RU2720913C1 - Method of obtaining fertilizer based on pyro-carbon, which contains microelement iodine, and fertilizer produced by said method - Google Patents

Abstract

FIELD: agriculture.SUBSTANCE: method of producing pyro-carbon based fertilizer involves taking 10 mg of potassium iodide, dissolving in 100 ml of distilled water, taking silica sol with weight concentration of silicon dioxide of 39–41 % and micelle size of not more than 6 nm, mixing with water at ratio of 1 part silica sol to 3 parts of water, mixing 100 ml of potassium iodide solution and 400 ml of silica sol solution, takes 1 kg of pyro-carbon and adds 500 ml of obtained aqueous solution of potassium iodide and silica sol, then pyro-carbon is granulated, then granules of pyro-carbon are held at 35 °C for 4 hours. Fertilizer based on pyro-carbon with silica sol, micelle size of which does not exceed 6 nm, which contains microelement iodine in concentration of 7.5 mcg/g with respect to pyro-carbon.EFFECT: invention increases content of microelement of iodine in soil and plants, as well as improves quality of grain.2 cl, 4 dwg, 6 ex

Description

The claimed technical solution relates to fertilizers, namely, fertilizers based on pyrochlide containing the microelement iodine and the method for its preparation. Designed to expand the range of fertilizers to increase the iodine content in soils and plants, to improve grain quality by enhancing the prolonged action of fertilizers based on pyrocarbon containing an iodine trace element.

Metabolism in the body is provided by hormones, among which an essential role is played by thyroid secretion products - iodine-containing thyroid hormones - thyroxine and triiodothyronine [Severin E. S. Biochemistry: Textbook. for universities // M .: GEOTAR-Media. - 2003]. With a lack of iodine in the body in animals and humans, a whole class of iodine deficiency diseases can develop. One of the most common is hypothyroidism, accompanied by a slowdown in metabolic processes, a decrease in basal metabolism, body temperature, etc. In addition, with the inability of the gland to secrete a sufficient amount of thyroid hormones, a chronic disease can develop - non-malignant hypertrophy of the thyroid gland [Stroev EA, et al. Pathobiochemistry. - M: GOU VUNMTS, 2002], which reduces the quality of life, in particular, causing a decrease in cognitive functions of a person of various degrees of severity [Fuge R. Soils and iodine deficiency // Essentials of Medical Geology. - Springer, Dordrecht, 2013. - S. 417-432]. Against the background of iodine deficiency, endocrine malignancies can also develop [Feldt-Rasmussen U. Iodine and cancer // Thyroid. - 2001. - T. 11. - No. 5. - S. 483-486]. This class of diseases can lead to complete or partial disability even in case of successful therapy [Edis A. J. Surgical treatment for thyroid cancer // The Surgical clinics of North America. - 1977. - T. 57. - No. 3. - P. 533-542], in addition, postoperative mortality in cases of thyroidectomy remains a significant surgical problem [Bergamaschi R. et al. Morbidity of thyroid surgery // The American journal of surgery. - 1998. - T. 176. - No. 1. - S. 71-75.].

In general, according to current research [Delange F. The role of iodine in brain development // Proceedings of the nutrition society. - 2000. - T. 59. - No. 1. - S. 75-79], in 118 countries of the world more than one and a half billion people are at risk of iodine deficiency diseases. According to statistics from the Global Iodine Deficiency Network (Iodine Global Network), in 2017, 19 countries were classified as countries with insufficient iodine consumption among the population. Russia takes third place in this list, as does not have territories free from iodine deficiency [from the message of the RF Ministry of Health]. It follows that the prevention of iodine deficiency is of high socio-economic importance.

Note that in addition to the problems of preventing iodine deficiency among the population, there are similar problems in animal husbandry, since a lack of iodine in the diet leads to inhibition of cattle growth and the formation of barrenness, and an increased risk of a number of diseases [Orlov D. S. Microelements in soils and living organisms // Soros educational journal. - 1998. - No. 1. - S. 61-68 .; Fofanova I. Yu. Role of vitamins and microelements in maintaining reproductive health // Gynecology. - 2005. - T. 7. - No. 4. - S. 244-249].

Currently, this problem exists due to the deficiency of trace elements in soils of the middle zone of the Russian Federation, in particular, iodine, which, accordingly, leads to the problem of insufficient consumption of iodine by humans.

The main sources of iodine in food are iodized salt, seaweed, sea fish and seafood, dairy products and eggs, however, it is also considered advisable to introduce bread and cereal products with a high iodine content into the diet, including for economic reasons [Protasova N. A Microelements: biological role, distribution in soils, influence on the spread of human and animal diseases // Soros Educational Journal. - 1998. - T. 4. - No. 12. - S. 32-37].

Lack or excess of iodine in the soil leads to a decrease in plant productivity, deterioration in the quality of agricultural products. The intake of iodine in living organisms is carried out through the food trophic factor (by the origin of the abiotic and biotic, by the degree of influence - limiting) in the trophic chain of soil - plants - animals - people. The intake of iodine in plants and its content in crop products, in turn, depend on the content of this element in the soil, on the biological characteristics of plants, on the properties of the fertilizers used [Hong C. L. et al. Transfer of iodine from soil to vegetables by applying exogenous iodine // Agronomy for sustainable development. - 2008. - T. 28. - No. 4. - S. 575-583].

It follows that the most effective way to increase the iodine content in food products is to increase the iodine content in cereals and green crops (the former are characterized by high consumption in the population, the latter are characterized by a short growing season and a high level of iodine accumulation in plant tissues [Smoleń S., Kowalska I ., Sady W. Assessment of biofortification with iodine and selenium of lettuce cultivated in the NFT hydroponic system // Scientia Horticulturae. - 2014. - T. 166. - P. 9-16]) by increasing its content in the soil by biofortification methods [ Zimmermann MB, Jooste PL, Pandav CS Iodine-deficiency disorders // The Lancet. - 2008. - T. 372. - No. 9645. - S. 1251-1262], because natural concentrations of trace elements in intensive farming in violation of ecosystem stability can not provide proper consumer requirements for product indicators [Kabata-Pendias A. Soil – plant transfer of trace elements — an environmental issue // Geoderma. - 2004. - T. 122. - No. 2-4. - S. 143-149]. Along with an increase in the iodine content in the vegetative and generative parts of the plant, its use as a fertilizer component can improve the quality of crop production [Safronovskaya G. M. The effect of iodine, manganese and zinc on the yield and quality of crops with different acidity of sod-podzolic loamy the soil. - 2002; Kostin V. et al. Effect of iodine on the amino acid content and biological value of feed in pure and mixed crops of forage crops // Bulletin of the Orenburg State Agrarian University. - 2014. - No. 2] and increase the yield of grain crops [Sindireva A.V., Kekina E.G., Stepanova OV. Environmental assessment of the influence of iodine-containing fertilizers on the yield of spring soft wheat in the conditions of the southern forest-steppe of the Omsk Region // Bulletin of the Buryat State Agricultural Academy named after BP Filippova. - 2016. - No. 1. - S. 41-46].

