WO2023146507A2

WO2023146507A2 - Method for growing industrial hemp in a polyculture with medicinal plants and in conjunction with solar energy production

Info

Publication number: WO2023146507A2
Application number: PCT/UA2022/000059
Authority: WO
Inventors: Наталия Мыхайливна МЭЛЬНЫК; Васыль Васыльовыч КОНИЩУК; Мырослав Руслановыч МЭЛЬНЫК; Мыхайло Сэргийовыч ВОЛКОВ
Original assignee: Наталия Мыхайливна МЭЛЬНЫК
Priority date: 2022-01-31
Filing date: 2022-10-17
Publication date: 2023-08-03
Also published as: WO2023146507A4; WO2023146507A3

Abstract

The invention relates to the field of agriculture, and more particularly to crop cultivation techniques, and can be used for cultivating hemp and medicinal plants using solar energy. Claimed is a method for cultivating industrial hemp in a polyculture with medicinal plants in conjunction with solar energy production, according to which industrial hemp and medicinal plants are sown and cultivated in a field. The medicinal plants and industrial hemp plants are cultivated alongside one another throughout the entire field in alternating sections, wherein solar absorption modules of at least one electric power plant are installed above the surface of the ground in such a way as to allow the passage of agricultural machinery. The technical result is that of making it possible through the use of the claimed method to enhance productivity, i.e. increase crop yield, and environmental friendliness, and to reduce cultivation costs and the cost of the products obtained, namely industrial hemp and medicinal plants, thus ensuring wide-scale use of the claimed method and the creation, in different regions, of a large number of fields with improved protection and productivity, offering a broader range of products, such as industrial hemp and assorted medicinal plants, supplying raw material for many sectors of industry, producing electrical energy and satisfying the energy demands of cultivation in terms of watering systems and other products, and creating favourable conditions for cultivating plants in different soils and under different climatic conditions.

Description

A method of growing industrial hemp in the polyculture of medicinal plants in combination with solar energy.

The invention relates to the field of agriculture, namely to technologies for growing crops, and can be used to grow hemp and medicinal plants in combination with the use of solar energy.

To date, industrial hemp is the most profitable agricultural crop. Hemp can be used to produce more than tens of thousands of various products in the field of mechanical engineering and aircraft construction, the textile industry, pharmaceuticals and in many other areas, for example, hemp can be used to produce bulletproof vests. The plant can be used completely without residue. For example, seeds allow the farmer to get up to 100% profitability, and on the leaves, on the inflorescences of technical hemp, you can increase income by 3-5 times. Seeds are most often used in the food industry, cosmetology and pet business. About 57% of hemp fibers are used in the paper and pulp industry. There are several dozen enterprises in the world that produce paper with or based on vegetable cellulose from hemp. The fact is that in a year of cultivation, hemp gives an increase in plant mass more than a 50-year-old forest. And it is actively used in the EU, and projects are starting in Canada, China and Kazakhstan. In particular, the first plant for the primary processing of hemp for further paper production is being built in the latter. At the same time, even such a processing product as hemp dust, which remains after the primary processing of the hemp stem, is also used. When asphalting roads in the EU, this dust is added in the form of granules, the road surface becomes more reliable and durable. Hemp fire is also a product of hemp processing and is actively used in animal husbandry. In France, 80 to 90% fires used as bedding for animals and as a dry closet, because it absorbs urine better up to 400% and completely kills the smell and has an antiseptic effect.

The resumption of the cultivation of technical hemp in Ukraine will allow to revive the activities of the former cotton mill in Ukraine (25 thousand jobs), where instead of cotton, hemp fibers will be used as raw materials, and the plant's products will serve as raw materials for a pipe plant and a significant number of other industries.

Cultivation of technical varieties of hemp will allow the revival of other important Ukrainian enterprises - machine-building plants, which can quickly re-profile their products for the cultivation and primary processing of hemp and the production of modern sprinkler equipment.

To eliminate the colossal losses of water resources of the Dnieper in the Kherson region for consumption and irrigation (from 2 to 5 cubic km annually), it is necessary to transform the systems of main irrigation canals into systems of main irrigation pipelines using composite pipes of large diameter (from 300 to 4000 mm). Durability, corrosion resistance and relatively low cost of pipes (3 times cheaper than metal pipes) are the characteristics that are necessary for water supply and irrigation systems.

