RU2729363C1 - Fodder additive (embodiments) and method for production thereof - Google Patents

Abstract

FIELD: agriculture.

SUBSTANCE: inventions relate to agriculture. Feed additives for animals contain modified zeolite and amino acid component, wherein porosity of modified zeolite ranges from 45 to 75 %, sizes of cavities and channels of zeolite crystals range from 2 to 9 Angstrom, amino acid component contains a set of free amino acids obtained by cell synthesis and having a size of molecules up to 9 angstroms. Method of producing a feed additive based on modified zeolite enriched with an amino acid component is characterized by using a modified zeolite with porosity of 45 to 75 % and dimensions of cavities and channels of zeolite crystals from 2 to 9 Angstroms and an amino acid component comprising a set of free amino acids obtained by cell synthesis and having a molecule size of up to 9 Angstroms, semi-finished product of crushed and fractionated zeolite is placed in thermal activation unit, where zeolite is dehydrated at temperature of 150–600 °C, amino acid component is added to distilled water and their mixing is performed.

EFFECT: inventions allow increasing volumes of agricultural production, improving quality and value of agricultural products, productivity of animals, birds and fishes.

13 cl, 2 dwg, 6 tbl

Description

The technical field to which the invention relates.

The group of inventions relates to the field of agriculture and can be used to balance the diets of animals, poultry and fish.

State of the art.

Known feed additive, including protein-containing raw materials and zeolite, which additionally contains a liquid source of amino acids in the following ratio of components, wt.% Dry matter: liquid source of amino acids 11.7-33.9, zeolite 3.5-79.3, protein-containing raw material - the rest (RU2031950C1, 27.03.1995).

A known method of preparing feed for ruminants is characterized by the fact that mechanical mixing of a concentrated basic diet with essential amino acids, which are pre-mixed with dehydrated natural zeolite and water in a ratio of 1: 20: 0.2. The manufacture allows to protect essential amino acids from the action of proteolytic enzymes of rumen microorganisms and promotes transfer to the lower parts of the gastrointestinal tract of animals (RU2284123C2, 09/27/2006).

There is also known a method of obtaining a feed mixture, including mixing vegetable feed with an additive, an organo-mineral product containing, by weight, is used as an additive. amino acid component 18.5-35.3, organic component 10.3-48.4 and zeolite 16.3-59.7 in the following ratio of components, wt .: organo-mineral product 0.7-30.0, vegetable feed - the rest (RU2038799C1, 09.07.1995).

Known feed additives and mixtures are characterized by the joint content of zeolite and an amino acid component.

Zeolite is a mineral of natural origin, formed under the influence of high temperatures and pressure at the contact of rock and groundwater. It has a crystal lattice, cavities and channels (up to 9 angstroms), consists of aluminosilicates (SiO ₂ and AlO ₄ ), inside it has negatively charged ions of potassium, magnesium, silicon (up to 40 mineral elements) and water molecules. This structure allows you to capture substances in liquid, gaseous and solid form and, if necessary, decompose them. Zeolite not only adsorbs, removes harmful substances and removes them from the body, but at the same time gives it useful ones (ions of mineral elements, amino acids in weak bonds with it), increases the intensity of ion exchange, providing mineral homeostasis.

Amino acids, in turn, stimulate the processes of digestion and metabolism in the body.

Meanwhile, the known feed additives do not allow to fully realize the genetically based productivity of animals, birds and fish due to their insufficiently high efficiency.

The technical problem, the solution of which is provided in the implementation of the proposed group of inventions, is to create a group of feed additives based on zeolite and amino acids, applicable to various species of animals, birds and fish, as well as in the development of a method for the manufacture of such additives, which would ensure the preservation of the structure of the zeolite crystal with an increase in the adsorption capacity, the system of channels and cavities of crystals, which makes it more accessible for adsorbed amino acid molecules.

Disclosure of the essence of the invention.

The technical result of the claimed group of inventions is to increase the volume of agricultural production, improve the quality and value of agricultural products, the productivity of animals, birds and fish, as well as reduce the cost of feed and ensure the availability of feed additives for livestock breeders at a price.

