SK5789Y1 - Method for preparation of keratin fertilizer with admixture of humin acids in colloidal form and keratin fertilizer with admixture of humin acids - Google Patents

Abstract

Weighted feathers are placed into a reaction vessel and potassium hydroxide (KOH) is added. Then water is added to the prepared mixture and decomposition of the feather is realized in the closed reaction vessel. Later, phosphoric acid is added to the reaction vessel in order to neutralize the prepared mixture, then pH of the mixture is measured and in a case of bigger deviation the pH is adjusted by adding of phosphoric acid or potassium hydroxide. After it magnesium sulphate, iron sulphate, hydroboric acid, manganous sulphate, zinc sulphate, cupric sulphate, ammonium molybdate, calcium nitrate are added. The mixture is divided into prepared transport containers, where the distribution depends on the weight of potassium hydroxide content in the prepared mixture. The neutralized mixture, what is "the basis of the fertilizer" is distributed from the reaction vessel on the basis of calculation into the prepared transport containers with the aid of draining pump through a suitable filter at continuous stirring of the prepared mixture (the basis of the fertilizer) in the reaction vessel. The transport containers are watertight-closing containers with possibility of mixing. Water is added into the container with the prepared mixture and it is fully mixed. Then humin acids are added into the prepared diluted mixture in the transport container and finished keratin fertilizer with addition of humin acids in colloidal form is set up.

Description

The invention relates to a process for the preparation of a keratin fertilizer with the addition of humic acids in colloidal form.

BACKGROUND OF THE INVENTION

In the published Slovak patent application PP 1539-2003 is described an additive for fertilizer containing organically bound nitrogen for the production of granular or liquid fertilizer, which consists of a mixture of unprocessed or granular treated corners and digging bovine with a moisture content of up to 12% by weight, containing up to 18% organically bound nitrogen of a protein nature, the granules of treated horns and hooves of cattle being from 0 to 12 mm. At the same time, the present invention provides a process for the production of an organic nitrogen fertilizer additive for the production of a granular or liquid fertilizer, according to which the mixture is poured into a process vessel, for example a reactor. To the mixture is added 100% potassium hydroxide (KOH) in a weight ratio of min. 1: 2 to the amount of mixture to be treated and the contents of the process vessel are poured into 200 l of water. The mixture may be stirred or heated in the liquor bath. After dissolution, it is neutralized by the addition of 50 liters of 85% phosphoric acid. After neutralization, it can be enriched with other nutrients such as NO ₃ , Mg, Fe, Co, B, Mn, Zn, Cu and the like. Finally, the solution is quenched to 1000 liters with water (H 2 O).

In terms of plant nutrition, the nitrogen content of the soil is the most important, although the presence of phosphorus and sulfur also has a positive effect. Since it is organically bound in the soil, it is released gradually. The decomposition of the albuminoid substances changes first to ammonia (NH ₄ ) ⁺ and further oxidation to the nitrate form (NO 3).

The fertilizers produced so far usually have a low nutrient content. The nitrogen present is in nitrate form, to a lesser extent ammonium. In extracorporeal application, amidic nitrogen acts less necrotic on plant tissue. In combination with other forms of nitrogen it allows for better utilization of this nutrient by plants.

Furthermore, a process for producing compost according to the Hungarian invention, patent no. 205 336 A, high in organic matter with a stimulating and alternative ameliorative effect, using an additive containing keratin and pig manure. The production process consists in separating the liquid pig manure into a solid and a liquid part by phase separation. The solid is mixed with keratin-containing substances (fur, horn). The base material thus formed contains 5 - 50% keratin material. The base material is mixed with 2-8% slaked lime, 5-10% alginite, 5-10% riolite tufa and 10-20% peat. Taking into account its total weight, the resulting mixture is further homogenized after addition of 10% keratin additive. The well-mixed compost is then granulated. The grave humidity of 65-80% is ensured by a liquid containing 5-20% dissolved keratin. The tomb is stirred after 1-2 months.

According to the Hungarian invention, no. No. 205 739 A, a matrix is known for slowly degrading biofertilizer enriched with trace elements and with a high organic content using keratin. The process for producing this mixture is as follows. Keratin-containing substances are mixed with slaked lime. In an autoclave, with stirring, they are subjected to a heat treatment with a simultaneous pressure change. The hot meat is filtered and filled into containers. The organic fertilizer mass thus obtained is supplemented with trace elements as necessary.

Said fertilizers with keratin additives are technologically demanding, time consuming and require a certain time before its application and at the same time heat treatment increases the costs of its preparation.

The essence of the technical solution

The essence of the solution according to the present invention consists in a process for preparing a keratin fertilizer with the addition of humic acids in colloidal form and a fertilizer produced in this way, which is obtained by processing feathers from a poultry plant.