In Ukraine, there is currently no industrial production of such an urgently needed product as composite pipes, although in most neighboring countries such enterprises operate (several) not only for the agricultural sector of the economy, but also for the production of pipes for the oil and gas and chemical industries, water disposal systems, water supply and district heating in cities (Russia, Kazakhstan, Turkey, Iran, etc.).

It is extremely important to take into account the fact that the term "composite products" today is generally perceived from the standpoint of the manufacture of goods from fiberglass, which, in turn, is associated with the chemical industry, that is, with oil and gas. One should not neglect such a historical fact that the basis for the first composite products in the world was natural fibers, such as from hemp (Ford's first car), which in terms of their technical characteristics are by no means inferior to fiberglass.

So, the construction of a powerful plant (about 500-600 km / pipes per year) for the manufacture of fiberglass (from hemp fibers) large-diameter pipes in the south of Ukraine (in Kherson there are proper industrial sites, like the territory of a former oil refinery), will allow in a fairly short time (up to 5-8 years) not only to rebuild the main canals of Kherson into main pipelines, but also to revive and increase the area of land for irrigation of hemp plants in the Kherson region.

Thus, the need for the products of such a plant only to meet domestic demand in the country is more than relevant and extremely necessary.

At the same time, today there is a great need for the cultivation and use of medicinal plants.

To date, about 500,000 plant species are known, but only a small part (approximately 10%) of them are widely used in medicine. As of the 21st century, today only 25 types of medicinal plants are grown in specialized farms in Ukraine.

Plants are a source for obtaining various medicinal substances. More than 30% of all drugs are obtained from plant materials. Plants are used to obtain alkaloids, cardiac glycosides, vitamins, etc. Most medicinal plants are used in folk medicine. The low toxicity of most medicinal plants allows them to be used in the treatment of chronic diseases, for anti-relapse or rehabilitation treatment. Therefore, in order to scale up pharmaceuticals based on medicinal plants, it is necessary to carry out mass cultivation of raw materials.

It is important that such plants as ginseng, calendula, yarrow, wild rose, plantain, sage, onion, fennel, ginger, skullcap, lily of the valley, barberry aralia, turf, garlic, chamomile officinalis, St. John's wort, coltsfoot, sea buckthorn, licorice, peppermint , common chill, hawthorn, buckthorn, mountain ash, fennel, bird cherry, viburnum, Chinese lemon, purple echinacea, valerian officinalis and many others can be grown on different soils, and it is important that in this way plowed areas can be enriched with organic residues, which in the future will ensure the yield of agricultural crops such as corn, rapeseed, sunflower, winter wheat, spring barley, cabbage and many others that deplete the soil.

At the same time, it is important to take into account that hemp also enriches the soil, and the combination of growing these crops in one field allows for an ecological increase in the yield of both hemp itself and agricultural crops that will be grown after hemp and medicinal plants in this field, reduce or completely eliminate from pests, fungi and other plant pathogens.

In order for the cultivation of cannabis and medicinal plants to be mass-produced, it is necessary to make such cultivation low-cost, economical, environmentally friendly and highly productive.

From the prior art, a method of growing hemp on non-irrigated lands of the southern Steppe is known (Ukrainian patent for invention No. 69936, IPC А01В79 / 00, published on November 27, 2004, bull. No. 9), which includes basic tillage, application of mineral fertilizers, sowing, caring for sowing and harvesting. To obtain a seed crop, mineral fertilizers are applied to the sowing with the norm N90P60, sowing is carried out in a wide row method with row spacing of 45 cm, seeding rate of 1.8 million/ha of viable seeds, and to obtain a crop of stalks, fertilizers are applied with the rate of N60P60, sowing is carried out in the usual line method with row spacing of 15 cm, seeding rate of 2.5 million/ha of viable seeds.

The disadvantages of the known method include the fact that for the enrichment of the soil fields use only mineral fertilizers that are applied to the soil. At the same time, the known method does not provide for the protection of hemp from pests throughout the field, the ability to significantly increase the yield of hemp in an ecological way, such as the simultaneous cultivation of medicinal plants together with hemp plants. Thus, the known method is inefficient, low-environmental, expensive and has a limited scope.