The technical result is achieved by a feed additive for animals, characterized in that it contains a modified zeolite and an amino acid component, the porosity of the modified zeolite is from 45 to 75%, the dimensions of the cavities and channels of the zeolite crystals are from 2 to 9 angstroms, the amino acid component contains a set of free amino acids obtained by the method of cell synthesis and having a molecular size of up to 9 angstroms, with the following ratio of components, wt%:

amino acid component - 2-3

modified zeolite - the rest.

The free amino acid set of the animal feed supplement may include at least L-lysine, L-valine, L-arginine, L-isoleucine, aspartic acid, L-alanine, glutamic acid, L-glycine, L-methionine, L -proline, hydroxyproline, leucine, phenylalanine, serine.

The technical result is achieved by a feed additive for poultry, characterized by the fact that it contains a modified zeolite, an amino acid component, an antioxidant, a vitamin component and potassium iodide, the porosity of the modified zeolite is from 45 to 75%, the dimensions of the cavities and channels of the zeolite crystals are from 2 to 9 angstroms, the amino acid component contains a set of free amino acids obtained by the method of cell synthesis and having a molecular size of up to 9 angstroms, with the following ratio of components, wt%:

antioxidant - 1-3

vitamin component - 0.3-0.5

potassium iodide - 0.2-0.4

modified zeolite enriched with amino acid component - the rest.

The free amino acid kit of the poultry feed additive may include at least L-lysine, L-valine, L-arginine, L-isoleucine, aspartic acid, L-alanine, glutamic acid, L-glycine, L-methionine, L -proline, hydroxyproline, leucine, phenylalanine, serine.

The vitamin component of the poultry feed supplement may contain at least vitamin A, vitamin D3, vitamin E, vitamin K, and B vitamins. Diludin can be used as an antioxidant.

The technical result is achieved by a feed additive for fish, characterized in that it contains a modified zeolite, an amino acid component and a vitamin-amino acid complex, the porosity of the modified zeolite is from 45 to 75%, the dimensions of the cavities and channels of the zeolite crystals are from 2 to 9 angstroms, the amino acid component contains a set of free amino acids obtained by the method of cell synthesis and having a molecular size of up to 9 angstroms, with the following ratio of components, wt%:

amino acid component - 1.5-2.5

vitamin and amino acid complex - 8-10

modified zeolite - the rest.

The free amino acid kit of the fish feed supplement may include at least L-lysine, L-valine, L-arginine, L-isoleucine, aspartic acid, L-alanine, glutamic acid, L-glycine, L-methionine, L -proline, hydroxyproline, leucine, phenylalanine, serine.

The vitamin-amino acid complex of the fish feed additive may contain at least vitamin A, vitamin D3, vitamin E, vitamin K, vitamin H and B vitamins.

The technical result is achieved by the method of making a feed additive, characterized in that the semi-finished product of crushed and fractionated zeolite is placed in a thermal activation unit, where the zeolite is dehydrated at a temperature of 150-600 ° C, the amino acid component is added to distilled water and mixed, the zeolite is placed in a mixing the installation and fed into it through sprinklers an aqueous solution of the amino acid component with constant stirring, while one ton of the modified zeolite is sprayed from 50 to 200 liters of an aqueous solution of the amino acid component, and the zeolite is heated to a temperature of 35-60 ° C.

In some embodiments of the method, the dehydration of the zeolite is carried out until it reaches a moisture content of 0.1 to 5%; during dehydration of the zeolite, its partial dealumination is carried out; an aqueous solution of the amino acid component is sprayed onto the modified zeolite until the resulting mixture reaches a moisture content of 1 to 7%.

Implementation of the invention.

A feature of all variants of the proposed feed additives is that the amino acid component included in their composition contains a set of free amino acids obtained by the method of cell synthesis and having a molecular size of up to 9 angstroms, which allows them to enter into synergistic interaction with modified zeolites at the ultramolecular level.