According to the source [MV Katalymov. Microelements and micronutrients. - Ripol Classic, 2013], the iodine content in the soils of the middle zone of the Russian Federation varies in the range of 0.3 - 6.0 mg / kg, with an average value of 2.5 mg / kg, when in the zone of distribution of chernozem soils the range is already 2.0 - 9.8 mg / kg with an average value 5.3 mg / kg, however, not all of this iodine is available to plants, and during the mineralization of organic matter it intensively migrates from the biogenic accumulation region to the underlying profiles [Protasova N. A., Kopaeva M. T. Rare and scattered elements in soils of the Central Russian Upland / / Soil science. - 1985. - No. 1. - S. 29-37]. Iodine can occur in nature in various forms [I ^- , I ₃ ^- , IO ₃ ^- , H ₄ IO ₆ ^- , of which the first two are most common (Kabata-Pendias A., Mukherjee AB Trace elements from soil to human. - Springer Science & Business Media, 2007]), but iodide I ^- , the accumulation of which is many times greater than the accumulation of, for example, iodate [Muramatsu Y., Christoffers D., Ohmomo Y. Influence of chemical forms on iodine uptake, is considered the most appropriate form for artificial application. by plant // Journal of radiation research. - 1983. - T. 24. - No. 4. - S. 326-338].

The natural routes of iodine entry into the soil are of a different nature:

- ascending character: occur during soil formation on certain mother rocks, where iodine is concentrated in the humus layer;

- descending character: with sediments in the floodplain and estuary and from atmospheric air in the form of gaseous compounds or aerosol particles.

The descending path is considered the most important source of supply for plants [Kabata-Pendias A. Trace elements in soils and plants. - CRC press, 2000]. It is it that is inherent in territories close to the coastline of inland seas and not affecting the distribution of iodine in the soils of agricultural land in most of the Russian Federation.

The above ascending nature of migration, followed by the accumulation of iodine in the biogenic horizon (humus layer), is accompanied by the inclusion of iodine in the composition of organic substances, including inside living organisms or detrital mass: iodine accumulation in the upper parts of the profile is predominantly biological. There is a dependence on the degree of humus content, the mechanical and mineralogical composition of soils (an increase in the organic matter of organic matter and the proportion of minerals with a developed surface, such as clay minerals of the smectite group, an increase in the dispersion of particles will ensure the effectiveness of the geochemical barrier), but such accumulation is not accompanied by an increase in the availability of iodine forms for plants [Gerzabek MH et al. Iodine and bromine contents of some Austrian soils and relations to soil characteristics // Journal of plant nutrition and soil science. - 1999. - T. 162. - No. 4. - S. 415-419], capable of absorbing readily soluble iodine compounds. This implies the need for artificial introduction of iodine compounds in a form readily accessible to cultivated plants (usually potassium iodide).

However, getting into the biogenic horizons of the soil profile as part of complex fertilizers, the iodine anion can be in the form of organic complexes bound and inaccessible to plants, or it may migrate into the gas phase during microbiologically induced transition to methyl iodide [Amachi S. et al. Microbial participation in iodine volatilization from soils // Environmental science & technology. - 2003. - T. 37. - No. 17. - S. 3885-3890] and oxidation to I2 by the soil medium [Fuge R. The role of volatility in the distribution of iodine in the secondary environment // Applied Geochemistry. - 1990. - T. 5. - No. 3. - P. 357-360], and lower in profile under the influence of precipitation: the presence of iodine in soils in mineral forms has not been established due to the high mobility of compounds that are not able to fix in the soil profile (washed out by water) [Kashin V. K ., Tikhomirov F.A. Biogeochemistry, phytophysiology and agrochemistry of iodine. - science, 1987]. In acidic soils, which are widespread in the middle zone of the Russian Federation, the mobility of iodine increases, and accordingly, its more intensive washing out occurs; this mobility does not allow creating sufficient iodine content in the soil profile to provide nutrition for cultivated plants in all phases of vegetation [Kabata-Pendias A. Trace elements in soils and plants. - CRC press, 2000].

Thus, when cultivating crops on the territory of the Russian Federation, there remains the problem of providing the arable layer of soils, and subsequently, plants, with sufficient iodine content, taking into account the soil and climatic conditions, while minimizing evaporation losses, leaching into the underlying horizons, and maintaining the mobility of iodine compounds at all stages of plant vegetation, since instantaneous high doses are not absorbed by plants or have a toxic effect [Lawson PG et al. Soil versus foliar iodine fertilization as a biofortification strategy for field-grown vegetables // Frontiers in plant science. - 2015. - T. 6. - P. 450], which should be excluded as reducing the activity of soil microbiota and worsening plant productivity [Mackowiak CL, Grossl PR, Cook KL Iodine toxicity in a plant-solution system with and without humic acid / / Plant and soil. - 2005. - T. 269. - No. 1-2. - S. 141-150]. In this case, the susceptibility of plants to iodine and the range of toxic effects for different cultures are not well understood [Shitou X. et al. Effects of Iodine Application on Growth and Content of Iodine, Amino Acid, Vitamin C and Fiber in Radish Sprouts // Acta Horticulturae Sinica. - 2003. - T. 30. - No. 2. - S. 218-220]. The solution of this problem within the framework of choosing the preferred biofortification strategy can increase the iodine content in plants used by humans and animals, while increasing the yield and quality of the products.

The most common form of iodine in agricultural practice in the composition of potassium iodide is used mainly as a component of complex mineral fertilizers [Potatueva Yu.A., Prokofieva R.I. Increase in iodine content in plants of nutritional value // Microelements in medicine. - 2005. - T. 6. - No. 4. - P. 40-42], which does not provide a sufficient iodine content in the arable horizon, due to intensive washing out due to high mobility, or foliar top dressing introduced by the sprayer [Starovoitov V. I., Starovoitova O. A., Manokhina A. A. Influence of the combination of high-precision application of mineral fertilizers and growth regulators on the yield and quality of potato tubers // Bulletin of the Federal State Educational Institution of Higher Professional Education "Moscow State Agroengineering University rsitet them. VP Goryachkin. " - 2014. - No. 2], the effectiveness of which is very low, since iodine intake in soluble form mainly occurs through the root system [Golubkina N. A., Kekina E. G., Nadezhkin S. M. Prospects for enriching agricultural plants with iodine and selenium (review) // Trace elements in medicine. - 2015. - T. 16. - No. 3. - S. 12-19]. Accordingly, it becomes necessary to select the most optimal iodine microelement carrier, which reduces to the fact that the carrier must possess a combination of the following consumer properties:

- not show chemical activity in relation to the soil matrix and soil solution;

- have a developed porous surface;

- have surface characteristics favorable for manufacturing processes;

- have high consumer and technological qualities (long shelf life, flowability, low caking, lack of strict requirements for storage conditions, manufacturability of fertilizer application, etc.);

- provide a sustained release of potassium iodide to the soil.

