RU2705275C2 - Method for preparation of keratin soil enriching agent with addition of humic acids in colloid form - Google Patents

Abstract

FIELD: chemistry.

SUBSTANCE: invention relates to a method for preparation of keratin soil enriching agent with addition of humic acids in colloid form. Method comprises treating mixture, which is a chicken feather, duck or ostrich feathers from poultry farms, and/or bristle and hair covering from animal skins, horns and hoof, pork hooves, fish processing wastes, fur, hair, leather production wastes, sheep wool, camel's wool, bristles of pigs, cattle and/or kangaroos, livestock bones, camels, kangaroos, bones of any poultry and pork bones. At the first stage, the preliminarily suspended said mixture is loaded into the reaction vessel. At the second step, weight ratio of one part of caustic potassium (KOH) per one part of said mixture is added to a reaction vessel in which the suspended treated mixture is loaded. At the third step, water is added to the reaction vessel in the weight ratio of one part of water to one part by weight of said mixture. At fourth stage conditions are created for decomposition of treated mixture in reaction vessel. Decomposition is carried out in a reaction vessel for 20 hours under conditions of stirring performed from time to time. At the fifth stage neutralization is performed. At the sixth step, the pH of the mixture is measured. For this purpose, neutralized treated mixture is sampled, cooled to temperature of 20 °C and its pH is measured. PH value must be in range of 6.5 ± 0.2. If pH is outside this range, 99 % citric acid, 85 % formic acid, 80 % acetic acid or caustic potassium are added to the range of values to be added to the mixture. At the seventh step, to obtain a modified mixture, the treated mixture is added with 10–13 wt. % of an Epsom salt (MgSO₄), 0.19–0.23 % of iron vitriol (FeSO₄), 0.05–0.075 wt. % boric acid (H₃BO₃), 0.03–0.055 wt. % manganese sulphate (MnSO₄), 0.008–0.02 wt. % zinc sulphate (ZnSO₄), 0.008–0.02 wt. % copper sulphate (CuSO₄), 0.001–0.005 wt. % ammonium molybdate ((NH₄)₆Mo₇O₂₄) and 17–22 wt. % calcium nitrate (Ca(NO₃)₂) in respect to the weight of the mixture to be treated. At the eighth stage, the mixture is unloaded from the reaction vessel into the transfer vessels. Unloading depends on the mass of potassium hydroxide contained in the obtained modified treated mixture. Amount N of prepared transportation containers is determined by formula N = KOH/50, where KOH is the mass of potassium hydroxide. Neutralized mixture, which is the base of soil enriching agent, is unloaded from reaction vessel and based on calculations is dosed loaded into prepared transportation containers by means of drain pump through suitable filter at continuous mixing of treated mixture, which is base of soil enriching agent and is in reaction vessel. At the ninth step, the diluted treated mixture is prepared. Water with amount of up to 1000 l is added to the vessel with the mixture and the whole contents of this vessel is mixed until homogeneous. At the tenth step humic acids are added to the mixture in a transportation container in amount of 10–15 wt. % of humic acids based on the weight of the suspended mixture. Neutralization at the fifth step of the method is carried out using citric acid (C₃H₅O (COOH)₃), formic acid (HCOOH) or acetic acid (CH₃COOH), wherein 50 kg of 99 % citric acid, or 50 kg of 85 % acetic acid, or 50 kg of 80 % formic acid is used for every 50 kg of 95 % potassium hydroxide (KOH).

EFFECT: implementation of the assignment is provided.

1 cl

Description

The technical field to which the invention relates.

The present invention relates to a method for preparing a keratin soil enriched with an additive from humic acids in colloidal form and a keratin soil enriched with an additive from humic acids.