Separation of free amino acids (ranging in size from 5 to 20 angstroms) occurs when passing through a molecular sieve of zeolites (up to 9 angstroms). As a result, cation exchange is activated in the zeolite crystal lattice, and fragile bonds with amino acids are formed. Due to this, the feed additive gives (throws away) exactly those amino acids that are needed by the body at the moment for the synthesis of a certain protein and (or) are carriers of biologically active substances, and these components are able to easily penetrate the walls of the cells of the stomach, intestines and are quickly absorbed by the body.

It is also essential that for the production of the proposed feed additives, it is the modified natural zeolite treated with various activation methods that enhances its properties and effectiveness several times.

Almost all natural zeolites are suitable for use in various industries. The dehydration process is the preparation of zeolites of a particular deposit for work. Increases its sorption capabilities and increases ion exchange capacity.

The ion exchange capacity of zeolites is one of the main parameters characterizing their sorption and technological properties. The maximum ion exchange capacity corresponds to the complete replacement of one ion by another in all crystal positions, which corresponds to the maximum sorption capacity of the zeolite.

The chemical composition of zeolites CPS: (Ca, Na2, K2) O • Al2O3 • 10SiO2 • 8H2O. The total cationic capacity is 87 meq / 100 g of rock, the ion exchange capacity is 2.5 meq / g. The adsorption capacity for H2O (water), methanol, CO2 (carbon dioxide), O2 (oxygen), SO2 (sulfur dioxide), H2S (hydrogen sulfide), NH3 (ammonia), N2 (nitrogen), large organic molecules is noted.

An important property of zeolites is their porosity - the proportion of filling the volume of the material with pores. Total porosity or simply porosity -

P total = (1-ro / ri) x100

ro is the average density of the material, g / cm3 (kg / m3);

ri is the true density of the material, g / cm3 (kg / m3).

The porosity is defined as a percentage.

The total porosity consists of open and closed.

The open porosity of a material is called the volume of those that communicate with the external environment. Their volume can be measured by the water saturation of the material. Open porosity is numerically equal to the water absorption of the material. Closed porosity is calculated from the difference between total and open porosity.

Zeolite modification is carried out to increase open porosity so that as many pores as possible are freed from impurities and zeolite water for the adoption of amino acids or any other enrichment. The porosity of the modified zeolite in the proposed group of inventions is from 45 to 75%.

Zeolite frameworks are similar to honeycomb and are formed from chains of silicon and aluminum anionites. Due to its structure, the framework has a negative charge and this charge is compensated by cations of alkali or alkaline earth metals in the honeycomb cavities. The type of zeolite (its pore diameter) is determined by the ratio of silicon and aluminum and the type of cations.

The molecular sieve properties of zeolites are determined by the effective diameter of the "windows", which, in turn, depend on the geometric dimensions of the latter and the presence of exchangeable cations in them. To assess the possibility of a molecule of the adsorbed substance entering the adsorption cavity (both during adsorption of substances and during ion exchange), the diameter of the entrance windows of the zeolite (angstroms) is compared with the diameter of the adsorbed molecule itself (during adsorption) or with the diameter of various cations (during ion exchange) ... The size and shape of the windows can change during the dehydration of the zeolite. Windows can be round (zeolite A), elliptical (dehydrated chabazite, erionite). Hydrated Ca-chabazite has round windows with a diameter of 0.39 nm, but upon dehydration they take an elliptical shape of 0.37x0.42 nm. The shape of the windows can change during the adsorption of polar molecules. With increasing temperature, the effective window size increases by approximately 0.03 nm. The change in the window diameter with temperature is explained by the activation character of the diffusion process as a result of an increase in the kinetic energy of molecules. An increase in temperature enhances the vibrations of O - ions and cations surrounding the window in the zeolite lattice.

Each of the zeolites is capable of absorbing molecules no larger than their own "windows"; this zeolite is not able to adsorb molecules larger than the pore diameter of the zeolite.