The applicant has considered known from the prior art media options, including the most common:

diatomite [Weng H. X. et al. Increment of iodine content in vegetable plants by applying iodized fertilizer and the residual characteristics of iodine in soil // Biological trace element research. - 2008. - T. 123. - No. 1-3. - S. 218-228, Weng H. X. et al. Iodine biofortification of vegetable plants — An innovative method for iodine supplementation // Chinese Science Bulletin. - 2013. - T. 58. - No. 17. - S. 2066-2072],

zeolite [Reha M. et al. Ac and dc conductivity study of natural zeolitic material of the clinoptilolite type and its iodine forms // Solid State Ionics. - 1993. - T. 66. - No. 1-2. - S. 189-194].

However, their use has several disadvantages:

- not described prolonged intake of iodine in the soil,

- the method of their manufacture is not technologically advanced or is accompanied by significant economic costs - zeolite and diatomite are minerals that do not require special manufacture, however, it is necessary to ensure extraction, enrichment of the original rock and product purification, delivery to the place of manufacture of fertilizer,

- such undesirable effects are noted with regular application to the soil, such as a change in the physical properties of the soil and the dynamics of nutrient compounds during sorption of cations.

Based on the foregoing requirements, the applicant, as a result of the analysis of the prior art, the applicant chose pyrocoal, which is a product of pyrolysis of poultry waste, the production of which can be organized in close proximity to agricultural land. Pyrocarbon provides environmental benefits (carbon sequestration while disposing of waste [Spokas KA et al. Biochar: a synthesis of its agronomic impact beyond carbon sequestration // Journal of environmental quality. - 2012. - T. 41. - No. 4. - S. 973-989]. At the same time, pyrocarbon has all the properties shown to the carrier for the claimed technical solution, because it is able to favorably affect the soil (provides improved physical and mechanical properties, aeration, due to the alkalizing effect, increases the pH in soils with an acidic reaction of the medium, is the source additional carbon for microorganisms and mobile cations for plants, [Chan KY et al. Agronomic values of greenwaste biochar as a soil amendment // Soil Research. - 2008. - T. 45. - No. 8. - P. 629-634 ]), has no undesirable effects when applied regularly to the soil.

From the above, it becomes apparent that pyrocarbon is able to play the role of a highly effective carrier. At the same time, the properties of pyrocoal itself, which is a fertilizer of a new generation, in combination with the presence of a trace element iodine, allows one to obtain fertilizer with higher consumer qualities in comparison with analogues known at the filing date.

The claimed method for producing the claimed fertilizer based on pyrocholum with iodine provides a fertilizer that makes it possible to achieve a prolonged action and distribution of iodine compounds in the upper arable layer in a form accessible to plants when introduced into the soil. The specified properties of the claimed fertilizer obtained by the claimed method, allow to put into practice the claimed technical results, namely:

- increasing the trace element iodine in the soil and in plants when applying the declared fertilizer obtained by the claimed method;

- improving the quality of grain when making the claimed fertilizer obtained by the claimed method.

Moreover, according to the applicant, the prolonged nature of the action and distribution of iodine compounds in the upper arable layer in a form accessible to plants helps to improve the quality of crops due to the effective microelement nutrition of plants, leading to the intensification of biochemical processes in plants, improving their growth, development and formation large volume of the generative part (grain) [Rengel Z., Batten GD, Crowley DE Agronomic approaches for improving the micronutrient density in edible portions of field crops // Field crops research. - 1999. - T. 60. - No. 1-2. - S. 27-40].

Further in the text, the applicant provides the terms that are necessary to facilitate an unambiguous understanding of the essence of the claimed materials and to eliminate contradictions and / or disputed interpretations when performing substantive examination.

Pyrocarbon is a carbon-rich product obtained from biomass (wood, litter, plant residues, etc.) by pyrolysis (thermal decomposition of organic materials in the absence of oxygen); classified according to the initial biomass and pyrolysis parameters (temperature, duration, pyrolysis mode); used as a fertilizer, carbon source, sorbent for heavy metals, etc. [Biochar for Environmental Management: Science and Technology / J. Lehmann and S. Joseph - Earthscan - 2009.]

The applicant explains that in the context of the present description to refer to pyrochol also uses the term synonym biochar , used in a number of patents-analogues.

Biofortification - a set of measures to improve the nutritional qualities of cultivated plants by selection methods using a number of biotechnologies [https://ru.wikipedia.org/wiki/Biofortification].

Grain quality - under this term the applicant in the context of this description refers to the conformity of grain quality indicators with the requirements of GOST, for example, GOST 9353-2016 Wheat. Specifications and GOST R 53900-2010. Feed barley. Technical conditions

The removal of potassium iodide - under the specified term in the context of the present description, the applicant means the process of transferring from the fertilizer to the soil trace elements of iodine.

Further, the applicant provides information of the level of technology identified by the applicant from scientific and patent information.

From the investigated prior art, the applicant has identified sources that describe various approaches to biofortification, including in developing countries and identified attempts to increase the microelement nutrition of plants.

