UA16029U - Method of obtaining a feed additive - Google Patents

Abstract

A method of obtaining a feed additive relates to feed additive production. The method includes binding micronutrients with an organic carrier. Aqueous solutions of inorganic salts of iron and cobalt, while being heated, is slowly mixed with an aqueous solution of glycine and the mixture obtained is evaporated by four times.

Description

Description of the invention

The useful model refers to the production of feed additives and can be used in the production of 2 mineral additives for the enrichment of compound feed with microelements.

The use of a concentrated type of compound feed in poultry farming imposes certain requirements on the provision of trace elements to the bird's body, as the nutritional components of compound feed partially satisfy the need for them, which requires their additional introduction. Various types of feed additives are used as sources of trace elements, most of which contain trace elements in an inorganic form. Due to the fact that inorganic compounds of trace elements are mostly characterized by different hygroscopicity, solubility and reaction mobility, which creates certain difficulties when using them as part of compound feed, in addition, they inactivate vitamins and other biologically active substances. It is well known that inorganic substances significantly enhance their physiological effect when they are included in organic complexes (chelates).

A known method of obtaining a feed additive, which consists in the fact that to obtain trace elements in organic form, microorganisms are incubated in the presence of a source of trace elements | see example -

Patent of the Russian Federation, KO Mo2056762, A2ZK1/00 dated 03.27.96 Bull. Mo 9).

A known method of synthesis of chelate compounds of trace elements, in particular, iron, during the interaction of solutions of their sulfates in an alkaline environment with amino acids. | See for example - A.I. Sparrow, M.S. Zedyak Synthesis and biological activity of microelement chelates // Poultry Republic. between subject of science coll. - Kyiv, 1982. -

Harvest vol. 33. P. 8-12).

The closest in terms of technical essence and the achieved result is the method used for the synthesis of chelated compounds of microelements for the purpose of use in animal husbandry | see for example - R.Y. Kravtsiv, M.3.

Easter cake. To the method of synthesis of chelated compounds of trace elements for the purpose of use in animal husbandry // Scientific Bulletin of the Lviv State Academy of Veterinary Medicine named after P.3. Gzytskoho - L., 2001. - Volume 3. - Mo 4, V.Z - 29 b. 53-57). The essence of the known method consists in obtaining a solution of sodium salts of amino acids, followed by obtaining chelate compounds with ions of divalent metals Сy? sulfate of the corresponding metal in a ratio of 2:71, the mixture is cooled to 2-42C, the precipitate that falls out is filtered and dried at 702C for 75 hours.

The disadvantage of the known method is the complexity and multi-stage synthesis process, significant duration, which is associated with significant energy consumption, the need for additional chemical reactions to obtain sodium salts of amino acids, which is associated with the consumption of chemical reagents. In addition, the same synthesis conditions are used to obtain compounds from different metals, which leads to a decrease in the yield of the final product. (Se)

A useful model is the task of increasing the efficiency and manufacturability of obtaining a feed supplement enriched with microelements, in which the microelements are in the form of organic compounds.

The task set by the useful model is achieved by the fact that in the method of obtaining a feed additive, which involves the binding of microelements with an organic carrier, according to the useful model, aqueous solutions of inorganic salts of iron and cobalt are slowly mixed with an aqueous solution of glycine when heated to 602C, after which they are evaporated obtained mixtures four times, while the concentration of aqueous solutions in the systems iron glycine and pt) with cobalt : glycine are 36 and 2295 and 44 and 2395 with their ratio by mass of 1.5:1 and 1:1, respectively, while the evaporated solution complex iron compound is dried at 8092 for 24 hours and ground;" formed crystals, and ethyl alcohol in the amount of 1/3 of its volume is added to the evaporated solution of the cobalt complex compound and thoroughly rubbed; the formed crystalline precipitate is washed with water, alcohol and dried, and as sources of microelements, iron sulfate (ЖЙ) Reg(5О4)39Н20 and hexahydrate cobalt chloride СоСи»бНО.О are used, and distilled water is used as a solvent.

The implementation of the method is illustrated by examples in which optimal concentrations and ratios are used

Means of reacting components and parameters of the synthesis process. Their increase or decrease does not lead to an increase in the efficiency and manufacturability of the synthesis process.

Example 1. In the synthesis of a complex compound of iron with glycine, iron sulfate ЕРе4(50,)59Н20 of the "khch" brand and glycine of the "h" brand were used.

Ge) The synthesis of the complex compound was carried out as follows. 28.1 g of ferrous sulfate was added to 50 ml of distilled water when heated to 602C and a solution of glycine (11.25 g in 40 ml) was slowly added. At the same time, the color of the solution changes from brown to almost red. The change in color is the first evidence of a change in the immediate environment of the iron atom, i.e., the formation of a complex with glycine. The resulting solution is evaporated 4 times, and precipitation does not occur, and the solution itself acquires a thick consistency. The obtained product is dried at a temperature of 809 for 24 hours. The resulting dry substance grinds well and has a reddish-brown color.

