PL160363B1 - Method of obtaining a microelements containing liquid fertilizer - Google Patents

Abstract

1. The method for manufacturing liquid fertilizer with microelements, consisting in that in the organic protein hydrolysate obtained by alkaline hydrolysis of animal protein - keratin, the solution obtained by decomposing roasted magnesite with acetic acid using for decomposition 10 per cent of the excess acid in relation to the stoichiometric standard for obtaining magnesium acetate is dissolved, introducing from 2 to 25 g Mg/dm<3>in that form to the basic solution, and then microelements are introduced in the form of salts to obtain concentrations from 0 to 5 g Fe/dm<3>, from 0 to 5 g Cu/dm<3>, from 0 to 5 g Zn/dm<3>, from 0 to 2 g Mo/dm<3>, from 0 to 2 g Mn/dm<3> and potassium in the quantity from 0.01 to 15 g K2O/dm<3>.

Description

The subject of the invention is a method of producing a liquid fertilizer, useful both in agriculture and in horticulture and horticulture, characterized by the content of fertilizing components in organic and inorganic form, and also showing protective properties.

The use of liquid fertilizers has a number of advantages over conventional fertilizers. First of all, fertilizers in this form are characterized by a higher degree of utilization of nutrients and, moreover, they can be very evenly distributed over the soil surface or under its surface using mechanical devices. In this operation, manual labor can be virtually eliminated, which is the main difficulty in using conventional fertilizers.

It is known from the publication of J. Machej et al. / Przemysł Chemiczny 1980, 2, 102, 102 / a method of producing a liquid fertilizer based on extractive polyphosphoric acid obtained by concentration of extractive phosphoric acid in an evaporator with a tunnel burner. Concentrated to 72-76 wt%. P2O5 / of which approx. 50% in the form of non-ortho / polyphosphoric acid is continuously neutralized with ammonia water and, after dilution with water, a liquid fertilizer of the 10: 34: 0 or 11: 34: 0 type is obtained. He is known from the report entitled Fluid Fertilizers, issued by the Tennessee Valley Authority National Fertilizer Development Center, Alabama 1984, a method of producing and using liquid calcium fertilizers, obtained by dispersing calcium carbonate in water with the addition of a suspension stabilizing agent. It is also known from the same agent the influence of organic substances of the lignin type and the like on the increase in the use and time of the impact of fertilizing components by plants. These compounds in the soil form permanent connections with nitrogen and other nutrients, which prolongs their action, and also reduces the overall loss of nutrients due to leaching.

However, the presented method of producing a highly concentrated liquid fertilizer is inconvenient due to the energy-consuming method of producing polyphosphoric acid. The presented method of obtaining and using liquid calcium fertilizer or the use of organic substances is characterized by a limited fertilizing effect and it is not possible without losing the fertilizing properties of these products, adding additional fertilizing ingredients or preparations eliminating the pathogenic effect.

The limitations and disadvantages of the mentioned methods can be avoided by using the method according to the invention, in which a liquid multi-component fertilizer is obtained, containing, in addition to the fertilizing macro- and microelements, also calcium and an organic substance. Moreover, the fertilizer obtained according to the method shows protective properties. The essence of the invention is a method of producing a liquid fertilizer with a multilateral fertilization effect of the contained ingredients, both in an organic and inorganic form, and a protective effect on pathogens. The use of liquid fertilizer has a number of advantages over conventional fertilizers. First of all, the fertilizer in this form is characterized by a higher degree of utilization of nutrients by plants.

The product presented according to the invention therefore has an advantageous all-round agrotechnical effect with respect to plant growth and protection, some of these features having a synergistic effect.

A process for preparing the composition according to the invention consists in that in an organic hydrolyzate of protein obtained by alkaline hydrolysis of animal protein keratin dissolved solution obtained by the decomposition of the calcined magnesite acetic acid, using for distribution to 10% excess of acid relative to the normal stoichiometric preparation of ethyl ma ^g nezowe ^ ^p in the ditch ^d addressed in the ^d-form of a solution of the azo ^{b d d} of ^0.1 Mg 25 g / dm ^3, and then in seq ^ę ditch ^{p d} t ^o for trace elements in the form of soh ^d st ^E with ^{ñ 0 , 1} to ^5g FeMm ³ from ^0.1 to ^5g Cu / dm ^3, o ^{d 0.1 d} o ^5g Zn / dm ³ o ^{d 0,} 1 ^d o 2g ^M o ^{/ d} m ^3, o ^{d 0.1 d} o 2 ^{g M} n / ^d m ^{3 and 0.01} to ^{15 g} K / dm3, the obtained clear fertilizing solution also contains protein hydrolyzate components in the form of polypeptide combinations in the amount of 50 to 100 g N / dm ³ 4 to 10 g PzOs / dm and from 30 to 40g CaO / dm ³ .

It turned out that the agent has favorable properties if the microelements are introduced in the following form: iron in the form of copper sulphate, zinc in the form of zinc sulphate, boron in the form of sodium borate or boric acid, molybdenum in the form of a molybdate salt or molybdenum waste solution from the etching process of this element , manganese in the form of manganese sulfate and potassium in the form of potassium hydroxide or potassium chloride.

Unexpectedly, it turned out that the agent has synergistic and protective properties of the contained magnesium acetate and polypeptide combinations, as well as optimal bioavailability of nutrients at the content of: 60-80 g / dm ³ N, 4.5 g / dm ³ P2O5, 8 g / dm3 K2O, l , 2g / dm ^{3 Mg 35g / d} m ³ Ca ° ^{2g /} dm ^3F e ² g / dm ³ Cu ^{2g / d} m ^{3 Z} n, ^l g ^/ dm ³ B ^{, lg / d} m ^{3 M} o, lg / dm ³ Mn.