But in order to force the zeolite to work in the right direction, it is necessary to carry out its modification, which includes mechanical activation, thermal activation. This technological process is aimed at obtaining a modified zeolite, which will be able to ensure the introduction of various useful components into its structure and the creation on their basis of highly effective, environmentally friendly and cost-effective feed additives (premixes).

The production process of feed additives based on modified zeolite enriched with low molecular weight amino acids consists of four main stages:

1. Preparation of zeolite for enrichment - the process of modification or activation. These are mechanical activation, thermal activation or dehydration, at the required temperatures, intensive cooling, crushing, fractionation.

2. Preparation of amino acids and vitamins for enrichment of zeolite - the process of dosing, mixing the main components, obtaining the desired concentration by diluting with ionized or distilled water, introducing additional components according to the approved recipe.

3. Enrichment of zeolite with amino acids and vitamins.

4. Packing the resulting product in big bags (polypropylene bags with a dense polyethylene liner of 650 kg) or in multi-layer paper bags of 25 kg, as well as in polypropylene bags with an inner liner, valve or with a sewing, or in other containers as agreed with the consumer ... Warehousing, shipment to the consumer.

The creation of a product that ensures the effectiveness of a zeolite is as follows: the structure of zeolites determines their internal volume, which becomes available after dehydration. Dehydrated zeolite is a crystalline body permeated with micropores. In the dehydrated state, zeolites maximize their adsorption, molecular sieve and catalytic properties.

The pore size of the zeolite also determines the size of the particles that can penetrate into them; zeolites can "sift molecules", sort them by size.

The zeolite modification process takes place in rotating units at certain temperature conditions.

With satisfactory results of the production control analysis, after the 1st stage of cascade mechanical activation, the semi-finished product of crushed and fractionated zeolite enters a specialized thermal activation unit, where, at individual design temperature ranges, the zeolite is dehydrated - removal of zeolite water and gaseous impurities that the zeolite sorbs in natural conditions, as well as organic impurities in the rock. The stage of thermal activation of the semi-finished product takes place without disturbing the crystal structure. The thermally activated zeolite retains its properties and allows the vital microelements to be preserved in unchanged quantities. Thermal activation of natural zeolite can significantly increase the adsorption capacity - the system of channels and cavities that permeate the crystals of the zeolite. This system becomes more accessible for adsorbed molecules, dehydrated crystals of zeolite most strongly exhibit molecular sieve effects, and also allows you to ensure the absence of pathogenic microflora in the final product, which once again confirms the safety of the product. For example, the specific surface area of a processed zeolite is more than 3 times that of an unactivated zeolite.

Zeolite is being prepared, i.e. thermomechanical treatment required for its subsequent enrichment. Zeolite dehydration takes place at a temperature of 150-600 ° C. At a given temperature, β-quartz transforms into β-quartz with an expansion coefficient of 1.082. At this temperature, all channels are opened, zeolite water and impurities, which are saturated with natural zeolite, are removed, and partial dealumination also occurs - removal of free aluminum.

The moisture content of the modified zeolite should be within 0.1-5%.

Technological parameters of the obtained modified zeolite:

1. Appearance - gray-yellow granules

2. Bulk density - 650-700 kg / m3

3. Fractional composition - 0.3-4 mm

4.pH of the water extract - 6.5-7

5. Water absorption - 35-65%

6. Porosity - 45-75%

7. Moisture capacity - 3 liters of water per 1 kg of zeolite

8. Oil content - 61%

9. Water-holding capacity - 96.13%

10. Thermal conductivity - 0.08-0.11 W / m * K

11. Strength when compressing in the cylinder - 4.5 - 11.0 MPa

To prepare the amino acid component, water is supplied to the cubic containers. Distilled water is used, heated to 35-40 ° C. At the same time, 2 cubic containers of 900 liters of water each are used.

Further, a liquid concentrate of amino acids of high purity and biological activity in a certain amount is measured and poured into the container.

With the help of a small submersible pump at low speed, all components are mixed until smooth. Stir slowly to avoid foam formation. Further, the prepared mixture is fed through pipelines to the supply tank of the mixing plant.