The background of the invention

A ballast impurity containing organic bonded nitrogen intended for the production of granular or liquid soil enrichment is described in the published patent application of the Slovak Republic No. PP1539-2003. This ballast admixture contains a mixture of untreated horns and hooves of cattle or granules of processed horns and hooves of cattle with a moisture content of up to 12 wt. % of horns and hooves, with up to 18% of this ballast impurity being protein-bound organic nitrogen, while the size of granules obtained from granules of horns and hooves varies from 0 mm to 12 mm. The essence of this solution consists in a method for the production of ballast impurities containing organic nitrogen, which is intended for the production of granular or liquid soil enrichment, while the ballast mixture is poured into a technological tank, for example, in a reactor. 100% potassium hydroxide (KOH) is added to the mixture to be processed in a mass ratio of at least 1: 2, and 200 l of water are poured into the process tank. The mixture may be subjected to stirring or heating in an alkaline bath. After the mixture is dissolved, it is neutralized by mixing 50 l of 85% phosphoric acid. Upon completion of the neutralization process, the mixture can be enriched with other nutrients and elements, for example, nitrates (NO ₃ ^- ), magnesium (Mg), iron (Fe), cobalt (Co), boron (B), manganese (Mn), zinc ( Zn), copper (Cu), etc. Finally, the solution is mixed with water (H ₂ O) until a volume not exceeding 1000 l is reached.

The amount of nitrogen in the soil is the most important factor in terms of plant nutrition, although the presence of phosphorus and sulfur are also useful in terms of plant nutrition. Nitrogen in the soil is bound organically, so it is gradually released into the soil. During the decomposition of protein substances, first of all, ammonium ions (NH ₄ ) ^{+ are formed} , which upon further oxidation turn into nitrates (NO ₃ ^- ).

Soil fortifiers produced so far usually have a low content of the above nutrients and elements. Nitrogen is present in the form of nitrates, and also, in less significant quantities, in the form of ammonium. Amide nitrogen is less necrotic on plant tissue when it is not applied directly to the roots. In combination with nitrogen in other forms, amide nitrogen provides better absorption of these nutrients by plants.

There is also known a method of producing compost according to Hungarian patent No. 202 336A. This patent describes a method for producing compost with a high content of organic substances, which have a stimulating and alternative improving effect when using additives containing keratin and pig manure. The production process itself consists in the separation of pig manure into a solid phase and a liquid phase. The solid phase of pork manure is mixed with components containing keratin - hair or horns. The base material resulting from this process contains keratin in an amount of 5% to 50%. This base material is mixed with 2-8% slaked lime, 5-10% alginite, 5-10% rhyolite tuff and 10-20% turf. The resulting mixture, taking into account its total mass, is homogenized by mixing with a keratin additive taken in an amount of 10%. Then such a well-mixed compost is placed in tanks. The humidity of the tank, which reaches 65-80%, is provided thanks to the liquid, which contains 5-20% of dissolved keratin. Such a tank is mixed after one to two months.

These above-mentioned soil enrichment agents with keratin additive are technically expensive and time-consuming, requiring a certain time for implementation, in addition, the costs of their development are also increased due to the use of heat treatment.

A brief description of the invention

The subject of the claimed invention is a method for preparing a keratin soil fortifier with colloidal form of humic acids and a keratin soil fortifier obtained by this method, that is, obtained by processing feathers, for example, chicken, duck or ostrich from poultry farms, and (or) bristles and hair cover from the skins of cattle, horns and hooves, pork hooves, waste from the processing of fish, fur, hair, leather wastes, sheep wool, camel hair, pig bristles, cattle and (or) kangaroos, awns cattle, camels, kangaroos, birds and any bones of pig bones.

Before the start of the production process, feathers, for example, chicken, duck or ostrich from poultry farms, and (or) bristles and hair from the skins of cattle, horns and hooves, pork hooves, fish processing waste, fur, hair, leather processing waste, sheep’s wool, camel hair, bristles of pigs, cattle and (or) kangaroos, bones of livestock, camels, kangaroos, bones of any bird and pork bones must be delivered in a transport container that has been approved by the veterinary service and sanitized by a certified firm. Then feathers, for example, chicken, duck or ostrich from poultry farms, and (or) bristles and hair from the skins of cattle, horns and hooves, pork hooves, fish processing waste, fur, hair, leather processing waste, sheep’s wool, camel’s wool, the bristles of pigs, cattle and (or) kangaroos, livestock bones, camels, kangaroos, bones of any birds and pig bones are properly unloaded in a specially designated place. In order to avoid possible undesirable changes in the quality of the material, processing of feathers, for example, chicken, duck or ostrich from poultry farms, and (or) bristles and hair cover from the skins of cattle, horns and hooves, pork hooves, waste from processing fish, fur, hair, leather waste production, sheep’s wool, camel’s wool, pig bristles, cattle and (or) kangaroos, livestock bones, camels, kangaroos, any bird’s bones and pork bones begin immediately after delivery to their destination.