From the studied prior art, the invention was discovered according to the application for the invention WO2016040564 "Micronutrient fertilizer" ("Micronutrient fertilizer"). The essence is a liquid microfertilizer composition comprising an aqueous dispersion of soluble and insoluble trace elements, where trace elements can be immediate release, delayed release or mixtures thereof, a polyelectrolyte and a metal complexing agent. The composition according to claim 1, in which the soluble trace element can be any form of trace element that is soluble in water or aqueous systems and is present in a concentration of about 0.5-25 wt.%. The composition according to claim 1, in which the insoluble trace element can be any form of trace element that is insoluble in water or aqueous systems and is present in the concentration range from about 1 to 80 wt.%. The composition of claim 1, wherein the soluble microelement comprises boric acid, borax, boron trichloride, boron trifloride, boron tribromide, boron triiodide, boron trioxide, sodium borohydride, disodium octaborate tetrahydrate, orthoboric acid, potassium tetraborate, calcium borate, magnesium chloride magnesium. fluoride, magnesium bromide, magnesium iodide, magnesium nitrate, magnesium sulfate, magnesium sulfite, magnesium acetate, magnesium citrate, magnesium chromate, magnesium bicarbonate, magnesium perchlorate, aluminum nitrate, aluminum chloride, aluminum fluoride, aluminum bromide, aluminum iodide, aluminum sulfate, aluminum hydroxide, aluminum molybdate, potassium aluminum sulfate, sodium silicate, silicic acid, sulfuric acid, sodium sulfide, calcium carbonate, calcium chloride, calcium sulfate, calcium nitrate, lime, calcium ammonium citrate, calcium citrate, chromium (III) chloride , chromium (III) bromide, chromium (III) iodide, chromium (III) nitrate, hydrated chromium (III) sulfate, chromic acid, potassium chromate, potassium dichromate, manganese nitrate, manganese chloride, manganese bromide, manganese iodide, manganese sulfate, manganese oxysulfate, manganese acetate, manganese citrate, manganese acid, potassium permanganate, sodium manganate, silver nitrate, silver, silver fluoride, iron (II) chloride, iron (II) bromide, iron (II) sulfate, iron (II) acetate, zither t of iron (II), iron (II) gluconate, iron (II) lactate, iron (III) nitrate, iron (III) chloride, iron (III) oxychloride, potassium ferrite, potassium ferricyanide, potassium ferrioxalate, potassium chloride, potassium iodide potassium bromide, potassium nitrate, potassium bicarbonate, potassium chromate, potassium dichromate, potassium phosphate, potassium hydroxide, potassium sulfate and mixtures thereof. The composition according to claim 1, in which the insoluble trace element includes elemental boron, boron nitride, boron carbide, elemental magnesium, magnesium carbonate, dolomite, hydrated dolomite, magnesium hydroxide, magnesium oxide, magnesium oxalate, struvite, elemental aluminum, aluminum dodecaboride, aluminum oxide , aluminum hydroxide, bauxite, elemental silicon, silicon dioxide, elemental sulfur, calcium sulfate, gypsum, calcium carbonate, calcium phosphate, calcite limestone, eggshell, bone meal, calcium apatite, elemental chromium, chromium phosphate, chromium oxide (III), elemental manganese, rhodochrosite, manganese (II) oxide, elemental iron, iron oxide (II), iron oxide (III), iron hydroxide, iron sucrat, elemental cobalt, cobalt (II) oxide, cobalt (III) oxide, cobalt oxide ( II, III) oxide, cobalt (II) hydroxide, cobalt (III) hydroxide, cobalt (II) sulfide, cobalt (II) selenide, cobalt (II) phosphide, cobalt (II) cyanide, elemental nickel, nickel (II) oxide nickel (III) ) nickel oxide-hydroxide, nickel (II) carbonate, nickel (II) chromate, nickel (II) hydroxide, millerite, nickel (II) selenide, nickel titanate, nickel phosphide, elemental copper, copper (I) cyanide, copper chromite, copper (I) oxide, chalcocyte, copper (I) selenide, copper (I) phosphide, copper (II) oxide, copper (II) carbonate, copper (II) phosphate, covellite, copper (II) selenide, copper (II) arsenate ), elemental silver, silver chloride, silver bromide, silver iodide, silver oxide, elementary zinc, zinc cyanide, zinc chromate, zinc molybdate, zinc oxide, zinc hydroxide, zinc nitride, zinc blende, wurtzite, zinc selenide, zinc telluride, pyrophosphate zinc, zinc phosphide zinc phosphate, tin (II) oxide, tin (II) hydroxide, tin (II) sulfide, tin (II) selenide, tin (IV) oxide, tin (IV) sulfide, and mixtures and alloys thereof.

Thus, in the known technical solution, similar to the claimed technical solution, a carrier is used, and the carrier has a polymer nature, which ensures the nature of immediate release due to the presence of soluble forms of trace elements in the composition and the slow release of trace elements due to the presence of insoluble forms of trace elements in the composition held polymer matrix. The known composition is an aqueous dispersion of trace elements that can be applied once during the growing season to immediately correct any deficiencies of micronutrients in the soil. In addition, in a known fertilizer, similar to the claimed technical solution, there is potassium iodide.

Moreover, the claimed technical solution expands the range of fertilizers with microelements and prolonged action due to the claimed method, which produces the claimed fertilizer containing pyrocarbon as a carrier and microelement iodine.

A disadvantage of the known technical solution is that it does not provide evidence of improving the quality of grain, in contrast to the claimed technical solution, which describes the achievement of the specified technical result.

Also, additional steps in the known method (compared with the claimed technical solution), such as the need to equalize the pH to a range of 6-10, can lead to the formation of soluble salts in the liquid phase of the suspension, which have an undesirable effect on soils with low fertility and are in conditions of weakened ecological equilibrium (for example, soil buffering is impaired). In addition, elevated pH values are undesirable for use on carbonate soils, for example, southern chernozems, whose need for trace elements, with all their fertility, also exists. Also, the known technical solution does not describe how the polyelectrolyte complex used as a carrier will be effective for the distribution of trace elements in the upper layers of soils with low fertility.

In addition, the well-known technical solution does not describe the consequences of regular fertilizer application (for example, several seasons in a row). In this case, the accumulation of complexing agents is possible, which are potentially harmful to soils in elevated doses, since they can form complexes with heavy metal ions, for example, complexing agents such as EDTA contained in the known composition. These complexes are subsequently potentially transferred to plant tissues with subsequent inhibition of their growth and development and a change in the quality of agricultural products. It is also not described how fully and over what period the process of degradation of polyelectrolyte complexes occurs with regular application to the soil.

From the studied prior art, the applicant has identified a number of inventions where pyrochol or activated carbon is used in water treatment and water purification systems, while potassium iodide is added to it for antiseptic purposes. The applicant identified the most similar technical invention invention “Activated carbon associated with alkaline or alkali iodide” (Activated carbon associated with alkali or alkaline iodide) according to the patent US20120263801A1, the essence of which is the use of activated carbon, in a structure similar to pyrocarbon, as an sorbent for water treatment and, at the same time, as a carrier for potassium iodide, which affects the quality of water. The essence of the known technical solution is a method of filtering contaminants from a fluid stream, including: using a filter material containing both potassium iodide and carbon with the possibility of regeneration; passing a stream of contaminated liquid through the filter material; adsorption of contaminants from the fluid stream on the filter material; passing electric current through the filter material with an adsorbed pollutant on it; removal of contaminants from the filter material; as well as the removal of contaminants from the filter material by the removal of contaminants in the fluid stream. The method involves the use of filter material of activated carbon and at least 0.05% by weight of iodine salt in a solid state. The iodine salt, in this case, includes potassium iodide, carefully mixed with activated carbon. Distribution, at least, occurs on some surfaces of activated carbon. In this method, an electric current is supplied at voltages from 2.0 to 15 volts, including after removing the filter material from the stream of contaminated liquid. An electric current provides dissociation of the pollutant without irreversible reduction or irreversible oxidation of the pollutant. The method is implemented by using a device for removing contaminants from a fluid stream, comprising: a) a housing containing a filter material containing carbon and potassium iodide; b) a fluid inlet to the housing; c) an outlet for fluid from the housing; d) a source of contaminated fluid available for the fluid inlet; d) a device for moving fluid through the inlet and through the outlet; e) a current source that passes current through the filter material; and g) the source of movement of the mass of liquid above the filter material after or during the passage of direct current through the filter material. The method also includes a liquid antimicrobial solution containing: at least 80% of the total weight of the carrier fluid containing water, alcohol or a mixture of water and alcohol; at least 0.001% by weight of a solution K + I ^- ; at least 0.001 wt.% CuSO ₄ ; and also a sufficient amount of acid in the solution to ensure a pH of less than 6.5.

A disadvantage of the known technical solution in relation to the method is that the details of the procedure for introducing potassium iodide into activated carbon are not described. Moreover, in a known manner, according to the applicant, it is impossible to achieve technical results achieved in the claimed technical solution, since the known technical solution is aimed at improving and purifying water quality, respectively, has no focus on solving agricultural problems, in contrast to the claimed technical solution, in which The achievement of the indicated technical results is described.