Example 2. In the synthesis of a complex compound of cobalt with glycine, cobalt hexahydrate chloride 60 СОСИ»бНОЙ grade "хх" and glycine grade "х" were used. The synthesis of the complex compound was carried out as follows. IN

24g of cobalt chloride was dissolved in 30ml of water when heated to 602, 15g of glycine was dissolved in 5O0ml of water, the solutions were drained and evaporated four times, the mixture of solutions acquired a thick consistency. Then 5 ml of ethyl alcohol was added to it and thoroughly rubbed. During grinding, a crystalline precipitate is formed. The precipitate that fell out was collected on a filter, washed with cold water, alcohol and dried. 65 Based on the physicochemical properties of amino acids, inorganic and organic salts of iron and cobalt, and on the basis of studies of the molecular structure of the obtained complex compounds according to the content of glycine, metal and acid residue, it was established that they correspond to the general formulas - iron glycinate (BRe(с1u)3( 504)25Н201; - cobalt glycinate (Со(с1у)»СИ»2НоОИ.

The composition and structure of the obtained complex compounds were confirmed by means of IR spectra. Dissociation constants and stability constants of amino acid complexes, as well as valence and deformation vibrations of amino groups and symmetric and asymmetric vibrations of carboxyl groups of iron and cobalt glycinates correspond to the formula and structure of the obtained compounds. Organoleptic studies have established that iron glycinate is a brown-reddish powder with a slight fruity smell, sour-salty taste, well soluble in water - 180g/l at a temperature of 42022 and 435g/l at 402C, and in a 0.1N solution of hydrochloric acid, its solubility is 250 g/l at 202 and 640 g/l at 1402C. Cobalt glycinate is a pink, odorless powder, slightly salty in taste, dissolves well in water and in 0.1 N hydrochloric acid solution. Its solubility at a temperature of 402C in water or 0.1 N hydrochloric acid solution is more than 1000 g/l.

The toxicity of complex compounds of iron and cobalt for white laboratory mice according to the LdD indicator at 75 oral administration is for iron glycinate - more than 500Omg/kg of body weight, cobalt glycinate - 106bOmg/kg of body weight. According to the classification of poisonous substances according to the degree of danger (GOST 12.1.007.76), cobalt glycinate belongs to the III toxicity class and is considered moderately toxic, and iron glycinate - to the IM toxicity class and are low-toxic compounds. The expediency of using complex compounds of iron and cobalt with the amino acid glycine, obtained according to the claimed useful model and which are recommended to be included in compound feed, was also tested on laboratory rats. Thus, long-term administration of iron and cobalt glycinates in different doses compared to sulfates of these elements to purebred white laboratory rats does not affect clinical and hematological indicators, behavior and feed consumption by animals, increases the activity of a number of digestive and tissue enzymes, does not cause the accumulation of trace elements in the liver, which indicates their intensive use in their own metabolic processes.

Scientific and industrial experiments were conducted to check the effectiveness of the feed additive. The material for the research was day-old KOBB-500 cross-bred chickens, which for 42 days were fed the chelate compounds of Re and Co with the amino acid glycine obtained, according to the proposed useful model, with the control feeding of compound feed with sulfates of these metals.

The use of iron and cobalt compounds in the feed of broiler chickens increases the biological (o) availability of trace elements for the body, ensures better assimilation in the digestive tract, does not affect the clinical condition, improves hematological indicators, stimulates metabolic processes in body tissues, contributes to the growth of live weight and reducing feed costs per kg of bird weight gain. ("in

Thus, feeding chelated compounds of iron and cobalt to poultry for 42 days with 10095 livestock preservation provided an increase in average daily gains from 21 to 42 days by 194965 and 20.2995, while the consumption of

Forage per kg of growth decreased by 9.38-14.0695 and 8.02-12.8395, respectively. In comparison with the known method, the efficiency of the proposed useful model is 18-3095 higher in terms of the output of the final product.

Claims (2)

The formula of the invention « 40 - c 1. The method of obtaining a feed additive, which includes the binding of microelements with an organic carrier, which differs in that aqueous solutions of inorganic salts of iron and cobalt, when heated to 6092C, are slowly mixed with an aqueous solution of glycine and the resulting mixture is evaporated four times . 2. The method of obtaining a feed additive according to claim 1, which differs in that the concentration of aqueous solutions in 45 systems of iron, glycine and cobalt, glycine is 36 95 and 22 95 and 44 95 and 23 95 with a mass ratio of 1.5:1 and 1:11, respectively, at the same time, the evaporated solution of the iron complex compound is dried at 802 for 24 FU hours and ground, and ethyl alcohol in the amount of 1/3 of its volume is added to the evaporated solution of the cobalt complex compound, thoroughly ground, the formed crystalline precipitate successively washed with water, alcohol and (av) dried. 7 50 3. The method of obtaining a feed additive according to claims 1 and 2, which differs in that iron sulfate (P)Ре5(50О03)539Н2О and hexahydrate cobalt chloride СоСи are used as a source of trace elements. bno, and as a solvent - distilled water. Official bulletin "Industrial Property". Book 1 "Inventions, useful models, topographies of integrated 29 microcircuits", 2006, M 7, 15.07.2006. State Department of Intellectual Property of the Ministry of Education and Science of Ukraine. 60 b5