The third stage is the process of enrichment of the zeolite modified with an amino acid component.

The beneficiation process begins with weighing and feeding the modified zeolite using a self-loading skip hoist into the mixer. Dosing is carried out when loading modified zeolite per 1 big-bag, i.e. 1 m ³ , which corresponds to 650 kg. Next, an aqueous mixture of amino acids is fed to the mixer through a sprayer with constant stirring.

The whole process is automated, controlled from the operator's room through a computer according to a given program. The estimated time for feeding an aqueous solution of amino acids is 6 minutes. This time was chosen after a series of mixing operations. For 650 kg of modified zeolite, 30-130 liters of an aqueous solution of amino acids are fed. Mixing goes very well, almost all of the granules are wetted. The resulting mixture of modified zeolite with an aqueous solution of amino acids has a moisture content of 1-7%

To improve the adsorption capacity of the zeolite, it is necessary to heat it up to a temperature of 35-90 ° C. For this, sprayers are installed in the structure intended for enrichment of the zeolite with the amino acid component. For the most effective adsorption of amino acids into the zeolite, the amount and time of spraying of the supplied amino acid solution and, most importantly, the temperature of the mixture heating are important.

Tables 1-3 show examples of various options for feed additives made in this way based on a premix from a modified zeolite enriched with an amino acid component. In some variants, the composition of the supplement is supplemented with a vitamin component, an antioxidant and a trace element or a vitamin-amino acid complex.

The proposed variants of feed additives have high biological activity and do not contain chemical components. They are a source of amino acids for the synthesis of new protein and a source of mineral elements, when they are deficient in the body. Supplements improve appetite, digestion and assimilation of substances in the feed ration of animals, birds and fish. They are well absorbed and absorbed, stimulate beneficial microflora in the gastrointestinal tract, enhance the formation of: bones, collagen, nucleic acids, heparin, increase metabolic processes in the body. In addition, supplements stimulate the body's defenses after illness, childbirth, stress, restore reproductive capacity, and increase the likelihood of successful fertilization.

Feed additives work well on diets poor in protein and amino acids and increase the efficiency of using the most deficient amino acids for the body, adsorb and remove radioactive substances, toxins, allergens, and heavy metals.

The additive for animals increases their productivity by 8 ... 36%, improves the quality, improves the taste and nutritional value of products, increases the safety and survival of young animals, is a growth stimulator, increases protein anabolism in their bodies, allows better food absorption, improves the quality of carcasses, reduces feed costs, reduces stress factors, recovers from illness and antibiotic treatment.

The additive for poultry improves the general health of the bird, regulates growth and productivity (egg production by 12-20%; shell strength), increases feather growth and shell formation.

The additive for fish increases fish productivity (underyearlings by 19 ... 36%), stimulates the growth rate, provides high taste qualities of fish, increases the activity of fish and reduces its waste (by 20..30%). The additive also improves the physiological state of underyearlings and marketable fish, reduces the concentration of heavy metals and radionuclides in the muscle tissue of fish, their accumulation occurs in the inedible part of the fish (head, bone tissue and internal organs). Thanks to the additive for fish, the hydrochemical regime of the reservoir is improved: the water is purified from ions of heavy metals and radionuclides (Zn, Cu, Pb, Cs, Sr, etc.), completely frees water from mercury and arsenic.

The positive effect of using the proposed feed additives is confirmed by test results.

In lactating cows, a positive effect of feeding additives on milk composition and level of productivity was revealed (table 4).

The use of zeolite as a filler promoted a gradual increase in the fat content of cows' milk. Feeding cows supplements based on zeolite and amino acids contributed to increased protein synthesis, increased protein content and the amount of non-fat milk solids in milk. The protein concentration in the milk of cows of the 2nd group was 3.145 ± 0.047 and 3.353 ± 0.028%, compared with the control, this parameter increased by 2.3 ... 2.4%, and in relation to the previous period - increased by 6.6%. SOMO shows what will remain of milk if you dry all the water from it and remove all the fat. In cows of the 2nd group, the concentration of SNF was in the range of 8.607 ± 0.090 and 8.968 ± 0.046, which is close to 9.0% and indicates the naturalness of whole milk, if it is less than 8%, then it is considered that the milk is diluted with water. The ash content in the experimental group in relation to the previous period increases only by 4.5%, while in the control - by 6.2%. This characterizes the best use of minerals both for the development of the fetus and their output with milk.

