RU2692551C1 - Seedling planting method, spiral cartridge, collapsible cellular cassette, polyhedral pot - Google Patents

Abstract

FIELD: agriculture.SUBSTANCE: method can be used by private gardeners and truck-farmers, breeders, as well as small, medium and large agricultural enterprises. Seedlings are grown in empty or partially (or completely) soil-filled sachets arranged in cells of a rolled-up cassette, and in another version - in cells of the demountable cassette. Performing the second stage of the method, the seedlings together with sachets or cells of the dismountable cartridge are transplanted into pots. Used multi-faceted pots have the shape of six- or octagonal hollow prisms with legs 20, which are manually or automatically assembled from reamers. With such method and implementation of devices it becomes possible to divide in two stages of transplanting vegetables, poorly carrying transplantation, cost price of seedlings decreases by not less than 10 %, at least for two weeks reducing the transplant period of vegetables and berries growing.EFFECT: reduced labour costs, easier maintenance of seedlings, prolonged period of fruiting, water, thermal and electrical energy saving, reduced consumption of soil for seedlings, rational use of available areas, seedlings are not damaged during transportation, mechanization of their transplantation becomes possible.10 cl, 16 dwg

Description

The invention can be used in the cultivation of vegetables, berries, flowers, saplings of trees, shrubs and vines, as well as in the manufacture of containers for growing seedlings.

In the field in areas with adverse natural conditions and in greenhouses, many vegetables are cultivated by seedling. Agricultural enterprises seedlings of vegetables and flowers are grown in greenhouses, and tens of millions of Russian gardeners and gardeners [1] - on window sills. In most cases, seedlings are bred in a two-step process: first, seedlings are raised from a seed in a limited amount of soil, and then they are grown in a larger area of nutrition. Seedlings are grown in common drawers, in plastic cups or in plastic cellular cassettes, representing several rows of cups, connected by bridges. Plastic cellular cassettes supplanted previously used Finnish paper [2]. Plastic was economically more profitable, but lost a number of significant signs of its predecessor. Paper cups were porous, which provided good conditions for root gas exchange of seedlings. Finnish cassettes were collapsible: seedlings were transplanted along with alternately breakable cups. Thus, the plant roots were protected from damage, the seedlings took root in the new place without wasting time, and cups, decomposing in the soil, fertilized it. Finnish cassettes were manufactured by an expensive method (stamping), so their cost was high. Plastic cassettes are significantly more expensive, but they serve for many years, and the cost of acquiring them has little effect on the cost of seedlings. However, plastic cassettes need to be sanitized using environmentally hazardous disinfectants. At the end of the life of the plastic containers have to be disposed of, which also reduces the efficiency of their use.

After the appearance of at least two true leaves, the seedlings are transferred to a new place of growth by picking (alternatively, by transshipment). At the phase of the cotyledon leaves, they are not transplanted because the damage caused to immature stems and roots turn out to be disastrous. Tightening the transplantation terms extends the seedling period of vegetable cultivation. And this is the inefficient use of space, the waste of water and energy. The roots of plants extracted from the common box during a picking are injured twice: first - when they are dug out of the soil, and then - when the surplus is removed. The injuries slowed down the subsequent development of the seedlings, and the maturation of the crop is delayed for up to two weeks. Seedlings grown in plastic vessels are transplanted after preliminary drying of the soil for several days. Grabbing fingers for the lower part of the stalk, plants with soil lumps are removed from the cups and rolled over to a large area of nutrition. And while seed transplantation transplants less traumatized, the further development of seedlings still slows down. When the soil is dried, the plants wither, and this reduces the amount of organic matter accumulated during photosynthesis. Seedlings of vegetables that do not tolerate transplantation are grown in one stage - the plants are transferred to a permanent place of growth in the phase of several true leaves.

Known [3] amateur version of the hydroponic method of growing seedlings of peppers and tomatoes. On a tape of black plastic film (it was called the substrate) is placed a piece of toilet paper. The paper is moistened, the seeds are laid out on it, the same strip of toilet paper is put on top and it is all rolled up in a roll, which is immersed in water. The roots grow in the space between the layers of wet toilet paper twisted into a three-dimensional helix, and the stalks and leaves of the plants develop on top of it. Before transplanting the roll is unrolled, the seedlings, together with the torn strips of paper, are transferred to the soil of large containers for growing.