The closest analogue is the known method of growing hemp contained in the method of protecting hemp from colonization by hemp codling moth (Ukrainian patent for invention No. 131353, IPC А01В79/00, published on January 10, 2019, bull. No. 1), including methods of settling an entomophage into agrocenoses of an industrial culture trichograms. In autumn, after harvesting hemp, one step of continuous treatment of the surface of the fields with a 5.0% aqueous solution of the entomopathogenic drug Picilomin is carried out, while the titer of spores of the fungus Paecylomyces farinosus Brown et Smit, the active ingredient of the drug is at least 5 billion per 1 g, except in addition, 7-10 days before the start of the spring reactivation of caterpillars of the hemp codling moth, the number of viable individuals is determined by sampling caterpillars from the fields, while along the perimeter of the fields, with a ribbon 0.6-0.7 m wide, herbaceous nectariferous plants are sown early in spring plants, in four doses, with an interval of 10 days, in addition, they sow phacelia, yellow and medicinal sweet clover, buckwheat, sowing coriander in equal proportions, while at the beginning and immediately after flowering of plants, two doses of root feeding of plants are carried out with water with a solution of organic fertilizer Rostock, at the rate of 10 l/ha, in addition, at the beginning of the mass oviposition of hemp codling moth females of the first and second generations, three methods of settling on plants, with an interval of 5-6 days, of an industrial culture of Trichogramma, a parasite of codling moth eggs, are carried out, while settle the species Trichogramma dendrolimi Mats., the resettlement rate is 60; 80 and 60 thousand individuals of Trichogramma per 1 ha.

According to a known method, herbaceous nectariferous plants are sown along the perimeter of the fields, with a tape, 0.6-0.7 m wide, in early spring, in four doses, with an interval of 10 days. Sow phacelia, yellow and medicinal sweet clover, buckwheat, coriander seed in equal proportions. At the beginning and immediately after the flowering of plants, two doses of root feeding of plants are carried out with an aqueous solution of organic fertilizer Rostock, at the rate of 10 l/ha.

The disadvantages of the closest analogue include the following.

The disadvantages of the closest analogue is that it does not allow enriching the soil over the entire area of the field on which hemp plants are grown, and significantly increase the ecological yield of hemp with the exception of the use of fertilizers. At the same time, the protection of hemp from pests is complex and expensive due to the need to create a complex preparation and treat the entire field with it, which also limits its use.

In a known method, hemp plants are protected from pests by planting and growing medicinal plants only along the perimeter of the field. The known method provides for the protection of the soil to protect hemp plants from pests by treating it with an entomopathogenic preparation, increasing the yield by root feeding of plants with an aqueous solution of organic fertilizer, which requires many operations and labor costs, the use of special preparations, which makes the known method expensive, insufficiently effective to provide the possibility of cheaper cultivation of cannabis plants with increased yields while enriching the soil, repelling, destroying pests and pathogens of plants by combining medicinal plants and hemp throughout the field where hemp plants are grown, which would allow the method to be distributed with an increase in area cultivation of hemp and at the same time medicinal plants for industrial and medical needs.

The invention is based on the task of creating a new highly efficient, with increased environmental friendliness, productivity, economical and low cost method of growing industrial hemp in the polyculture of medicinal plants in the solar energy complex, which will ensure the wide distribution of the method, the formation of many fields in different regions with an increased protective function, with the expansion range of resulting products, such as industrial hemp, a variety of medicinal plants, electrical energy, and with energy self-sufficiency for irrigation systems and other products, creating favorable conditions for growing plants on different soils and in different climatic conditions.

The task is achieved by the fact that according to the method of growing industrial hemp in the polyculture of medicinal plants in combination with solar energy, according to which, after the main tillage, technical hemp is sown or planted in the field and grown, medicinal plants, according to the proposal, medicinal plants and plants of technical hemp are grown nearby throughout the field in areas that alternate, while solar absorption modules of at least one solar power plant are installed on the field with their location above the earth's surface with the possibility of passing agricultural machinery. Also, according to the proposal, medicinal plants and industrial hemp plants are grown side by side throughout the field with a crop rotation of these plants at each subsequent sowing or planting of their seedlings in areas that alternate.