The analysis of the average daily milk yield of experimental cows made it possible to identify some patterns (table 5).

If the animals of the control group over the period of the experiment noted a pronounced decrease in the average daily milk yield from the 4th to the 6th month of lactation within 7.77 ... 9.47%. The inclusion of additives in the diet of dairy cows does not allow a sharp drop in milk yield, but maintains it at a certain level. In the 2nd group, cows showed a gradual decrease in milk yield compared to the previous period, respectively, by 6.9% - at 4 ... 5 months of lactation and by 2.47% - at 5 ... 6 months. This is a good indicator. The calculation of milk fat showed that if there was a decrease in the control group, then under the influence of the additive there was an increase in this parameter by 12.52% in comparison with this indicator by the previous month of lactation. Thus, the inclusion in the daily diet of lactating cows of an additive based on modified zeolite enriched with amino acids stimulates the synthesis of milk in their body, improves the quality of milk, increases its fat content and SNF.

Tests of the feed additive for poultry showed an increase in poults with the use of the additive up to 18% (diagram 1) Also, turkeys showed a positive effect on plumage due to the enrichment of their diet with a feed additive based on modified zeolite (photo 1).

As part of the test of a feed additive for fish, larvae of fish with an average piece weight of 60 mg, stocking density of 30 thousand were introduced into two nursery ponds. / ha. After 18 days, 1% of the feed additive was introduced into the feed. The second pond served as a control without the use of additives in the feed.

Before stocking the ponds, a qualitative and quantitative survey of zooplankton in the control and experimental ponds was carried out. The biomass of zooplankton organisms in both ponds was the same.

Every 15 days after stocking the ponds, the water temperature and oxygen content were regularly monitored. Determined the temperature of the water. Water samples to determine the oxygen content were taken at a depth of 10 cm from the bottom of the reservoir at 10 am.

The growth of juveniles during the growing season was monitored by catching 400-500 pieces. juveniles. The caught fish was weighed, carefully examined for the absence of diseases.

At the end of the growing season, fish underyearlings were counted in both ponds and samples were taken for biochemical studies for protein, fat, minerals and dry matter, as well as for the content of heavy metals and radionuclides.

The studies carried out to determine the content of heavy metals and radionuclides in the water of the compared ponds showed that the zeolite enriched with amino acids ensures the purification of water from zinc, copper, lead, cadmium, nickel, chromium, cesium, strontium ions. The water was completely freed from mercury and arsenic. This is due to the fact that the zeolites in the composition of the food were supplied to the fish along the food paths directly into the water and, being in the water for some time, the zeolites adsorbed ions of heavy metals and radionuclides.

Thus, the addition of zeolite enriched with amino acids to the feed improved the hydrochemical regime. The concentration of heavy metals and radionuclides has significantly decreased. All this could not but have a positive effect on the formation of a natural food base.

A month after the start of the introduction of the additive into the feed, the absolute growth of underyearlings in the control pond was already 4.2 times less than in the experimental pond. Analysis of the results shows that in the control pond the fish productivity was 741 kg / ha, in the experimental pond the fish productivity was 32% higher and amounted to 980 kg / ha. The average piece weight of young of the year fish after three months was 38 g in the control pond, 62 g in the experimental pond; the yield was 90% higher.

The calculation of the economic efficiency of using fish in the diet of underyearlings at a dose of 1% of the feed weight showed that fish productivity increased by 141 kg / ha. The profitability in the experimental pond was more than 300% versus 18.5% in the control (table 6).