The first stage of the method is that pre-weighed feathers, for example, chicken, duck or ostrich from poultry farms, and (or) bristles and hair from the skins of cattle, horns and hooves, pork hooves, fish processing waste, fur, hair, waste leather production, sheep’s wool, camel hair, pig bristles, cattle and (or) kangaroos, livestock bones, camels, kangaroos, any bird’s bones and pork bones are loaded into the reaction vessel. Such a reaction vessel should be made of a material resistant to the action of concentrated alkalis and should be equipped with a locking mechanism, a stirring mechanism, an inlet valve, an exhaust valve, as well as a mechanism for automatically discharging the gaseous phase through a carbon filter.

In the second stage of the method, in some mass relation to feathers, for example, chicken, duck or ostrich from poultry farms, and (or) bristles and hairline from cattle skins, horns and hooves, pork hooves, fish processing waste, fur, hair, leather waste production, sheep’s wool, camel’s wool, pig bristles, cattle and (or) kangaroos, livestock bones, camels, kangaroos, poultry bones and pork bones in the reaction vessel into which they are added caustic potassium (KOH) and mix until mixtures.

In the third stage of the method, in some mass relation to feathers, for example, chicken, duck or ostrich from poultry farms, and (or) bristles and hairline from cattle skins, horns and hooves, pork hooves, fish processing waste, fur, hair, leather waste production, sheep’s wool, camel’s wool, pig bristles, cattle and (or) kangaroos, livestock bones, camels, kangaroos, poultry bones and pork bones are mixed with water in the reaction vessel. Before adding water, it is important to lock the reaction vessel, and water should be added in one go, as the mixture undergoes intense heating.

The fourth stage of the method is that they create conditions for the decomposition of feathers, for example, chicken, duck or ostrich from poultry farms, and (or) bristles and hair from the skins of cattle, horns and hooves, pork hooves, waste from processing fish, fur, hair, tanning waste, sheep’s wool, camel hair, pig bristles, cattle and (or) kangaroos, livestock bones, camels, kangaroos, any bird’s bones and pork bones in the reaction vessel, the decomposition is carried out within 20 hours . After about 20 hours, feathers, for example, chicken, duck or ostrich from poultry farms, and (or) bristles and hair from the skins of cattle, horns and hooves, pork hooves, fish processing wastes, fur, hair, leather wastes, sheep’s wool, camel hair, bristles of pigs, cattle and (or) kangaroos, bones of livestock, camels, kangaroos, bones of any bird and pork bones are dissolved in a locked reaction vessel with irregular, that is, stirring from time to time and under the action of caustic kali (KOH).

At the fifth stage, in some mass relation to feathers, for example, chicken, duck or ostrich from poultry farms, and (or) bristles and hair cover from animal skins, horns and hooves, pork hooves, fish processing waste, fur, hair, leather processing waste , sheep’s wool, camel’s wool, pig bristles, cattle and (or) kangaroos, livestock bones, camels, kangaroos, poultry bones and pork bones add 85% phosphoric acid to the reaction vessel. After feathers, for example, chicken, duck or ostrich from poultry farms, and (or) bristles and hair from the skins of cattle, horns and hooves, pork hooves, fish processing waste, fur, hair, leather processing waste, sheep’s wool, camel wool, bristles of pigs, cattle and (or) kangaroos, bones of livestock, camels, kangaroos, bones of any bird and pork bones will be dissolved, in the fourth stage, the prepared mixture is neutralized with 85% phosphoric acid. You can mix this acid directly into the reaction vessel with vigorous stirring of the mass contained in the reaction vessel. At this fifth stage, gas bubbles are still forming.

The sixth step of the method begins with measuring the pH, that is, measuring the degree of acidity or alkalinity of the mixture being processed. A sample is taken from the neutralized and cooled to a temperature of 20 ° C mixture to be processed to measure pH. The pH should be in the range of 6.5 ± 0.2. If the pH is outside this range, then to introduce it into the required range of values, 99% citric acid, 85% formic acid or potassium hydroxide are added to the mixture being processed.