Also, according to the proposal, for sowing and cultivation of medicinal plants, at least ginseng, calendula, yarrow, wild rose, plantain, sage, onion, fennel, ginger, skullcap, lily of the valley, barberry, aralia, turf, garlic, medicinal chamomile, St. John's wort, mother-stepmother, sweet sea buckthorn, peppermint, common chill, hawthorn, buckthorn, mountain ash, fennel, bird cherry, viburnum, Chinese lemon, purple echinacea, medicinal valerian.

Also, according to the proposal, the field has a width of 450-1500 m and a length of 750-2900 m.

Also, according to the proposal, technical hemp is grown alternately on one part of the field, mainly half of the field, and medicinal plants on the other.

Also, according to the proposal, medicinal plants are sown and grown in the middle part of the field, and technical hemp is sown and grown on one and the other side of this part, while the parts of the field have approximately the same width.

Also, according to the proposal, industrial hemp is sown and grown in the middle part of the field, and medicinal plants are sown and grown on one and the other side of this part, while the parts of the field have approximately the same width.

Also, according to the proposal, the field is divided into at least four parts, on which industrial hemp and medicinal plants are alternately sown and grown in a checkerboard pattern, while the parts of the field have an area close to the same. Also, according to the proposal, solar absorption modules are installed in row spacing at a height of at least 5.5 m.

Also, according to the proposal, solar panels are used as solar absorption modules.

Also, according to the proposal, solar panels and/or solar collectors are used as solar absorption modules.

Also, according to the proposal, balloons are used as modules for absorbing solar rays.

Also, according to the proposal, parabolic concave mirrors are used as solar absorption modules.

Also, according to the proposal, the solar power plant is being built as a tower plant.

Also, according to the proposal, the solar power plant is made as a plate-type one.

Also, according to the proposal, the solar power plant is designed as a parabolic one.

Also, according to the proposal, the solar power plant is being implemented as a photovoltaic one.

Also, according to the proposal, the solar power plant is performed as a solar-vacuum one.

Also, according to the proposal, the solar power plant is designed as a balloon.

Also, according to the proposal, the solar power plant is being implemented as a combined one.

The listed features of the proposed technical solution are the essential features of the claimed invention, and their combination allows to obtain the expected technical result - providing the possibility, using the claimed method, to increase productivity with an increase in yield, environmental friendliness, reduce the cost of cultivation and the cost of the products obtained, and namely industrial hemp and medicinal plants, which will ensure the wide dissemination of the claimed method, the formation of many fields in different regions with an increased protective function, productivity, with an expansion of the range of products obtained, such as industrial hemp, a variety of medicinal plants, providing many industries with raw materials, obtaining electrical energy and energy self-sufficiency, growing needs for irrigation systems and other products, creating favorable conditions for growing plants on different soils and in different climatic conditions.

This also solves the problem of finding large areas of land for solar power plants.

The causal relationship of the essential features of the proposed solution with the achieved technical result is as follows.

Using the claimed method, a gradual elimination of the need to use substances for the destruction of plant pests and pathogens is ensured, which provides, in the aggregate of signs, the cultivation of medicinal plants that cleanse the soil of fungi, parasites and other pathogens and factors of plant diseases, enriching them throughout the field along with technical plants hemp, which also leads to a decrease in the amount of fertilizers, and the creation of favorable growing conditions using solar panels, which provide automatic timely watering in the right amount using the generated electrical energy, can provide heating of water and, if necessary, soil, the formation of condensate and the preservation of the ecological microclimate .

The claimed method makes it possible to use, among other things, infertile soils with their enrichment and improvement of their composition; prevents the occurrence of pests, prevents the development of purulent processes, is an antiparasitic and antibacterial method. Usage method promotes the removal of chemical residues (pesticides, herbicides and other toxic chemicals) from the soil, ensures the development and growth of healthy plants.

Carry out the claimed method as follows.

The claimed method includes basic tillage, application, if necessary, depending on the soil of mineral or organic fertilizers.

Prior to performing the main tillage, the shape and size of the field are selected.

Perform the calculation according to the known method (https://studffle.net/preview/5283632/page.42/).

When forming crop rotation fields, it is necessary to take into account fertility, agrotechnical and dynamic properties of the soil. The yield of crops depends on these properties, as well as the timing, methods of processing fields, sowing, harvesting, types and rates of fertilizers, pesticides, the performance of tractor units, and so on.