Known [4] the method of growing seedlings, in the implementation of which the seeds are sown in the soil "snail". A scroll was called a substrate rolled into a roll (foam polypropylene tape) with a layer of soil between the turns of the three-dimensional spiral. The roll is set vertically, seeds are embedded in the soil, the plants are watered from above. It turned out [5] that the seedlings of certain types of vegetables in snails develop much worse than those grown in a common box or cups. In particular, onions sprout, but soon rot, and from the seeds of the peppers (if the seedlings are transplanted in the phase of these leaves), excellent seedlings are obtained [6]. Apparently, those plants whose root system needs more soil oxygen develop poorly. Since the propylene substrate is airtight, oxygen to the roots of the seedlings comes only through the rather narrow upper and lower spiral layers of the cochlea soil. There is not enough oxygen coming from above, the main roots rush down, adventitious roots weaken, the plants are degrading.

The considered rolls are two variants of a primitive spiral cassette. In the first case, there is a long flattened paper vessel between the turns of the substrate, which, when transplanted, is torn apart, and the cavity in the cochlea is the cavity between the turns of the substrate. Such spiral cassettes do not have dividing partitions, the roots of plants intertwine and are damaged when transplanted during transplantation.

The Dutch technology of cultivation of tomatoes in a closed ground is known [7], to date, almost everywhere displaced by hydroponics. In the implementation of the Dutch method, the seeds are sown in the soil of plastic cassette cells, subsequently the soil with the grown seedlings is dried. Plants with lumps of soil are rolled into pots made of a material that decomposes in the soil. Seedlings transplanted manually - this greatly increases the cost of seedlings. Grown up plants are transferred to the ground along with pots, which provides reliable protection of the roots from damage. Excess water, which is watered seedlings and seedlings, is removed through holes, specially provided in the bottom of the cells of the cassettes and pots. Plastic cassettes and pots should not touch stagnant water - they are raised above the supporting surfaces, and this is unnecessary labor and material costs. Oxygen to the roots of seedlings growing in plastic cassettes comes from above and through the holes in the bottom of the cells, carbon dioxide moves in the opposite direction. It is obvious that the root gas exchange of plants growing in porous pots occurs more intensively than in plastic cassettes. The outer sides of the pots of seedlings, placed on the shelves of greenhouses, are washed by ascending air mixed with a large amount of water vapor. High humidity due to the extremely developed surface of the pots. Thus, the total outer surface area of a thousand conical cups, having a height of 85 and diameters of 75/50 millimeters, exceeds 17.3 square meters. Since the casings of the seedling pots are porous and rough, their surface area accessible to the surrounding air is immeasurably larger. Obviously, the water that is being sprinkled on the seedlings is used inefficiently — on the damp surface of the pots, a significant part of it turns into steam. Vaporization is an energy-intensive process: during the transformation of each gram of water, 1.2 liters of steam are formed and 2.3 kilojoules of heat are absorbed. Due to evaporation of water, the root system of the seedlings is cooled by several degrees, which slows down the development of plants. Moreover, the plants that are being diluted from below need extra heating in the cold. Uncontrolled water losses in the form of steam, the overrun of thermal and electrical energy increase the cost of seedlings. Nevertheless, it is obvious that a certain amount of water from the surface of the pots must evaporate - without this process, intense root exchange of the seedlings is impossible.

Pots decomposing in the ground are used not only for breeding seedlings, but also for growing saplings of trees, shrubs and vines.

Seed pots made of waste paper (or peat and binders) available on the market are unnecessarily massive - the thickness of their walls reaches 2-3 millimeters. Due to this manufacturing technology - they are stamped. Excessive consumption of raw materials, as well as small-scale, or, at best, the medium-volume nature of production significantly increase the cost of pots. It is not only a matter of cost: the thick shells of the pots are a formidable obstacle to the roots. A lot of energy is expended on overcoming shells, the development of plants slows down.