The technological process is carried out in such a way that the alkaline hydrolysis of keratin with lime milk is carried out. Obtained hydrolyzate having, inter alia, ^{120g of} 60% ^{N /} m, ^{5 P 2 O} 5 -7 g / dm ^3, and ²⁵ - ^50g Ca ^{O / d} m ^3. Hy roHzat ^d is the ^d joints ^y m of the liquid fertilizer components, which are dissolved are: a reaction product of the decomposition is injured by ^p nez ^{g of} acetic acid there ^{s d d y} m avant The quantities of ^d of ^d of ^{0.1 Mg 25 g} / l ³ in terms of this element, from 0 ^ 1 to 5g Fe / dm3, copper and zinc added in the form of sulphate salts, from 0.1 to 2g Mo / dm3 added as a molybdate salt or waste acid molybdenum solution from the etching process of this metal and from 0.1 to 2 g Mn / dm ³ added in the form of manganese sulphate. Potassium is then introduced in an amount of from 0.1 to ^{15 g} K2 ^{O /} m ^{3 d p stand} to Son ^l of potassium wodorotten ^{b k} u.

The resulting solution of the invention is a finished product having a density of from 1 to 1.22 ^{kg /} dm ^{3, pH 6.5} to ^8.5 and tepko & ^d of ¹⁰ to ^{50 cp. In} ylew ^al wear ^{Æ g} Otow ^g of product away ^{and d} of 98 to 100%. This product is packed into unit packages. The production method is explained in the following examples:

Example 1. The solution obtained by decomposing 20.64 kg of calcined magnesite with anhydrous acetic acid in the amount of 67.65 kg was introduced into the reactor, and it was dissolved in the protein hydrolyzate in the amount of 223 dm3 obtained by the alkaline hydrolysis of the animal protein - keratin. Then 18.6 dm3 of the waste acid molybdate solution from etching this metal and 10 kg of ferrous sulphate (FeSO4 7H2O), 8 kg of copper sulphate (CuSCM 5H2O), 9 kg of zinc sulphate (ZnSO-7H2O) were introduced into the reactor. 9 kg of borax / EXCLUSIVE Cb IOH2O / and 3 kg of magnesium sulphate / MnSC4 H2O /. After thorough mixing to dissolve the components listed introduced lOkg KOH and were homogenised for intens mieszame ^s Century ^{D p} etaego rozpuszczema. In ^y N & obtained in ^{1 m3} of fertilizer clear

160 363 liquid with micronutrients, density 1.17 kg / dm, pH = 8, viscosity 33 cP, flow rate 99.5%. 1 dm ^{3 of} fertilizer contains 54g N, 4g P2O5, 8kg K2O, 12.5g Mg, 35g CaO, 2g Fe, 2g Cu, 2g Zn, lg B, lg Mo, lg Mn.

Example Π. To the reactor was added a solution obtained by decomposition of 16,5kg of calcined magnesite anhydrous acetic acid in an amount of 54,12kg and dissolved in ^{180 d} m ³ h ^ rohzatu ^{b Lk} and a detailed ^g o. ^{P N} ASTE is not of the reactor ^{d p d} trench bride, ² kg moles of sodium / Na2MoO4 2H2O /, 6.4 kg of copper sulphate / CuSO4 5H2O /, 7.2 kg of zinc sulphate / ZnSO4 7H2O /, 29 kg of borax / Na2B4Ch IOH2O /, and 2.4 kg of manganese sulphate / MnSO4 H2O /. After mixing, 10 kg of potassium salt / KCk was introduced until the solids were dissolved. The mixture was again vigorously stirred to obtain a clear liquid solution of the Estonian ^{COG g} of ⁴ M k ^ m ^{3, pH} = ^8, bk ^{p th} wheel ⁹ cP wytewno ^{R, 5%. 1 d} m ^{3 of} fertilizer contains 56g N, 6.5g K2O, 10g Mg, 36g CaO, 1.6g Fe, 1.6g Cu, 1.6g Zn, 0.8g B, 0.8g Mo, and 0, 8g Mn.

The Publishing House of the Polish Patent Office. Mintage 90 copies. Price: PLN 10,000

Claims (2)

Patent claims 1. Method for the production of liquid fertilizer with microelements, characterized in that in the organic protein hydrolyzate obtained by the alkaline hydrolysis of the animal protein - keratin, the solution obtained by decomposing the roasted magnesite with acetic acid is dissolved, using a 10% excess of acid in relation to the stoichiometric standard of acetate production for decomposition magnesium, introducing in this form into the base solution from 0 to 25 gMg / dm ³ , and then introducing microelements in the form of salt to concentrations from 0 to 5g FeMm ^, with ^{d 0} to ^{5 g} Cu ^{/ d} m ^{3, d 0 d} o ^{5 g n} / dm ^3, a ^{0 d d} of Mo ^2g / dm ^3, a ^{0 d d} Mu about ^{2g /} dm ^{3 ip} in otasu It claims ^d of ^0.01 to ^{15 g} foo / dm ^3. 2. The method according to p. A method according to claim 1, characterized in that the microelements are introduced in the following form: iron in the form of ferrous sulfate, copper in the form of copper sulfate, zinc in the form of zinc sulfate, boron in the form of sodium borate or boric acid, molybdenum in the form of a molybdenum salt or molybdenum waste solution from the digestion process of this element, manganese in the form of manganese sulphate and potassium in the form of potassium hydroxide or potassium salt.