in that the cavity for the seed in the biocontainer gives the shape of a truncated cone with a generatrix located at an angle of 20 ... 35 ° to the axis of the cone, and a smaller base facing the inside of the biocontainer.

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