A thin-walled pot, having the form of a polygonal straight prism, is known - it is collected from a reamer made of a material decomposing in the soil [8]. When assembling the pot, the elements of the sweep are held together by bending petals inserted into the corresponding slots. The locking device used is unreliable: the bent fragile petals can break, and the pot collapses when filled with soil. The side faces of the prefabricated pots installed in rows on the shelves of greenhouses may touch, which makes it possible to drastically reduce the surface area that evaporates water. However, gaps should be left between the faces of the neighboring pots (they are necessary to ensure the root gas exchange of plants), and this technique makes it difficult for workers to work. The prefabricated pots in question have another drawback - they have to be raised above the supporting surfaces.

Known scans cardboard packaging boxes designed to protect the goods placed in them from damage and exposure to the environment. When assembling boxes, automatic machines are used - the elements of development are held together by gluing or locking systems, in particular, knife locks with arrow-shaped petals [9].

The first of the group of proposed inventions allows to eliminate the disadvantages of the known versions of the two-stage method of breeding seedlings of vegetables, berries and flowers cultivated in open and protected ground. The purpose of the other inventions is to improve the vessels in which seedlings are grown, seedlings are grown, and the cuttings of trees, shrubs and lianas are rooted.

These interrelated problems are resolved by solving four technical problems related to a single inventive concept.

The first technical problem is solved by changing the conditions for the implementation of actions that characterize a known method of breeding seedlings.

The initial stage of the four versions of the proposed method has the same features with its counterpart. In particular, seedlings are grown in vessels made of porous organic material that decomposes in the soil. In the claimed and known methods, it is also common that seedlings in a large area of nutrition are transplanted together with the vessels in which they were raised.

In the first stage of the three versions of the claimed method, a well-known technique is used: seedlings are grown in flattened vessels located between the turns of the substrate of the spiral cassette.

Carrying out the first two versions of the method, the lower part of the spiral cassette is immersed in an aqueous solution of nutrients, and food to the roots of seedlings is delivered through the capillaries of the vessel shells.

In the second stage of all versions of the proposed, as in the implementation of the known method, seedlings grow in vessels filled with a large amount of soil.

The first version of the considered method differs from the analogue in that the seedlings grow separately from each other - their roots are in flattened sachets placed in the cells of the spiral cassette.

New in the second version of the claimed method is that the seedlings are grown in the soil, which is filled with the upper part of the bags placed in the cells of the spiral cassette.

New in the third version of the proposed method is that the seedlings are bred in soil-filled flattened bags placed in the cells of the spiral cassette.

The fourth version of the claimed method is characterized in that the seedlings are grown in cells (or cups) of a collapsible cassette, made with legs, and also with perforations in bridges.

площадь питания пересаживают на фазе семядольных листочков (или после появления одного настоящего листочка). Рассаду доращивают в почве, находящейся в ячейках (или стаканчиках) разборной кассеты, присоединенных друг к другу перемычками, выполненными с перфорацией, а также с ножками. Осуществляя другой вариант второй стадии способа, сеянцы доращивают в почве сборных шести- или восьмигранных горшочков с ножками.New in all versions of the claimed method is also changing the conditions for the implementation of the second stage of growing seedlings. In contrast to the known method, seedlings on

the food area is transplanted in the phase of cotyledon leaves (or after the appearance of one true leaf). Seedlings are grown in the soil located in the cells (or cups) of the folding cassette connected to each other by jumpers made with perforation, as well as with the legs. Carrying out another variant of the second stage of the method, the seedlings grow in the soil of teams of six or octahedral pots with legs.

The second technical problem is solved by improving the known spiral cassette. The claimed spiral cassette is specifically designed for use in the implementation of the first three versions of the claimed method.

The proposed spiral cassette, like its counterpart, includes a substrate, between the turns of which at least one flattened vessel is placed, intended for growing a seedling from a seed. The vessel is made of a porous material decomposing in the soil.

New to the claimed spiral cassette is that the vessel with the seed sown is in the cell communicated with the air channel, the boundaries of which are the protrusions of the substrate.

The vessels used in the implementation of the first version of the proposed method, have the form made of, for example, paper, flattened bags without soil. Sachets used in the implementation of the second version of the method are flattened below, and their extended upper part is filled with soil. Bags used in the implementation of the third version of the proposed method have the form of flattened cups filled with soil.

The third technical problem is solved by improving the known collapsible cellular cassette. The claimed cassette is specifically designed for use in the implementation of the fourth version of the proposed method. The folding cartridge with cells of large volume is used when growing seedlings.