The seventh step of the method involves adding to the mixture to be processed epsom salt, iron sulfate, boric acid, manganese sulfate, zinc sulfate, copper sulfate, ammonium molybdate and calcium nitrate.

The eighth stage of the method involves the unloading of the mixture to be processed from the reaction vessel into transport containers. Unloading depends on the mass of caustic potassium contained in the mixture being processed. The neutralized processed mixture, which is the basis of the soil enrichment agent, is discharged from the reaction vessel and, based on calculations, metered into the prepared transportation containers using a drain pump through a suitable filter while continuously stirring the mixture to be treated, which is the soil enrichment agent base and located in the reaction vessel.

The ninth stage of the method involves the preparation of a diluted mixture undergoing processing. The shipping containers are equipped with a watertight locking mechanism with the possibility of stirring the contents. Water is added to such a container with the mixture to be treated, and the entire contents of this container are stirred until homogeneous.

The tenth stage of the method involves mixing humic acids with the diluted mixture being processed in the shipping container. In this case, the formation of a keratin enrichment of the soil with the addition of humic acids in colloidal form as the final product.

A keratin soil fortifier with colloidal addition of humic acids contains feathers, potassium hydroxide, phosphoric acid, epsom salt, iron sulfate, bromic acid, manganese sulfate, zinc sulfate, copper sulfate, ammonium molybdate, calcium nitrate, humic acids and water.

Examples of preferred embodiments of the invention

Before the start of the production process, feathers, for example, chicken, duck or ostrich from poultry farms, and (or) bristles and hair from the skins of cattle, horns and hooves, pork hooves, fish processing waste, fur, hair, leather processing waste, sheep’s wool, camel hair, bristles of pigs, cattle and (or) kangaroos, bones of livestock, camels, kangaroos, bones of any bird and pork bones must be delivered, for example, from a poultry farm, in a transport container that has been approved by the veterinary service and disinfected Vann certified firm. Then the delivered feathers, for example, chicken, duck or ostrich from poultry farms, and (or) bristles and hair from the skins of cattle, horns and hooves, pork hooves, fish processing waste, fur, hair, leather processing waste, sheep’s wool, camel’s wool , bristles of pigs, cattle and (or) kangaroos, bones of livestock, camels, kangaroos, bones of any bird and pork bones are properly unloaded in a specially designated place. In order to avoid possible undesirable changes in the quality of the material, processing of feathers, for example, chicken, duck or ostrich from poultry farms, and (or) bristles and hair cover from the skins of cattle, horns and hooves, pork hooves, waste from processing fish, fur, hair, leather waste production, sheep’s wool, camel’s wool, pig bristles, cattle and (or) kangaroos, livestock bones, camels, kangaroos, any bird’s bones and pork bones begin immediately after delivery to their destination.

At the first stage of the method, pre-weighed feathers, for example, chicken, duck or ostrich from poultry farms, and (or) bristles and hair from the skins of cattle, horns and hooves, pork hooves, fish processing waste, fur, hair, leather processing waste, sheep wool, camel hair, bristles of pigs, cattle and (or) kangaroos, bones of livestock, camels, kangaroos, bones of any bird and pork bones are loaded into the reaction vessel, where P is the mass of suspended feathers, for example, chicken, duck or ostrich with poultry farm , and (or) bristles and hairline from the skins of cattle, horns and hooves, pork hooves, waste from processing fish, fur, hair, leather wastes, sheep wool, camel hair, pig bristles, cattle and (or) kangaroos bones of livestock, camels, kangaroos, bones of any poultry and pork bones, while the above reaction vessel must be made of a material resistant to concentrated alkalis and must be equipped with a locking mechanism, a mixing mechanism, an inlet valve, usknym valve, and a mechanism to automatically release the gaseous phase through the charcoal filter.

In the second stage of the method in a mass ratio of one part of caustic potassium (KOH) to one part of feathers, for example, chicken, duck or ostrich from poultry farms, and (or) bristles and hair cover from the skins of cattle, horns and hooves, pork hooves, waste from processing fish, fur, hair, leather wastes, sheep’s wool, camel hair, pig bristles, cattle and (or) kangaroos, livestock bones, camels, kangaroos, bones of any bird and pork bones to suspended feathers, for example, chicken , duck or ostrich with poultry eggs, and (or) bristles and hairline from cattle skins, horns and hooves, pork hooves, fish processing waste, fur, hair, leather waste, sheep wool, camel hair, pig bristles, cattle and (or) kangaroos Caustic potassium (KOH) is added to the bones of livestock, camels, kangaroos, bones of any bird and pig bones in the reaction vessel into which they are loaded.