Crop rotation fields should be approximately equal in quality. It is not possible to include soil varieties with only low fertility in one field, as they may be unsuitable or unsuitable for more demanding crops. This leads either to uneven receipt of agricultural products by years of rotation, or to disruption of crop rotation.

At the same time, it is necessary to take into account the agrotechnical features of the soil. The best solution should be considered when the field consists entirely of an agrotechnically homogeneous area. This ensures simultaneous field work on sowing, caring for crops and harvesting crops from the entire field in the best agrotechnical terms.

The dynamic properties of the soil have a certain influence on the placement of crop rotation fields. Inclusion in one field of soils with different mechanical composition creates unequal conditions for the operation of tractor units on its individual parts. If the processing is carried out on the entire field as a whole, the assembly of the unit is carried out taking into account the possibility of its operation on soils with higher resistivity, which reduces productivity in that part of the field where the soil resistivity is lower. To this end, crop rotation fields should be designed from agrotechnically homogeneous plots with slightly different soil dynamic properties. If other conditions do not allow this, it is necessary to allocate working areas within the fields so that tractor units can cultivate these lands with minimal losses separately from the rest of the field.

The dimensions of the sides and the shape of the field are set based on the requirements for performing production processes in them. The most preferred form of the field is considered to be a rectangular field with the optimal length and width, which determine the size of the working rut.

The dependence of the productivity of the use of machine-tractor units and the length of the working run is characterized by the path utilization factor (Kip), the percentage of idle runs (fx).

Lp Lp*100

Kip = - (3.10.) fx = - (3.11.)

Lp+Lx Lp+Lx where Lp is the length of the working head;

Lx - length of idle passes per one working pass.

The percentage of idle passes differs for tractors of different power and productivity, as well as for different types of mechanized work. The losses are more significant when using powerful tractors with a large working width.

The length, width and configuration of fields are differentiated taking into account the specialization of crop rotations. With a large proportion of tilled crops in them and the introduction of industrial technology, the volume work carried out in all areas. At the same time, in most special crop rotations saturated with highly intensive crops, the field sizes are relatively small, in connection with this, the shape of the field in them is closer to a square.

When designing fields in camp rotations, the length of the fields is calculated based on the convenience of organizing livestock grazing; avoid sharp corners and curved borders; trying to place them with elongated short sides to the cattle passes.

The disadvantage of fields in the form of a trapezoid is the sloping of the short side, which is why when the aggregates work across the field, residual angles are created.

The worst form of the field is considered a triangle, especially with sharp corners, created due to the irregularity of the long sides, the presence of ledges or wedges.

The length of the working run in rectangular fields is determined by measuring it on the plan. In fields of a non-rectangular configuration, the length is calculated using the formulas:

Where P is the area of the field;

In - estimated conditional field width; e, t - beveled sides of the trapezoid; h is the height of the trapezoid.

R

Hence Lo = - (3.14.)

Q,2(e+m+3h)

For triangular fields e+m+h Р

Bo = - (3.15.) Lo = - (3.16.)

3 0.33

To determine the conditional length of the working rut, the fields of a more complex configuration are divided into geometric shapes (rectangles, trapezoids, parallelograms, triangles) by lines parallel to the direction of processing.

The size of the fields for cultivating the land is chosen with a width of 450 m to 1500 m and a length of 750 m to 2900 m, covering the steppe zone.

In an embodiment, the length of the field can be 1500 - 2000 m, with such a length, the idle turns of the tractor-combine units are the smallest.

In other special embodiments, the width can be h-100 - 2000m, length L-200 - 2900m.

Crop rotations must ensure the planned output of products and the uniform use of labor and means of production for all years of rotation. Compliance with such a requirement is impossible if the fields are equal in size. But full compliance with this requirement is possible only under particularly favorable conditions, when arable tracts are large, homogeneous in natural conditions and their area is equal to the average size of the field.

Spatial conditions make it necessary to allow deviations from the average field size. The magnitude of deviations in the area of fields depends on soil fertility. It is allowed to reduce the area of the field with relatively better fertility and increase - with a lower one. To do this, the actual areas of crop rotation fields are converted into conditional, that is, reduced to one quality, and deviations from the average size are determined.