A disadvantage of the known technical solution for the composition in the case of using the known technical solution as a fertilizer containing the iodine trace element is that there is no information on how the known composition provides the distribution of the iodine trace element in the upper arable soil layer, prolonged action and improving the quality of grain . In addition, it is not possible to evaluate the removal of the trace element iodine into plants from a known technical solution in the case of an attempt to use the known technical solution as a fertilizer.

From the investigated prior art, the applicant has identified the invention “Biomass organic potash fertilizer” (patent potassium biomass based organic fertilizer) according to the patent CN105924322, the essence of which is an organic potassium fertilizer that improves soil fertility, in which the content of available nitrogen, phosphorus, and especially potassium and various trace elements improves and also improves the physical and chemical properties of the soil. Fertilizer according to the specified patent is made from the following components in weight ratios: 12-14 parts of animal waste (animal hair), 1-2 parts of flavonoid powder of bamboo leaves, 1-3 parts of potassium iodide, 9-10 parts of oilcake, 4-7 parts corn protein powder, 3-5 parts of potassium carbonate, 1-2 parts of copper sulfate, 80-90 parts of crop straw, 24-25 parts of plant ash, 3-5 parts of carnallite powder, 6-7 parts of potassium dihydrogen phosphate, 2-3 potassium chlorate, 45-50 parts of the alga Elodea canadensis, 2-3 parts of cellulase powder, 2-3 parts of pores clad protease, 23-26 tamarindus indica and corresponding amount of water. Cooking technology includes the following options:

a) pressing and drying the alga Elodea canadensis, mixing with copper sulfate and potassium iodide when heated to 74-76 ° C, stirring for 20 minutes, drying and obtaining a powder for further use;

b) drying the alga Elodea canadensis and pyrolysis at 450 ° C for 90-120 minutes. The finished pyrochol is crushed and sieved, separating the fraction in the range of 0.15-0.25 mm, for further use;

c) the resulting biochar is mixed with water in a ratio of 1: 9 by weight, held for 18-24 hours, centrifuged to separate the supernatant, washed again with water until clear wash water appears, the washed biochar is dried at 50-55 ° C;

g) the biochar obtained according to point c) is mixed with a solution of potassium permanganate 0.2 mol / l at a mass ratio of 1:12 using ultrasound with a frequency of 30-40 kHz and a power of 15 W for 60-80 minutes for stirring and placed in high-temperature furnace at 500-550 ° C for 30-40 minutes for anaerobic pyrolysis to obtain biochar material immobilized on manganese oxide;

d) add 5-6 parts of water to the washed biochar obtained under item d) add a cellulase preparation and a protease preparation, ensure that the pH of the suspension is up to 5.0-5.5, mix slowly at room temperature for 10-20 minutes and incubate for 7 hours, filtered and dried at 48-52 ° C to obtain a composite material based on biochar with immobilized exogenous enzyme;

f) mix pressed and dried algae with Indian dates Tamarindus indica, straw, oilcake and animal waste (animal hair) and compost and ferment. After 20 days, the temperature of the compost decreases, while adding flavonoid powder - bamboo leaves, corn protein powder and vegetable ash, add biochar-based composite material with immobilized exogenous enzyme, obtained according to point d), leave to ferment for 12-15 days;

g) the fermented material obtained in step e) is dried at a low temperature of 45-50 ° C and ground and mixed with potassium dihydrogen phosphate, potassium chlorate, potassium carbonate, carnallite powder, Elodea canadensis algae powder obtained in paragraph a) and other remaining materials and placed on a production plant for granulation.

Thus, the known invention provides a method for immobilizing biological enzymes on pyrochrome from biomass to improve the stability of enzymes and resistance to their inhibition, in order to compensate for the lack of potassium in the soil.

The disadvantages of the known technical solutions in relation to the method is the high technological complexity of manufacturing, including many stages of production, such as the need to neutralize compost, repeated drying, etc.

The disadvantages of the known technical solutions in relation to the composition is the complexity of the composition of the known fertilizer, which does not allow to establish how the known composition ensures the distribution of the trace element iodine in the upper arable soil layer, in contrast to the claimed technical solution.

There is also no evidence that the known technical solution provides a prolonged nature of the removal of iodine, data on the iodine content in the soil and its transition to plants when using a known fertilizer. In addition, the data on improving the quality of grain in comparison with the claimed technical solution are not confirmed in the description of the known technical solution.

The technical solution according to patent RU2557432C1 “Long-acting peat zeolite fertilizer modified with potassium iodide” was revealed from the studied prior art, the essence of which is modified with potassium iodide, including low-level peat and natural zeolite modified with potassium iodide KI, in the ratio 2.3: 1-3.4: 2 and characterized in that the natural zeolite, crushed to a grain size of 0.5-0.7 mm, is saturated from 0.02-0.04% potassium iodide solution for 14-16 hours with a weight ratio of natural zeolite and potassium iodide solution of 1: 7-1: 13.

A well-known technical solution involves increasing the bio-productivity of low-fertility cryaride and permafrost soils and crop yields, improving their quality composition by applying fertilizer containing an increased amount of potassium, humic acids, and iodine trace element in the matrix of natural zeolite. Moreover, the known method involves mixing lowland peat and natural zeolite modified with potassium iodide.

The disadvantages of the known technical solutions in relation to the composition include the absence in the description of the nature of the distribution of iodine on a solid porous carrier - zeolite. Also in the description of the known invention there is no data confirming the prolonged character of the removal of iodine from the solid porous carrier and data confirming the distribution of iodine in the upper soil layers and, accordingly, the availability of trace elements for plants. At the same time, the description does not provide evidence of an increase in the level of iodine trace element in the green mass of plants, but only an increase in certain quality parameters of the yield of green crops, which can be more associated with the introduction of peat into the soil as an integral part of the known fertilizer. Such a conclusion can be made, since the description does not include a comparison of the quality of crops when applying peat and known fertilizer containing peat and zeolite saturated with iodine. Also, in the known technical solution there is no data on improving the quality of crops, in contrast to the claimed technical solution.

The disadvantages in relation to the method include the lack of information on the procedure for applying potassium iodide to zeolites, there are no data on the characteristics of zeolites, in addition to particle sizes, the solvent and requirements for saturation of zeolite with a solution of potassium iodide are not indicated. Thus, the description of the known invention does not allow, according to the applicant, to assess the possibility of obtaining the claimed technical result in a known manner. Also, in the description of the known technical solution, the form of the known fertilizer is not indicated, which does not allow, according to the applicant, to evaluate the technological and consumer qualities of the fertilizer in comparison with the claimed technical solution.

From the investigated prior art identified a number of technical solutions, where the technical result is the improvement of grain quality.