Before the start of the production process, feathers are fed from a poultry plant in a transport container approved by a veterinary authority and carried out by a valid disinfection by an authorized company. The feather is then emptied from the container to a suitable place. The processing of the feathers is carried out immediately after arrival at the designated location in order to prevent undesirable qualitative changes in the feathers.

In the first step, the weighed feathers are placed in the reaction vessel, the reaction vessel being made of a material resistant to concentrated alkalis with the possibility of closing, stirring, with an outlet and inlet valve and equipped with a self-draft through a carbon filter.

In a second step, potassium hydroxide (KOH) is added to the weighed down reaction vessel in proportion to the weight of the weighed down.

SK 5789-1

In a third step, water is added to the prepared mixture in the reaction vessel in proportion to the weight of the weighed feather. Before adding water, the reaction vessel should be closed and water must be added at once, as the mixture is heated very strongly.

In a fourth step, a feathering decomposition lasting 20 hours occurs in the reaction vessel. In a sealed reaction vessel, stirring occasionally for 20 hours, the feathers dissolve by treatment with potassium hydroxide (KOH).

In the fifth step, 85% phosphoric acid is added to the prepared mixture in the reaction vessel in proportion to the weight of the feather weighed. After the feathers dissolved in the fourth step, the prepared mixture was neutralized with 85% phosphoric acid. This can be added directly to the reaction vessel with vigorous stirring. In this fifth step, the reaction associated with short-term foaming takes place.

In a sixth step, the pH of the prepared mixture is measured. A sample is taken from the neutralized mixture to be prepared, cooled to 20 ° C and its pH measured. The desired pH should be in the range of 6.5 ± 0.2. In case of major deviation, the pH should be adjusted with 85% phosphoric acid or potassium hydroxide.

The seventh step involves the addition of magnesium sulfate, iron sulfate, boric acid, manganese sulfate, zinc sulfate, copper sulfate, ammonium molybdate, calcium nitrate.

The fourth step involves the separation of the prepared mixture from the reaction vessel into the prepared transport vessels, the distribution being dependent on the weight of the potassium hydroxide contained in the prepared mixture. The neutralized feed mixture being the " fertilizer base " is separated from the reaction vessel by recalculation into the prepared transfer containers by means of a drain pump through a suitable filter while stirring the mixture being prepared (fertilizer base) in the reaction vessel.

The ninth step involves the preparation of a diluted mixture to be prepared. Transport containers are waterproof closable containers with the possibility of mixing. In such a container with the prepared mixture (fertilizer base) water is added and mixed thoroughly.

The tenth step involves the addition of humic acids to the diluted preparation of the transport container to form a finished keratin fertilizer with the addition of humic acids in colloidal form.

Solution examples

Before the start of the production process, feathers are fed from a poultry plant in a transport container approved by a veterinary authority and carried out by a valid disinfection by an authorized company. The feather is then emptied from the container into a suitable place. The processing of the feathers is carried out immediately after being transported to the designated location in order to prevent undesirable qualitative changes in the feathers. The feather is pressed from water, which is normally carried out in a poultry house and has a humidity of 25 to 29%. This means that for example, from 300 kg of wet feather delivered from slaughter of poultry, we get approximately 107 kg of dry feather (300: 2.8 ~ = 107), so we have approx. 193 liters of water.

In the first step, it is placed on the weighed feathers in a reaction vessel, where P - is the weight of the weighed feather, the reaction vessel being made of resistant alkali-resistant material with the capability of closing, stirring, drain and inlet valve .

In a second step, 15-18% by weight of KOH is added to the weighed feather reaction vessel relative to the weight of the weighed feather.

In a third step, 2.5-2.9% by weight of water is added to the prepared mixture in the reaction vessel relative to the weight of the feather weighed. Before adding water, the reaction vessel should be closed and water must be added at once, as the mixture is heated very strongly.

In a fourth step, a feathering decomposition lasting 20 hours occurs in the reaction vessel. In a closed reaction vessel, stirring occasionally for 20 hours, the feathers are dissolved by treatment with potassium hydroxide (KOH).

In a fifth step, 15-18% by weight of 85% phosphoric acid H ₃ PO ₄ is added to the prepared mixture in the reaction vessel in proportion to the weight of the feather weighed. After the feathers were dissolved in the fourth step, the prepared mixture was neutralized with 85% phosphoric acid. This can be added directly to the reaction vessel with vigorous stirring. In this fifth step, the reaction associated with short-term foaming takes place.

In a sixth step, the pH of the prepared mixture is measured. A sample is taken from the neutralized mixture to be prepared, cooled to 20 ° C and its pH measured. The desired pH should be in the range of 6.5 ± 0.2. In case of major deviation, the pH should be adjusted with 85% phosphoric acid or potassium hydroxide.