The cells of the claimed cassette, as well as the analogue, are interconnected by bridges, with both types of seed tanks made of a porous material decomposing in the soil.

New in the claimed cassette is the shape - the cells have the form of triangular (or square) prisms with concave edges, in which the notches are made, and the bridges between the cells are weakened by perforations.

Alternatively, the claimed collapsible cellular cassette consists of conical or pyramidal multi-faceted cups with legs and with perforations in the jumpers.

The solution to the fourth technical problem is to eliminate the drawbacks of the famous pot, collected from the scan. The proposed pot is specifically designed for use in the implementation of one of the versions of the second stage of the claimed method.

The declared pot, as well as its analogue, has the shape of a multifaceted prism, and both of them are made of a porous material decomposing in the soil.

New in the proposed pot is that it has three (or four) legs, as well as three (or four) wide faces, three (or four) narrow edges, in which the cuttings are provided.

The technical result obtained when using the claimed inventions, manifested in the following. Firstly, the cost of seedlings of agricultural and flower crops is reduced by at least 10%, which is ensured by: 1) transplanting seedlings to a large area of nutrition in the phase of cotyledon leaves (or in the phase of one true leaflet); 2) exclusion of root damage during transplantation; 3) eliminating the need for drying the soil during handling seedlings; 4) acceleration of adaptation of transplanted plants to the changed conditions; 5) reduce water consumption for watering plants growing in pots; 6) reduce energy consumption for plant lighting; 7) reduce the costs associated with heating greenhouses in the cold season; 8) mechanization of seedling transplantation. Secondly, the ripening of vegetables is accelerated by two to three weeks and, accordingly, the period of fruiting crops demanding to heat is prolonged. Thirdly, it becomes possible to two-stage cultivation of seedlings of vegetables and berries that do not tolerate the transplant. Fourth, the cost of vessels used in breeding seedlings, growing seedlings and rooting cuttings of trees, shrubs and vines decreases.

The proposed group of inventions is illustrated by drawings, where in FIG. 1 shows a spiral cassette in expanded form; in fig. 2 is a cross section of a cassette twisted into a three-dimensional helix; in fig. 3 - a bag with a flattened bottom and an expanded top filled with soil; in fig. 4 - bag in the form of a flattened cup filled with soil; in fig. 5 is a top view of a collapsible cassette with cells in the form of straight triangular prisms; in fig. 6 is a fragment of a plate having a cut-out above and below the plate — an element of the cellular cassette shown in FIG. five; in fig. 7 is a fragment made with cutouts in the lower part of the plate - the element of the cellular cassette shown in FIG. five; in fig. 8 is a fragment of cuts made in the upper part of the plate - the element of the cellular cassette shown in FIG. five; in fig. 9 is a section along A-A of FIG. 7 of the section of the cellular cassette element shown in FIG. five; in fig. 10 - collapsible cassette with tetrahedral pyramidal cells; in fig. 11 - collapsible cassette with hexagonal pyramidal cells; in fig. 12 - collapsible cassette with trihedral pyramidal cells; in fig. 13 is a scan of a prefab pot having a straight hexagonal prism shape; in fig. 14 is a view of a collecting pot, the development of which is shown in FIG. 13; in fig. 15 - scan of the collecting pot, having the form of a straight octahedral prism; in fig. 16 is a view of a collecting pot, the development of which is shown in FIG. 15.