Claims (16)

1. A feed additive for animals containing a modified zeolite and an amino acid component, characterized in that the porosity of the modified zeolite is from 45 to 75%, the dimensions of the cavities and channels of the zeolite crystals are from 2 to 9 angstroms, the amino acid component contains a set of free amino acids obtained by the method cell synthesis and having a molecular size of up to 9 angstroms, with the following ratio of components, wt%: amino acid component 2-3 modified zeolite rest 2. Feed additive for animals according to claim 1, characterized in that the set of free amino acids includes at least L-lysine, L-valine, L arginine, L-isoleucine, aspartic acid, L-alanine, glutamic acid, L-glycine, L-methionine, L-proline, hydroxyproline, leucine, phenylalanine, serine. 3. Feed additive for poultry, containing a modified zeolite and an amino acid component, characterized in that it additionally contains an antioxidant, a vitamin component and potassium iodide, the porosity of the modified zeolite is from 45 to 75%, the sizes of cavities and channels of zeolite crystals are from 2 to 9 angstroms, the amino acid component contains a set of free amino acids obtained by the method of cell synthesis and having a molecular size of up to 9 angstroms, with the following ratio of components, wt%: antioxidant 1-3 vitamin component 0.3-0.5 potassium iodide 0.2-0.4 modified zeolite enriched amino acid component, rest 4. Feed additive for poultry according to claim 3, characterized in that the set of free amino acids includes at least L-lysine, L-valine, L arginine, L-isoleucine, aspartic acid, L-alanine, glutamic acid, L-glycine, L-methionine, L-proline, hydroxyproline, leucine, phenylalanine, serine. 5. Feed additive for poultry according to claim 3, characterized in that the vitamin component contains at least vitamin A, vitamin D3, vitamin E, vitamin K and B vitamins. 6. Feed additive for poultry according to claim 3, characterized in that diludin is used as an antioxidant. 7. Feed additive for fish, containing a modified zeolite and an amino acid component, characterized in that it additionally contains a vitamin-amino acid complex, the porosity of the modified zeolite is from 45 to 75%, the sizes of cavities and channels of zeolite crystals are from 2 to 9 angstroms, amino acid the component contains a set of free amino acids obtained by the method of cell synthesis and having a molecular size of up to 9 angstroms, with the following ratio of components, wt%: amino acid component 1.5-2.5 vitamin and amino acid complex 8-10 modified zeolite rest 8. Feed additive for fish according to claim 7, characterized in that the set of free amino acids includes at least L-lysine, L-valine, L arginine, L-isoleucine, aspartic acid, L-alanine, glutamic acid, L-glycine, L-methionine, L-proline, hydroxyproline, leucine, phenylalanine, serine. 9. Feed additive for fish according to claim 7, characterized in that the vitamin-amino acid complex contains at least vitamin A, vitamin D3, vitamin E, vitamin K, vitamin H and B vitamins. 10. A method of manufacturing a feed additive based on a modified zeolite enriched with an amino acid component, characterized in that a modified zeolite with a porosity of 45 to 75% and dimensions of cavities and channels of zeolite crystals from 2 to 9 angstroms and an amino acid component containing a set of free amino acids are used, obtained by the method of cell synthesis and having a molecular size of up to 9 angstroms, a semi-finished product of crushed and fractionated zeolite is placed in a thermal activation unit, where the zeolite is dehydrated at a temperature of 150-600 ° C, the amino acid component is added to distilled water and mixed, the zeolite is placed in a mixing the installation and fed into it through sprinklers an aqueous solution of the amino acid component with constant stirring, while one ton of the modified zeolite is sprayed from 50 to 200 liters of an aqueous solution of the amino acid component, and the zeolite is heated to a temperature of 35-90 ° C. 11. A method of making a feed additive according to claim 10, characterized in that the zeolite is dehydrated until it reaches a moisture content of 0.1 to 5%. 12. A method of manufacturing a feed additive according to claim 10, characterized in that when the zeolite is dehydrated, it is partially dealuminated. 13. A method of manufacturing a feed additive according to claim 10, characterized in that an aqueous solution of an amino acid component is sprayed onto the modified zeolite until the resulting mixture reaches a moisture content of 1 to 7%.

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