The seventh step involves the addition of 10-13% by weight of magnesium sulfate MgSO ₄ relative to the weight of the weighed feathers, 0.19 to 0.23% by weight of ferrous sulfate FeSO ₄ in relation to the weight of the weighed feathers, 0.05 to 0.075% by weight of boric acid H ₃ BO ₃ in relation to the weight of the weighed feather, 0.03 to 0.055% by weight of manganese sulphate MnSO ₄ relative to the weight of the weighed feather, 0.008 - 0.02% by weight of zinc sulphate ZnSO ₄ relative to the weight of the weighed feather, 0.008 - 0, 02% by weight of copper sulphate CuSO ₄ in relation to the weight of the weighed feather, 0,001 - 0,005% by weight of mo3

571 ammonium lybdate (NH ₄ ) ₆ Mo ₇ O ₂₄ in relation to the weight of the weighed feather, 17 - 22% by weight of calcium nitrate Ca (NO ₃ ) ₂ in relation to the weight of the weighed feather.

The eighth step involves dividing the prepared mixture from the reaction vessel into the prepared shipping vessels, the distribution being dependent on the weight of the potassium hydroxide contained in the prepared mixture N = KOH / 50, where N - the number of vessels required and KOH - the weight of the potassium hydroxide contained. The neutralized feed mixture being the " fertilizer base " is separated from the reaction vessel by recalculation into the prepared transfer containers by means of a drain pump through a suitable filter while stirring the mixture being prepared (fertilizer base) in the reaction vessel.

The ninth step involves the preparation of a diluted mixture to be prepared. Transport containers are waterproof closable containers with the possibility of mixing. In such a container with the prepared mixture (fertilizer base), make up to 1000 liters of water and mix thoroughly.

The tenth step involves the addition of 10-15% by weight of humic acids relative to the weight of the weighed feather, into the diluted preparation of the transport container to form a finished keratin fertilizer with the addition of humic acids in colloidal form.

1000 liters of keratin fertilizer with addition of humic acids in colloidal form, contains 107 kg of feathers, 50 kg of potassium hydroxide, 50 kg of phosphoric acid, 33.75 kg of magnesium sulfate, 0.64 kg of ferrous sulfate, 0.19 kg of boric acid, 14 kg of manganese sulphate, 0,03 kg of zinc sulphate, 0,03 kg of copper sulphate, 0,01 kg of ammonium molybdate, 58, 98 kg of calcium nitrate, 40 kg of humic acids and at least 208,1 kg of water.

Claims (1)

Process for preparing a keratin fertilizer with an addition of humic acids in colloidal form, characterized in that weighed feathers with a moisture content of 25 to 29% are placed in the reaction vessel, then 15-18% by weight of KOH in KOH in the weighed reaction vessel are added. relative to the weight of the weighed feather, then 2.5-2.9% by weight of water in proportion to the weight of the weighed feather is added to the prepared mixture in the reaction vessel, followed by a 20-hour decomposition of the feather in a closed reaction vessel with occasional mixing. 15-18% by weight of 85% phosphoric acid H ₃ PO ₄ in proportion to the weight of the weighed feather is added in the reaction vessel, then the pH of the prepared mixture is measured, where a sample is taken from the neutralized prepared mixture, cooled to 20 ° C and its pH is measured, the desired pH of the prepared mixture being in the range of 6.5 ± 0.2, where sweat M in the case of greater deviations should be pH adjusted by the addition of 85% phosphoric acid or potassium hydroxide, followed by addition of 10-13% by weight of magnesium sulfate MgSO ₄ relative to the weight of the weighed feathers, 0.19 to 0.23% by weight of ferrous sulfate _FeSO4 relative to the weight of the weighed feather, 0.05-0.075% by weight of boric acid H ₃ BO ₃ relative to the weight of weighed feather, 0.03-0.055% by weight of manganese sulphate MnSO ₄ relative to the weight of weighed feather, 0.008-0.02 % by weight of zinc sulphate ZnSO ₄ in relation to the weight of the weighed feather, 0.008 - 0.02% by weight of copper sulphate CuSO ₄ in relation to the weight of the weighed feather, 0.001 - 0.005% by weight of ammonium molybdate (NH ₄ ) ₆ Mo ₇ O ₂₄ relative to weight of feather weighed, 17 - 22% by weight of calcium nitrate Ca (NO ₃ ) ₂ in proportion to the weight of weighed feather, reaction vessel to prepared transport containers, in which it is diluted with water if necessary and mixed thoroughly, followed by the addition of 10-15% by weight of humic acids in proportion to the weight of weighed feathers, into the diluted preparation mixture in the transport container. by adding humic acids in colloidal form.