In the third stage of the method, in a weight ratio, one part of water per one part of feathers, for example, chicken, duck or ostrich from poultry farms, and (or) bristles and hairline from the skins of cattle, horns and hooves, pork hooves, waste from processing fish, fur , hair, leather wastes, sheep’s wool, camel’s hair, pig bristles, cattle and (or) kangaroos, livestock bones, camels, kangaroos, any bird’s bones and pig’s bones to the mentioned suspended material (feathers, etc.) into the reaction vessel to mention oh being treated mixture is admixed with water.

At the fourth stage of the method, conditions are created for the decomposition of feathers, for example, chicken, duck or ostrich from poultry farms, and (or) bristles and hairline from the skins of cattle, horns and hooves, pork hooves, waste from processing fish, fur, hair, leather waste production, sheep’s wool, camel’s wool, pig bristles, cattle and (or) kangaroos, livestock bones, camels, kangaroos, any bird’s and pig’s bones in the reaction vessel, and decomposition is carried out within 20 hours. After about 20 hours, feathers, for example, chicken, duck or ostrich from poultry farms, and (or) bristles and hair from the skins of cattle, horns and hooves, pork hooves, fish processing wastes, fur, hair, leather wastes, sheep’s wool, camel hair, bristles of pigs, cattle and (or) kangaroos, bones of livestock, camels, kangaroos, bones of any bird and pork bones are dissolved in a locked reaction vessel with irregular, that is, stirring from time to time and under the action of caustic kali (KOH).

In the fifth step of the method, citric acid (C ₃ H ₅ O. (COOH) ₃ ), formic acid (HCOOH) or acetic acid (CH ₃ COOH) are added to the mixture to be treated. After feathers, for example, chicken, duck or ostrich from poultry farms, and (or) bristles and hair from the skins of cattle, horns and hooves, pork hooves, fish processing waste, fur, hair, leather processing waste, sheep’s wool, camel wool, bristles of pigs, cattle and (or) kangaroos, bones of livestock, camels, kangaroos, bones of any bird and pork bones will be dissolved, in the fourth stage, the mixture to be processed is neutralized with 99.99% citric acid, or 85 % acetic acid, or 80% formic acid. This acid can be mixed directly into the reaction vessel with vigorous stirring of the mass contained in the reaction vessel. At this stage, the reaction is associated with the formation of gas bubbles. In the case of citric acid (C ₃ H ₅ O. (COOH) ₃ ), for every 50 kg of 95% potassium hydroxide (KOH), 50 kg of 99% citric acid or 50 kg of 85% acetic acid is used, or 50 kg of 80% formic acid.

At the sixth stage of the method, the pH of the mixture to be processed is measured. A sample is taken from the neutralized mixture being processed and cooled to a temperature of 20 ° C and its pH is measured. The pH should be in the range of 6.5 ± 0.2. If the pH is outside this range, then to introduce it into the required range of values, 85% formic acid or potassium hydroxide is added to the mixture being processed.