Calculation of the conditional area of the field is carried out according to the formula:

R*b

Room - - (3.17.)

100 where Rum - conditional field area, ha; P - actual field area, ha;

B - evaluation score of the field.

In difficult conditions, especially when fragmenting individual arrays, the presence of interspersed lands, a deviation from the average field area by 10-12%, and sometimes more, is allowed in order to avoid cuttings and segments in the form of small areas that are not convenient for mechanical processing.

The size of the permissible unevenness of the fields also depends on the specialization of the crop rotation, the number of fields occupied by the main crops, and its labor intensity.

When designing fields, the elements of the organization of the territory existing in nature must be preserved as far as possible, and the proposed changes must be economically justified in detail. A particularly detailed justification is required for the elimination of improved roads and track structures.

But the preservation of the existing elements of the organization of the territory is by no means always advisable, since their placement often has serious drawbacks.

Upon completion of the project activities for the placement of fields, a technological characteristic is compiled that characterizes the territorial conditions created by the project, the degree of fulfillment of individual requirements for the placement of fields.

In an embodiment, soil treatment may include the following operations:

- peeling of stubble to a depth of 5-6 cm with disk peelers;

- plowing.

Spring processing begins with the physical ripeness of the soil for the purpose of drying, leveling the top layer of soil and closing moisture.

If necessary, it is possible to use double cultivation. It is important to carry out pre-treatment in a single technological process with sowing. In the case of planting seedlings of plants on the field, pits are formed for their planting, in which, if necessary, fertilizers, mostly organic, are placed.

After the necessary tillage, seedlings of industrial hemp plants and medicinal plants selected depending on the needs and / or climatic characteristics of at least ginseng, calendula, yarrow, wild rose, plantain, sage, onion, fennel, ginger, skullcap, lily of the valley, barberry, aralia, turf, garlic, chamomile officinalis, St. etc., care of crops and plants.

Medicinal plants and industrial cannabis plants are grown side by side throughout the field in alternating plots, while solar absorption modules of at least one solar power plant are installed in the field beforehand or between rows, with their location above the earth's surface with the possibility of passing agricultural machinery.

Medicinal plants and technical hemp plants are grown side by side throughout the field with a crop rotation of these plants at each subsequent sowing or planting of their seedlings, that is, annually in alternating plots.

At the same time, in an embodiment, technical hemp is grown alternately on one part of the field, mainly half of the field, and medicinal plants on the other. Landing plan in the embodiment:

In another embodiment, medicinal plants are sown and grown in the middle part of the field, and industrial hemp is sown and grown on one and the other side of this part, while the parts of the field have approximately the same width.

Landing plan in the embodiment:

In another embodiment, industrial hemp is sown and grown in the middle part of the field, and medicinal plants are sown and grown on one and the other side of this part, while the parts of the field are approximately the same width. Landing plan in the embodiment:

In another embodiment, the field is divided into at least four parts, on which industrial hemp and medicinal plants are sown and grown alternately in a checkerboard pattern, while the parts of the field have an area close to the same.

Landing plan in execution options:

The crops are grown alternately, that is, in one year, technical hemp is grown on a part of the field, and the following year, medicinal plants are grown on this part of the field.

Harvesting takes place at a certain time. In a preferred embodiment, solar absorption modules are installed between rows at a height of at least 5.5 m so that agricultural machinery, such as a tractor (combine), can pass for tillage, harvesting.

Solar absorption modules are part of solar power plants or power plants.

In embodiments, solar panels and/or balloons and/or parabolic concave mirrors are used as solar absorption modules.

In embodiments, solar absorption modules are implemented as solar cells and/or solar collectors.

Used solar power plants can be made in the following versions:

• Tower

• Poppet and/or parabolic

• Photovoltaic

• Solar-vacuum

• Balloon

• Combined

Combined power plants may include various of the above power plants in a single complex.

Electric energy is used to heat and supply irrigation water, if necessary, to heat the soil.

Thus, in this proposal there are three important elements that are combined:

1) Cultivation of hemp, which has the greatest profit, and raw materials for the manufacture of pipes, and at least 25 thousand goods;

2) Preservation of soil from aggressive depletion of agricultural crops by sequential sowing medicinal plants to enrich the soil with organic residues remaining on arable land;

3) An ecological microclimate will be maintained under solar panels that form a shadow, which will double CO ₂ -O ₂ and reduce water evaporation, will be directed to minimal irrigation (dew) for growing crops.