The spiral cassette intended for growing seedlings according to the first version of the proposed method includes substrate 1, made with protrusions 2, 3, and covering film 4. Substrate 1 is made of foamed polypropylene (or polyethylene foam), and covering film 4 is polyethylene. Soon after use, the substrate 1 and the covering film 4 are decomposed into safe components. In the cells, the boundaries of which are a pair of protrusions 2, as well as the corresponding areas of the substrate 1 and covering film 4, are flattened vessels without soil. These vessels can be bags 5, made of porous organic material decomposing in the soil (for example, from waste paper). The pores of the bags 5 form a system of communicating capillaries. FIG. 1 position 6 indicates the location of the seed, sown in bag 5. The distance between the projections 2 depends on the volume of the root system of seedlings (for tomatoes and peppers it is 15-20 millimeters). The width of the substrate 1 is 80-150 millimeters, and the length is determined by the number of sown seeds. The cavities of the spiral cassette (Fig. 2), bounded by the protrusions 3, adjacent areas of the substrate 1 and the covering film 4, function as air channels 7 communicated with the capillaries of the sachets 5 through the holes 8, 9. The spiral cassette used in the implementation of other versions of the proposed method, is equipped with sachets 10, 11 of another form (Fig. 3, Fig. 4). Sachets 10 have an expanded upper part filled with nutrient soil 12 and a flattened lower part, and sachets 11 are made in the form of flattened cups with soil 12. When breeding seedlings according to the fourth version of the proposed method, a cellular folding cassette is used. The proposed container, made according to one of the possible options, consists of cells 13, having the form of straight triangular prisms with concave sides (Fig. 5). The cassette is assembled from toothed plates made with transverse narrow slots 14 located above, below, as well as above and below (Fig. 6 - Fig. 8) - the thickness of the plates does not exceed 1.0-1.5 millimeters. The teeth of the plates, located between the slits 14, form concave faces of the cells 13, in which notches 15 and holes 16 are provided, extruded to form burrs 17. The jumpers between the cells 13 of the assembled cassette are weakened by the perforations 18 portions of the plates adjacent to the slots 14. Burrs 17 located outside of the cells 13, pushing their faces with the formation of air channels 19. As a side bottom of the cassette can be used a piece of polymer film of suitable dimensions, made with holes. Perhaps another solution: the teeth of one of the plates, forming the sides of the cells 13, have folded bottoms, as well as supporting legs (not shown in the drawings). The collapsible cassette may consist of cells in the form of hollow straight quadrilateral prisms (the quadrangular cassette and the plates from which it is assembled are not shown in the drawings). The cellular cassette made in yet another variant consists of conical cups (not shown in the drawings). In addition, the cellular cassette can be made up of four, six or three-sided pyramidal cups (Fig. 10 - Fig. 12) with notches 15, perforations 18 in jumpers and support legs 20. Collected from the reamers (Fig. 13, Figs. 15) pots used for growing seedlings (or rooting cuttings) are in the form of six - or octahedral prisms (Fig. 14, Fig. 16). Sweeps are specially arranged elements of pots with notches 15 (the thickness of the sweeps does not exceed 1.0-1.5 millimeters). These elements, separated from each other by perforations, are the bottom 21, three (or four) wide 22 side faces, three (or four) narrow 23 side faces and lining 24. When assembling the pots, three or four legs 20 are formed (Fig. 14, Fig. 16), the elements forming them are adjacent to the bottom of the 21 sections of the lining 24, 22 wide and 23 narrow 23 side faces. The necessary rigidity of the pots is ensured by knife locks consisting of arrow-shaped petals 25 and slots 26. Alternatively, the rigidity of the pots is achieved by gluing (the places where glue is applied in Fig. 15 are indicated by 27). It is also advisable to use locking systems, the fastening elements of which do not protrude beyond the lateral edges of the assembled pots. Such pots on the shelves of greenhouses (or on window sills) can be arranged in rows close to each other. With their wide side edges 22 they touch adjacent tanks, and between the narrow 23 side edges six or quadrilateral air channels are formed.

Sachets 5, 10, 11, cassettes and prefabricated pots are made of non-harmful porous organic material that decomposes in the soil.

The initial stage of the first version of the proposed method of growing seedlings is as follows. Between the protrusions 2 of the substrate 1 of the spiral cassette unfolded on the table, the bags 5 with seeds sown are laid out, then the bags 5 are moistened. A covering film 4 is placed on the protrusions 2, then the substrate 1 is rolled into a roll, which is placed in a vessel with an aqueous solution of nutrients - the bottom of the bags 5 should be in water. In the spiral cassette, the roots of seedlings are separated from each other, they are not intertwined with each other, food and water are delivered to them through the capillaries of sachets 5. Oxygen from air channels 7 to the roots of plants enters through holes 8, 9 and through the capillaries of sachets 5, carbon dioxide moves into the opposite direction.