At the seventh stage, to obtain a modified mixture, to feathers, for example, chicken, duck or ostrich from poultry farms, and (or) bristles and hairline from animal skins, horns and hooves, pork hooves, fish processing waste, fur, hair, waste leather production, sheep’s wool, camel hair, pig bristles, cattle and (or) kangaroos, livestock bones, camels, kangaroos, bones of any bird and pork bones are added 10-13 wt. % Epsom salt (MgSO ₄ ) in relation to the weight of feathers, for example, chicken, duck or ostrich from poultry farms, and (or) bristles and hair from the skins of cattle, horns and hooves, pork hooves, waste from processing fish, fur, hair , leather products, sheep’s wool, camel hair, pig bristles, cattle and (or) kangaroos, livestock bones, camels, kangaroos, bones of any bird and pork bones, 0.19-0.23% iron sulfate (FeSO ₄ ) in relation to the mass of feathers, for example, chicken, duck or ostrich from poultry farms, and (and l) bristles and hair from the skins of cattle, horns and hooves, pork hooves, waste from processing fish, fur, hair, leather wastes, sheep wool, camel hair, pig bristles, cattle and (or) kangaroos, bones of domestic cattle, camels, kangaroos, bones of any bird and pork bones, 0.05-0.075 wt. % boric acid (H ₃ VO ₃ ) in relation to the weight of feathers, for example, chicken, duck or ostrich from poultry farms, and (or) bristles and hair from the skins of cattle, horns and hooves, pork hooves, waste from processing fish, fur , hair, leather wastes, sheep’s wool, camel hair, pig bristles, cattle and (or) kangaroos, livestock bones, camels, kangaroos, bones of any bird and pork bones, 0.03-0.055 wt. % manganese sulfate (MnSO ₄ ) in relation to the weight of feathers, for example, chicken, duck or ostrich from poultry farms, and (or) bristles and hair from the skins of cattle, horns and hooves, pork hooves, waste from processing fish, fur, hair , tanning waste, sheep’s wool, camel hair, pig bristles, cattle and (or) kangaroos, livestock bones, camels, kangaroos, bones of any bird and pork bones, 0.008-0.02 wt. % zinc sulfate (ZnSO ₄ ) in relation to the weight of feathers, for example, chicken, duck or ostrich from poultry farms, and (or) bristles and hair from the skins of cattle, horns and hooves, pork hooves, waste from processing fish, fur, hair , tanning waste, sheep’s wool, camel hair, pig bristles, cattle and (or) kangaroos, livestock bones, camels, kangaroos, bones of any bird and pork bones, 0.008-0.02 wt. % copper sulfate (CuSO ₄ ) in relation to the weight of feathers, for example, chicken, duck or ostrich from poultry farms, and (or) bristles and hair from the skins of cattle, horns and hooves, pork hooves, waste from processing fish, fur, hair , tanning waste, sheep’s wool, camel hair, pig bristles, cattle and (or) kangaroos, livestock bones, camels, kangaroos, bones of any bird and pork bones, 0.001-0.005 wt. % ammonium molybdate ((NH ₄ ) ₆ Mo ₇ O ₂₄ ) in relation to the mass of feathers, for example, chicken, duck or ostrich from poultry farms, and (or) bristles and hairline from the skins of cattle, horns and hooves, pork hooves, waste from processing fish, fur, hair, leather wastes, sheep’s wool, camel hair, pig bristles, cattle and (or) kangaroos, livestock bones, camels, kangaroos, bones of any bird and pork bones and 17-22 wt. % calcium nitrate (Ca (NO ₃ ) ₂ ) in relation to the weight of feathers, for example, chicken, duck or ostrich from poultry farms, and (or) bristles and hair from the skins of cattle, horns and hooves, pork hooves, fish processing waste , fur, hair, leather wastes, sheep’s wool, camel hair, pig bristles, cattle and (or) kangaroos, livestock bones, camels, kangaroos, bones of any bird and pork bones.

In the eighth step of the method, the mixture to be treated is unloaded from the reaction vessel to the transportation vessels. Unloading depends on the mass of caustic potassium contained in the resulting modified mixture being processed, so that the number N of prepared shipping containers is determined by the formula N = KOH / 50, where KOH is the mass of caustic potassium. The neutralized processed mixture, which is the basis of the soil enrichment, is discharged from the reaction vessel and, based on the calculations, is metered into the prepared transportation containers using a drain pump through a suitable filter and with continuous stirring of the mixture under treatment, which is the basis of the soil enrichment and located in the reaction vessel.

In the ninth step of the method, a diluted mixture to be processed is prepared. The shipping containers are equipped with a watertight locking mechanism with the possibility of stirring the contents. Up to 1000 liters of water are added to such a container with the mixture to be treated, and the entire contents of this container are stirred until homogeneous.

At the tenth stage of the method, the humic acids are mixed with the diluted mixture in the shipping container in the amount of 10-15 wt. % humic acids by weight of suspended feathers. In this case, the formation of a keratin enrichment of the soil with the addition of humic acids in colloidal form as the final product.