The invention is known according to patent CN107935657 (A) "Biological organic fertilizer special for grain and preparation method of biological organic fertilizer" (Biological organic fertilizer for grain crops and a method for preparing biological organic fertilizer. The invention discloses a biological organic fertilizer specifically designed for grain crops and method preparation of biological organic fertilizer The essence is that fresh livestock and poultry manure, natural turf soil and agricultural waste are uniformly mixed for fermentation, and the fermented mixture is mixed with biochar, humic acid, clay, etc. for the preparation of organic fertilizer, where the weight ratios of the main components are as follows: 10-15 parts of turf soil, 60-70 parts of poultry and cattle droppings, 5-10 parts of humic acid, 15-20 parts of agricultural waste, 5-10 parts of clay, 5-10 biochar parts a and 0.1-0.5 parts of biological agents; the preparation method includes the stages of fermentation, mixing, granulation, drying, cooling, sieving and packaging. Organic biofertilizer for grain crops has the advantages of affordable raw materials, a simple process and low cost, it contributes to the yield of grain crops, improves the quality of grain and food quality, improves soil fertility and contributes to the problem of nutrient loss from droppings of agricultural animals, agricultural waste, and also solves the problem of disposal agricultural waste and animal droppings.

The disadvantage in relation to the method is its complex and multi-stage technology for the manufacture of known fertilizers, while the fertilizer obtained by a known method, according to the applicant, does not have a prolonged effect, the distribution of the trace element in the upper arable soil layer and the increase in the trace element content of iodine in the soil and plants its absence in the composition of a known technical solution.

A disadvantage of the known technical solution in relation to the composition is the presence of clay fillers that can have an undesirable effect on the fertile layer upon regular application, as well as the absence of a microelement of iodine in the composition, which, unlike the claimed technical solution, does not provide a technical result in the form of an increase in iodine content in plants.

Moreover, although the biochar is present in the known composition, in this case it acts as a component of the fermentable mixture, and not as a carrier for the microelement of iodine, in contrast to the claimed technical solution.

The closest in number of matching essential features, selected by the applicant as a prototype, with respect to the method for producing fertilizer and fertilizer obtained by the specified method, is the invention according to the patent RU 2698659 "Method for granulating pyrochrome with immobilized microorganisms and granules obtained by the specified method". The essence is a method of granulating pyrocholum from poultry manure with an immobilized consortium of microorganisms, characterized in that pyrocholum is fed into the granulator in an amount of 1 kg with a moisture content of up to 5%, with an average linear particle size of pyrocholum not exceeding 2 mm ± 0.5 mm, added to 1 kg of pyrocholum with immobilized microorganisms 500 ml of plasticizer, which is an aqueous solution of Silica sol “LEXIL®” 40-AL in the ratio silica sol: water = 4: 1, then the granulation process is performed at a temperature of 40 ° C ± 10 ° C and atmospheric m pressure to give the desired product in the form of granules with a size of 4 mm, then drying the granules is performed at room temperature for 2 hours. Pyrocarbon granules obtained by the method according to claim 1, having a macropore size of at least 5 μm, a specific surface area of at least 10 m ² / kg, toxicity (K10) with respect to P. caudatum no more than 5 and D. magna no more than 20, content on a dry matter basis carbon is not less than 40% by weight, nitrogen is not less than 3.5% by weight, phosphorus is not less than 1.5% by weight, potassium is not less than 4% by weight.

The disadvantages of the prototype in relation to the method is that the sequence of actions of the prototype does not allow to achieve the claimed technical result due to the lack of the stage of introducing a solution of potassium iodide into a solution of silica sol used as a plasticizer for granulation.

The disadvantages of the prototype in relation to the composition is that in the pyroglou there is no trace element iodine per se, as a result of which the technical results described in the claimed technical solution are not achieved, namely:

- increase in the trace element iodine in plants;

- improving grain quality;

Based on the analysis of the studied prior art, the applicant believes that the claimed technical solution meets the criteria of "novelty" and "inventive step", because not only eliminates the disadvantages of the prototype, but also additionally provides the ability to simultaneously improve the quality of grain and increase the iodine content in plants when using potassium iodide, which, according to the applicant, is additional evidence of compliance of the claimed technical solution with the criterion of "inventive step".

The purpose and technical results of the claimed technical solution are:

1. The prolonged nature of the removal of the trace element of iodine in the soil and its distribution in the upper arable layer of the soil, which ensures the availability of the trace element of iodine for plants;

2. The increase in the trace element iodine in the soil and in plants when applying the declared fertilizer obtained by the claimed method, due to the availability of the trace element iodine for plants;

3. Improving the quality of grain when applying the claimed fertilizer obtained by the claimed method.

An indirect result that logically follows from the technical result is the transfer of microelements into the human body when consuming vegetative or generative parts of plants, which ultimately leads to an improvement in the quality of human life and the prevention of a large number of human diseases in general associated with iodine deficiency.

The essence of the claimed technical solution is a method of producing fertilizer, which consists in the fact that they take 10 mg of potassium iodide, dissolved in 100 ml of distilled water; take silica with a mass concentration of silicon dioxide of 39-41% and a micelle size of not more than 6 nm, mix with water in the ratio of 1 part of silica to 3 parts of water; 100 ml of potassium iodide solution and 400 ml of silica sol are mixed; take 1 kg of pyrocholum and add 500 ml of the obtained aqueous solution of potassium iodide and silica sol; then pyrocarbon is granulated; then the pyrocarbon granules are kept at a temperature of 35 ° C for 4 hours. The fertilizer according to claim 1. based on pyrochol with silica sol, the micelle size of which does not exceed 6 nm, characterized in that it contains a trace element iodine at a concentration of 7.5 μg / g relative to pyrochol.

The claimed technical solution is illustrated in Figure 1 - Figure 4.

Figure 1 presents Table 1, which shows the results of a study of the prolonged removal of potassium iodide from the claimed fertilizer.

Figure 2 presents Table 2 and Table 3, which show the results of a study of the distribution of the trace element iodine in the upper arable layer under watercress and spinach, respectively.

Figure 3 presents Table 4 and Table 5, which show the results of a study of the iodine content in green and grain crops, respectively.

Figure 4 presents Table 6 and Table 7, which show the results of a study of the quality of grain of wheat and barley, respectively.

The claimed technical solution is as follows:

- Take, for example, 10 mg of potassium iodide, dissolve, for example, in 100 ml of distilled water, get a solution of potassium iodide.

- Take silica sol, for example, LEXIL® 40-AL, manufactured by the KOMPAS Science and Technology Center, with a mass concentration of silicon dioxide of 39-41% and a micelle size of not more than 6 nm, mixed with water in the ratio of 1 part of silica sol 3 parts of water.

- 100 ml of a solution of potassium iodide is mixed with 400 ml of a solution of silica sol, get 500 ml of an aqueous solution of silica sol with potassium iodide.

- Take pyrochol in an amount of 1 kg with a moisture content of up to 5%, preferably from poultry manure, mainly chicken manure, with an average linear particle size of pyrochol not more than 2 mm ± 0.5 mm, add 500 ml of an aqueous solution of silica sol with potassium iodide.