The second version of the claimed method is that the seeds are sown in the nutrient soil 12, which is located in the upper part of the bags 10 (Fig. 3). The sachets 10 are placed between the projections 2 of the substrate 1, a covering film 4 is applied to them, and all of this is rolled into a roll (FIG. 2), the bottom of which is buried in an aqueous solution of nutrients. In this case, the seedlings are first fed from the soil 12, and when the roots of the plants sprout into the flattened part of the bags 10, capillaries are used.

Carrying out the third version of the proposed method, seedlings are grown in nutrient soil 12, which is filled with bags 11 (Fig. 4). Plants are watered from above, they receive everything they need from soil 12, and the root gas exchange occurs through the air channels 7 and the pores of the sachets 11.

According to the fourth version of the claimed method, the seedlings are grown in the nutrient soil, located in the prismatic cells 13 of the collapsible cassette (Fig. 5). The soil, compacted by watering the plants, engages with facing inward burrs 17, which eliminates the destruction of the cells 13, when they break out of the cassette. Vegetable seeds in the soil are buried to the depth recommended by the relevant instructions, and seeds of certain types of flowers are sown on top of the nutrient soil. Plants are watered from above. Root gas exchange seedlings provide through the air channels 19 and communicated with them then the shells of the cells 13, the gaps between their ribs, as well as the gaps 15.

Alternatively, the fourth version of the proposed method, the seeds are sown in nutrient soil, located in the conical cups collapsible cassette. In yet another embodiment of the method, a collapsible cassette with cups having the appearance of four, six, or triangular truncated pyramids with legs is used (Fig. 10 to Fig. 12).

The declared cellular cassettes can be used for breeding plants in a two-step process that do not tolerate transplantation.

The first stage of the proposed method ends at the phase of cotyledon leaves (or after the appearance of one true leaflet). At the end of the initial stages of the first three versions of the claimed method, the spiral cassette is unrolled. Without touching the stalks and leaves of seedlings, sachets 5 are removed from the cells of the substrate 1, and they are rolled over to a large area of nutrition. Bags 5 reliably protect the roots of plants from damage. If the initial stage of the fourth version of the method is completed, the cassette is disassembled - the cells (or cups) with the seedlings are broken out, breaking the perforation 18 in the jumpers. Drying the soil is not required, the plants are not affected, their further development does not slow down. Seedlings are grown in large-volume cells (or cups) of a collapsible cassette with legs, or alternatively in combined six-or octahedral pots with legs. Through the shell of the bags, as well as through the thin walls of the cells (or cups), and their cutting through 15, the roots of the transplanted plants germinate without loss of time. Root gas exchange seedlings provide air channels, the boundaries of which are the porous walls of cells (or cups) cassettes or narrow faces of pots. The total area of the air-washed outer surface of prefabricated pots, which are installed close to each other, is insignificant. The amount of evaporated water is minimized, the seedlings are watered rarely, contact of the bottom of multifaceted cups and pots with stagnant water is excluded. Compared with the usual terms, the length of the seedling period for the cultivation of vegetables is reduced by 10-15 days. Upon completion of the second stage of growing the seedlings, the plants, along with the cells (or cups) of the cassettes (or with the pots), are rolled into the ground. Since the envelopes of the vessels used are of a negligible thickness and are made with notches 15, the plants transplanted into the ground take root in a short time, the energy costs are minimized.

Triangular cellular cassettes of appropriate sizes, as well as high multifaceted pots with legs are applicable when breeding saplings of trees, shrubs and vines. The claimed inventions allow to solve a number of long-standing problems of crop production, therefore, they are expected to have a special commercial success. The proposed method of breeding seedlings will find wide application. The method will interest private gardeners and gardeners, breeders, small, medium and large enterprises. Unusually early transplanting of seedlings without damaging the roots (and without drying the soil) will attract the attention of all those who grow vegetables, berries and flowers in open or closed ground. This technique will provide a significant reduction in the seedling period of cultivation of plants, simplified care of the seedlings. The development of productive organs is intensified. Vegetables ripen faster, soil consumption for seedlings will decrease, available areas will be more efficiently used. Seedlings will not be damaged during transportation, it will be possible to mechanize their transplant. The use of cups of collapsible cassettes with legs, as well as assorted pots with legs, will reduce the complexity of growing seedlings. The need to use seed protection against stagnant water will be eliminated. A number of environmental problems will be resolved. It will be possible to breed in two stages of seedlings of vegetables that do not tolerate transplantation, which will significantly expand their zoning zones.