With the use of the claimed method, an ecological and economic model is formed:

Solar energy to apply the profitability (and provide drip irrigation motors) to the land in a combination of industrial hemp plus medicinal plants.

Thus, the business model will have colossal cultivation and volumes of raw materials for the needs of production, which will ensure demand in Ukraine and abroad, and provide jobs, which will positively affect the tax organization and social policy in the state.

A comparative analysis of the above technical solution with the closest analogue showed that the implementation of a set of essential features that characterize the invention leads to the appearance of qualitatively new technical properties indicated above.

Since the combination of these properties has not been previously established from the existing prior art, we can conclude that the proposed technical solution meets the criterion of "inventive step".

At . At the same time, the known sources of patent and other scientific and technical information did not find a method for growing industrial hemp in the polyculture of medicinal plants in combination with solar energy with the set of essential features specified in the proposal, therefore, the proposed technical solution is considered to meet the criterion of "novelty". The proposed technical solution is industrially applicable, since it does not contain any actions, operations or activities that cannot be reproduced at the present stage of technology development.

Claims

FORMULA

1. A method of growing industrial hemp in the polyculture of medicinal plants in combination with solar energy, in which industrial hemp, medicinal plants are sown and grown on the field, characterized in that medicinal plants and industrial hemp plants are grown side by side throughout the field in areas that alternate, at the same time, solar absorption modules of at least one solar power plant are installed on the field with their location above the earth's surface with the possibility of passing agricultural machinery,

2. The method according to claim 1, characterized in that medicinal plants and industrial hemp plants are grown side by side throughout the field with a crop rotation of these plants at each subsequent sowing or planting of their seedlings in areas that alternate.

3. The method according to claim 1, characterized in that for sowing and growing medicinal plants are selected at least from a number of ginseng, calendula, yarrow, wild rose, plantain, sage, onion, fennel, ginger, skullcap, lily of the valley, barberry, aralia, sod, garlic, chamomile officinalis, St. John's wort, coltsfoot, sweet sea buckthorn, peppermint, common chill, hawthorn, buckthorn, mountain ash, fennel, bird cherry, viburnum, Chinese lemon, purple echinacea, medicinal valerian.

4. The method according to claim 1, characterized in that the field has a width of 450-1500 m and a length of 750-2900 m.

5. The method according to claim 1, characterized in that technical hemp is grown alternately on one part of the field, mainly half of the field, and medicinal plants on the other.

6. The method according to claim 1, characterized in that medicinal plants are sown and grown in the middle part of the field, and technical hemp is sown and grown on one and the other side of this part, while parts of the field have

22 close to the same width.

7. The method according to claim 1, characterized in that industrial hemp is sown and grown in the middle part of the field, and medicinal plants are sown and grown on one and the other side of this part, while the parts of the field are approximately the same width.

8. The method according to claim 1, characterized in that the field is divided into at least four parts, on which technical hemp and medicinal plants are sown and grown alternately in a checkerboard pattern, while the parts of the field have an area close to the same.

9. The method according to claim 1, characterized in that the solar absorption modules are installed in the aisles at a height of at least 5.5 m.

10. The method according to claim 1, characterized in that solar panels are used as solar absorption modules.

11. The method according to claim 1, characterized in that solar batteries and/or solar collectors are used as solar absorption modules.

12. The method according to claim 1, characterized in that balloons are used as solar absorption modules.

13. The method according to claim 1, characterized in that parabolic concave mirrors are used as solar absorption modules.

14. The method according to claim 1, characterized in that the solar power plant is performed as a tower.

15. The method according to claim 1, characterized in that the solar power plant is performed as a plate.

16. The method according to claim 1, characterized in that the solar power plant is performed as a parabolic one.

17. The method according to claim 1, characterized in that the solar power plant is performed as a photovoltaic.

18. The method according to claim 1, characterized in that the solar power plant is performed as a solar vacuum.

19. The method according to claim 1, characterized in that the solar power plant is performed as a balloon.

20. The method according to claim 1, characterized in that the solar power plant is performed as a combined one.