- The granulation process is carried out according to a known method (applicant's patent RU 2698659) (for example, using a domestic granulator ZLPS 120B) at a temperature of 40 ° C ± 10 ° C and atmospheric pressure in accordance with the instructions of the granulator, for which the starting materials are fed into the granulator to obtain granules with a size of, for example, 4 mm

- Maintain granules at room temperature for 4 hours at a temperature of 35 ° C.

As a result of the implementation of the claimed technical solution, the applicant received a fertilizer with the declared properties based on pyrochol containing a trace element iodine in a concentration of 7.5 μg / g with respect to pyrochol.

Further, the applicant provides evidence of the achievement of the claimed technical results in the following sequence:

1. The prolonged nature of the removal of the trace element of iodine in the soil and its distribution in the upper arable soil layer, which ensures the availability of the trace element of iodine for plants;

2. The increase in the trace element iodine in the soil and in plants when applying the declared fertilizer obtained by the claimed method, due to the availability of the trace element iodine for plants;

3. Improving the quality of grain when applying the claimed fertilizer obtained by the claimed method.

Example 1. The determination of the concentration of trace element iodine in the claimed fertilizer obtained by the claimed method.

Determination of the iodine concentration in the claimed fertilizer was carried out by a known method of mass spectrometry with inductively coupled plasma (ICP-MS) on a Perkin Elmer Elan DRC-II device (USA).

As a result of the measurements, it was found that the concentration of iodine in the claimed fertilizer is 7.5 ± 0.025 μg / g.

Proof of the claimed technical result No. 1:

Example 2. The study of the prolonged nature of the removal of the trace element iodine from the claimed fertilizer obtained by the claimed method.

The intensity of the removal of iodine trace element compounds was studied depending on the settling time (prolongation) by measuring the electrical conductivity of the aqueous extract of the claimed fertilizer and the initial pyrocarbon (control sample) at different settling times.

The intensity of the removal (prolongation) of the trace element compounds of iodine was studied by the example of contact of the claimed fertilizer with deionized water. The duration of contact was the following time intervals: 5 minutes, 60 minutes, 24 hours, 72 hours and 168 hours.

The degree of removal of soluble salts, including potassium iodide and other iodine compounds, was evaluated by the increase in electrical conductivity in the aqueous extract from the fertilizer compared with the control sample.

The experiment was carried out according to the following procedure:

Fertilizer samples weighing 2.5 g are placed in 47.5 g deionized water in conical flasks, stirred with a glass rod and set on a shaker at 800 shocks / min for 5 minutes, then left for 5 minutes and 60 minutes. To defend the hood for 24 hours, 72 hours and 168 hours, the suspensions are poured from conical flasks into cups and closed with a watch glass, sedimentation is carried out under the same conditions.

Next, determine the electrical conductivity of the resulting aqueous extract, immersing the conductivity sensor in the extract. After each measurement, the sensor is washed with distilled water.

The measurement results are shown in Table 1 in figure 1.

From the data shown in Table 1, it can be seen that the electrical conductivity indicators in the extracts from the claimed fertilizer and the control sample do not have significant differences during the first 24 hours of the experiment, which, according to the applicant, is due to the removal of soluble salts from pyrocarbon, which was initially present in both samples.

Further, in the period from 24 to 168 hours, the electrical conductivity in the extract from the claimed fertilizer exceeds 70% of the value of the control sample, which, according to the applicant, is due to the removal of iodine compounds made according to the claimed method and distinguishing the declared fertilizer from the control sample.

Proof of the claimed technical result No. 2:

Example 3. The study of the distribution of the trace element iodine in the upper arable layer when applying the claimed fertilizer obtained by the claimed method.

The experiment was performed in a laboratory experiment using soil samples as an example. The modeling of the properties of the upper arable layer was ensured by the use of gray forest soil with planted green crops - spinach and watercress, for a period of time coinciding with the corresponding vegetation cycle of these plants, subject to the corresponding temperature indicators, indicators of soil moisture, air, degree and regime of illumination in the duration of the experiment. Also, due to the presence of special drainage and the irrigation regime in the vegetation vessels, the water regime of the corresponding soil was simulated.

Take the claimed fertilizer obtained by the claimed method, in an amount of, for example, not more than 1% by weight of the soil sample, which corresponds to the dose of fertilizer based on pyrocarbon in the field. The soil is placed in the vegetation vessels, the declared fertilizer is mixed with it and moistened to the state of field moisture capacity. Next, pre-germinated spinach and watercress seeds are planted in the prepared soil with fertilizer.

In a similar way, control vegetation vessels are prepared:

- without fertilizing;

- with the introduction of a solution of potassium iodide with a concentration of 10 μg / g;

Soil samples were taken during the growing season — on days 1, 7, 14, and 21, and subsequent measurements of the iodine content in them were carried out by inductively coupled plasma mass spectrometry.

The results are shown in Tables 2 and 3 in FIG. 2.

From the data shown in Tables 2 and 3, it can be seen that at the beginning of the growing season, a soil sample with a potassium iodide solution added contains a slightly higher concentration of iodine than a soil sample with the declared fertilizer. By the end of the growing season, the iodine content in the soil in the growing vessels with watercress when applying the fertilizer declared is 85% higher compared to the control without fertilizing and with the addition of potassium iodide solution. A similar increase was proved for the soil in vegetation vessels with spinach, in which the increase in iodine concentration was 146% in relation to the control without fertilizer and 68% in relation to the control with the addition of potassium iodide solution.

This fact, according to the applicant, means that, due to the properties of the claimed fertilizer and its effect on the physical properties of the soil, when it is introduced, the intensity of migration of iodine compounds from the upper layers of the soil to the lower layers when washing out and into the atmosphere during evaporation decreases.

The observed effect can also be a consequence and indirect confirmation of the prolonged removal of iodine compounds from the claimed fertilizer.

Proof of the claimed technical result No. 2:

Example 4. The study of the iodine content in green plant cultures under the action of the claimed fertilizer obtained by the claimed method, in a laboratory experiment.

This experiment was carried out in a laboratory experiment using soil samples as an example. The modeling of the properties of the upper arable layer was ensured by the use of gray forest soil with planted green crops - spinach and watercress, for a period of time coinciding with the corresponding vegetation cycle of these plants, subject to the corresponding temperature indicators, indicators of soil moisture, air, degree and regime of illumination in the duration of the experiment. Also, due to the presence of special drainage and the irrigation regime in the vegetation vessels, the water regime of the corresponding soil was simulated.

The choice of green crops - spinach and watercress was due to their short growing season and the effective accumulation of trace elements from the soil.

Take the claimed fertilizer obtained by the claimed method, in an amount, for example, not more than 1% by weight of the soil sample. The soil is placed in the vegetation vessels, the declared fertilizer is mixed with it and moistened to the state of field moisture capacity. Next, pre-germinated spinach and watercress seeds are planted in the prepared soil with fertilizer.

At the same time, control vegetation vessels are prepared:

- without fertilizing;

- with the introduction of pyrochol without potassium iodide;

After the vegetation period, the results of determining the iodine content in plants obtained in the experimental and control vegetation vessels are compared. Determination of iodine content is carried out according to GOST 15111-2015.