The profitability of enterprises cultivating vegetables, berries, flowers, as well as planting trees, shrubs and vines, will increase through the use of cheap seedling tanks. The cost of these vessels will decrease due to a significant reduction in waste paper (or peat and binders). The cost of manufacturing the proposed containers will also decrease because it will be possible to stream them. The plant making rolled foam polypropylene (or polyethylene foam) will be able to produce curly substrates of spiral cassettes. Collapsible cellular cassettes and reamers of prefabricated pots are best made on rolling mills. Cartridges with square cells to customers will be delivered in the folded form, cassettes with conical and pyramidal cups - stacked, and prefabricated pots - in the form of packages of reamers. Breeders, individual gardeners and gardeners will be able to collect pots by hand, and agricultural enterprises - through the machines. The proposed vessels can be unified, and this will allow to standardize the mechanization of the cultivation of seedlings and transfer of seedlings into the ground.

The claimed group of inventions can be used in enterprises that grow vegetables in an outdated hydroponic way. Their products are supplanted by vegetables cultivated by Ultra clima technology in fifth generation greenhouses [10]. The proposed method and device will allow ruined greenhouses to grow environmentally friendly unpaved vegetables, the demand for which is steadily increasing.

Citation List

1. https://www.gazeta.ru/comments/column/miroriova/10722281.shtml.

2. http://www.7dach.ru/Exspert/tara-dlya-rassady-4211.html.

3. "If there is not enough space." Zamry N.N. Journal “My Beautiful Dacha”, Moscow, №23, 2016, p. 48.

4. https://www.youtube.com/watch?v=QuRE_X_BlVI.

5. https://www.youtube.com/watch?v=xOecHf8R4K4.

6. http://www.asienda.ru/post/24331/.

7. http://parnikiteplicy.ru/rasteniya/gollandskaya-texnologiya-vyrashhivaniya-tomatov.html.

8. RF patent 2048059 C1, cl. A01G 9/02, 9/10, 07.23.1992.

9. Packaging. All about packaging. Sokolnikov. Y. Publishing house "Tigra", Moscow, 2001.

Claims (10)

1. A method of breeding seedlings, including growing seedlings in vessels of a collapsible cassette made of a material decomposing in the ground, as well as transplanting them to a large area of food along with vessels, characterized in that the seedlings grow in flattened sachets placed in cells of the spiral cassette flattened lower and widened upper part, which is filled with soil, or in bags filled with soil, made in the form of flattened cups, or in soil-filled cells or cups of a folding box office you with legs, made with perforations in the jumpers. 2. The method of breeding seedlings under item 1, characterized in that the seedlings are transplanted in the phase of cotyledon leaves or after the appearance of one of this leaf. 3. The method of breeding seedlings according to claim 1 or 2, characterized in that the seedlings are transplanted into cells or cups having collapsible cassette legs connected to each other with perforated jumpers or into combined six- or octahedral pots with legs. 4. A spiral cassette for use in carrying out the method of claim 1, comprising a substrate and a flattened vessel made of a porous material decomposing in the soil, characterized in that the vessel is placed in a cell in communication with the air channel between the substrate protrusions. 5. Spiral cassette according to claim 4, characterized in that the vessel is made in the form of a bag without soil or a bag with an expanded upper part filled with soil, or a bag having the appearance of a cup filled with soil. 6. A collapsible cellular cassette made of a porous material decomposing in the ground, intended for use in carrying out the method of claim 1 or 3, made with bridges between cells, characterized in that perforations are provided in the bridges. 7. A collapsible cellular cassette according to claim 6, characterized in that the cells have the shape of three- or quadrilateral prisms with concave sides. 8. The collapsible cellular cassette according to claim 6, characterized in that the cells are made in the form of three-, four-or six-sided pyramidal cups. 9. Collapsible cellular cassette according to any one of paragraphs. 6-8, characterized in that the cups are made with legs. 10. Multifaceted pot, designed for use in the implementation of the method of breeding seedlings under item 3 or rooting cuttings of trees, shrubs and vines, assembled from a reamer made of porous material decomposing in the soil, characterized in that it has three or four wide faces, three or four narrow faces, as well as three or four legs.

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