Thus, 1000 l of keratin soil fortifier with colloidal addition of humic acids may contain 107 kg of feathers, 50 kg of potassium hydroxide, 50 kg of phosphoric acid, 33.75 kg of Epsom salt, 0.64 kg of vitriol, 0.19 kg boric acid, 0.14 kg of manganese sulfate, 0.03 kg of zinc sulfate, 0.03 kg of copper sulfate, 0.01 kg of ammonium molybdate, 58.98 kg of calcium nitrate, 40 kg of humic acids and at least 208.1 kg water.

Claims (11)

A method of preparing a keratin soil fortifier with colloidal addition of humic acids by treating a mixture of chicken, duck or ostrich feathers from poultry farms, and / or bristles and hair from the skins of cattle, horns and hooves, pork hooves, fish processing waste, fur, hair, leather wastes, sheep wool, camel hair, bristles of pigs, cattle and / or kangaroos, livestock bones, camels, kangaroos, bones of any bird and pork bones, containing: - the first stage in which the pre-weighed specified processed mixture is loaded into the reaction vessel, - the second stage, in which in a mass ratio one part of caustic potassium (KOH) to one part of the mixture being treated is added to the reaction vessel into which the suspended mixture to be processed is loaded, - the third stage, in which in a mass ratio of one part of water per one weight part of the specified processed mixture in the reaction vessel to the weighed specified processed mixture is added water, - the fourth stage, which creates the conditions for decomposition of the mixture being processed in the reaction vessel, the decomposition is carried out in the reaction vessel for 20 hours under conditions of stirring from time to time, - the fifth stage, which perform the neutralization, - the sixth stage, in which the pH of the mixture being processed is measured, for which a sample is taken from the neutralized mixture being processed, cooled to a temperature of 20 ° C and its pH is measured, while the pH should be in the range of 6.5 ± 0.2 if the pH is outside this range, then to introduce it into the required range of values, 99% citric acid, 85% formic acid, 80% acetic acid or potassium hydroxide are added to the mixture to be treated, - the seventh stage, in which to obtain a modified mixture to the mixture being treated add 10-13 wt.% Epsom salt (MgSO ₄ ) relative to the mass of the mixture being processed, 0.19-0.23% iron sulfate (FeSO ₄ ) according in relation to the weight of the mixture being treated, 0.05-0.075 wt.% boric acid (H ₃ BO ₃ ) in relation to the mass of the mixture being treated, 0.03-0.055 wt.% manganese sulfate (MnSO ₄ ) in relation to the mass undergoing processing the mixture 0,008-0,02 wt.% of zinc sulfate (ZnSO ₄₎ relative to the mass being treated mixture 0,008-0,02 ma .% Copper sulfate (CuSO ₄₎ in relation to the weight of the mixture being treated, 0.001-0.005 wt.% Of ammonium molybdate ((NH _{4) 6} Mo ₇ O ₂₄₎ relative to the weight of the mixture being treated and 17-22 wt.% Nitrate calcium (Ca (NO ₃ ) ₂ ) in relation to the weight of the mixture being processed, - the eighth stage, in which the mixture being processed is unloaded from the reaction vessel into the transportation containers, the discharge depends on the mass of potassium hydroxide contained in the resulting modified mixture being processed, the number N of prepared transportation containers is determined by the formula N = KOH / 50 , where KOH is the mass of potassium hydroxide, while the neutralized mixture being processed is the basis of the soil enrichment agent and is discharged from the reaction vessel and based on dose calculations Rowan loaded into shipping containers prepared by using the drain pump through a suitable filter under continuous stirring the mixture being treated, which is the basis fortifier soil and stored in the reaction vessel, - the ninth stage, in which the preparation of the diluted mixture to be processed is carried out, while in such a container with the mixture to be treated, water is added in an amount of up to 1000 l and the entire contents of this container are stirred until uniform - the tenth stage, in order to obtain a keratin soil enricher with the addition of humic acids in colloidal form as the final product, humic acids in the amount of 10-15 wt.% of humic acids from the weight of the suspension are mixed into the diluted mixture being processed in the transport container the specified mixture, characterized in that the neutralization in the fifth stage of the method is performed using citric acid (C ₃ H ₅ O (COOH) ₃ ), formic acid (HCOOH) or acetic acid (CH ₃ COOH), with every 50 kg of 95% potassium hydroxide (KOH) use 50 kg of 99% citric acid, or 50 kg of 85% acetic acid, or 50 kg of 80% formic acid.