The results are shown in Table 4 in FIG. 3.

From the data shown in Table 4, it is seen that the iodine content in the plants in the experimental vegetation vessel is higher than in the control vessels. Thus, when making the claimed fertilizer, it was proved that the trace element iodine concentration in the green mass of watercress was increased by 18% in relation to the control without fertilizer and by 10% in relation to the control with the added pyrocarbon without iodine. A similar increase was proved for the green mass of spinach, in which the increase in iodine concentration amounted to 21% in relation to the control without fertilizer and 18% in relation to the control with the addition of pyrocoal without iodine.

The technical result, according to the applicant, allows us to argue that the application of the claimed fertilizer obtained by the claimed method increases the trace element iodine in green plants.

Proof of the claimed technical result No. 2:

Example 5. The study of the iodine content in crops under the action of the claimed fertilizer obtained by the claimed method.

Take the claimed fertilizer obtained by the claimed method, in an amount of, for example, not more than 1% by weight of the arable layer, bring into the soil (experimental plot).

At the same time, control plots are prepared:

- without fertilizing;

- with the introduction of pyrochol without potassium iodide.

Then they carry out standard agrotechnical measures recommended for this type of soil and the nature of crop rotation, for example, cultivating the soil with further sowing, for example, wheat and barley.

After the growing season, a crop of wheat and barley is harvested, which is expressed in units, for example, c / ha.

The results are shown in Table 5 in FIG. 3.

From the data shown in Table 5, it is seen that the iodine content in cereals in the experimental plot is higher than in the control plots. So, when applying the claimed fertilizer, it was proved that the trace element concentration of iodine in wheat grain is increased by 30% in relation to the control without fertilizer and by 18% in relation to the control with the addition of pyrocoal without iodine. A similar increase was proved for barley grain, in which the increase in iodine concentration was 184% in relation to the control without fertilizer and by 157% in relation to the control with the addition of pyrocoal without iodine.

The technical result obtained, according to the applicant, allows us to argue that the application of the claimed fertilizer obtained by the claimed method increases the trace element iodine in grain crops.

Proof of the claimed technical result No. 3:

Example 6. The study of improving the quality of wheat and barley under the action of the claimed fertilizer obtained by the claimed method.

Take the claimed fertilizer obtained by the claimed method, in an amount of, for example, not more than 1% by weight of the arable layer, bring into the soil.

At the same time, control plots are prepared:

- without fertilizing;

- with the introduction of pyrochol without potassium iodide.

Then they carry out standard agrotechnical measures recommended for this type of soil and the nature of crop rotation, for example, cultivating the soil with further sowing, for example, wheat and barley.

After the growing season, a crop of wheat and barley is harvested, which is expressed in units, for example, t / ha, and the quality of wheat grain is analyzed according to the requirements of GOST 9353-2016 Wheat. Specifications and barley according to the requirements of GOST R 53900-2010. Feed barley. Technical conditions

Compare the results of grain quality assessment obtained in the experimental and control plots. The results are shown in Tables 6 and 7 in FIG. 4.

From the data shown in Tables 6 and 7, it is seen that the quality of wheat and barley grain in the experimental plot is higher than in the control plots.

Thus, when making the claimed fertilizer, an increase in the quality indicators of wheat grain in relation to the control without fertilizer was proved:

- mass fraction of protein by 37% (pyrochol without iodine by 31%);

- gluten by 33% (pyrocarbon without iodine by 14%);

- natures by 2.1% (pyrochar without iodine by 2.5%);

- the mass of a thousand grains by 7.8% (pyrochar without iodine by 5.6%);

- the numbers fall by 4% (pyrocoal without iodine by 1.1%).

A similar improvement is proven for barley grain in relation to control without fertilizer:

- increase in crude protein content by 14.4% (pyrochol without iodine by 11.6%),

- a decrease in the content of crude fiber by 21.4% (pyrocoal without iodine by 15.7%);

- a decrease in the content of crude ash by 19.1% (pyrocoal without iodine by 10.5%).

The results obtained, according to the above GOSTs, allow us to attribute these changes to improving grain quality indicators.

From the foregoing, we can conclude that the claimed fertilizer obtained by the claimed method, improves the quality of wheat and barley in the main quality indicators.

The technical result obtained, according to the applicant, allows us to argue that the application of the claimed fertilizer obtained by the claimed method improves the quality of crops in general.

Thus, from the above it can be concluded that the claimed combination of features leads to the achievement of a number of unobvious technical results that exceed the total technical results described in the analogues and prototype, namely:

1. The prolonged nature of the removal of the trace element of iodine to the soil and its distribution in the upper arable soil layer is ensured, which ensures the availability of the trace element of iodine for plants (see Example 2, Table 1 in FIG. 1);

2. The content of iodine trace element in soil and plants is increased when applying the declared fertilizer obtained by the claimed method due to the availability of the iodine trace element for plants (see Examples 3, 4, 5, Tables 2, 3, 4, 5 in Figs. 2, 3 );

3. Improved grain quality when applying the claimed fertilizer obtained by the claimed method (see Example 6, Tables 6, 7 in Figure 4);

An indirect result, logically following from the technical result, can be considered the transfer of trace elements into the human body when consuming vegetative or generative parts of plants.

The claimed technical solution meets the criterion of "novelty" presented to the inventions, since when determining the level of technology, no means were found that have characteristics that are identical (that is, coinciding in the function performed by them and the form of execution of these signs) to all the signs presented in the independent claim inventions, including the characteristics of the purpose, when achieving higher, in comparison with the prototype, technical results.

The claimed technical solution meets the criterion of "inventive step" for inventions, since no technical solutions have been identified that have features that match the distinctive features of the claimed invention, and the popularity of the distinctive features on the specified technical result has not been established. Moreover, the claimed technical solution is not obvious to the specialist due to the fact that the applicant was able to simultaneously ensure the prolonged action of the claimed fertilizer obtained by the claimed method, increasing the iodine content in grain and green crops, improving grain quality.

The claimed technical solution meets the criterion of "industrial applicability" to the invention, because can be implemented on an industrial scale through the use of well-known standard technical devices and equipment.

Claims (2)

1. A method of producing fertilizer based on pyrochol, which consists in the fact that they take 10 mg of potassium iodide, dissolved in 100 ml of distilled water; take silica with a mass concentration of silicon dioxide of 39-41% and a micelle size of not more than 6 nm, mix with water in the ratio of 1 part of silica to 3 parts of water; 100 ml of a solution of potassium iodide and 400 ml of a solution of silica are mixed, 1 kg of pyrocarbon is taken and 500 ml of the obtained aqueous solution of potassium iodide and silica are added, then the pyrocarbon is granulated, then the pyrocoal granules are kept at a temperature of 35 ° C for 4 hours. 2. The fertilizer obtained by the method according to claim 1, based on pyrochol with silica sol, the micelle size of which does not exceed 6 nm, characterized in that it contains a trace element iodine in a concentration of 7.5 μg / g relative to pyrochol.

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