PL195177B1 - Method of obtaining a foliar fertiliser constituting a borom compound, preferably orthoboric acid - Google Patents

Abstract

. Method for the preparation of a foliar fertilizer containing a boron compound by dissolving and chelation of the anionic group with boron, characterized in that it is first produced suspension of the boron compound by dissolving it in water at 55-65 ° C and then continuing while stirring and maintaining the same temperature range of 55-65 ° C, the suspension is directly processed chelation with amino alcohol-ethanolamine in an amount of 60-65% by weight based on the compound boron, dosed at a rate of preferably 1 dm3 / min, the boron compound being dissolved in water is carried out in at least two stages: 50-65% of the total weight is dissolved in the first stage dosing at a rate of preferably 5 kg / 4 min, and in the second or final, the remaining amount, not faster than 1 kg / min.

Description

Description of the invention

The present invention relates to a process for the preparation of a foliar fertilizer comprising a boron compound with chelated boric ion, preferably orthoboric acid.

One of the necessary agrotechnical treatments leading to crop optimization is the use of foliar fertilization. Each plant needs a whole set of macro and micronutrients for its proper development. Most often they are delivered in the form of organic and mineral fertilizers after the soil has been examined and the needs of the crop species have been balanced. However, some components are not taken up due to air and soil temperature, soil pH or ion antagonisms. To prevent this, nutrient deficiencies are supplemented by applying foliar fertilizers. As microelements, foliar fertilizers include the following elements: B, Mo, Cu, Fe, Mn, Zn, Ti. For better digestibility by plants, the elements require chelation. The most commonly used chelating agents are: ethylenediaminetetraacetic acid and its derivatives: citric acid and its derivatives, ascorbic acid and lignosulfonic acids.

Various fertilizing agents intended for foliar fertilization as well as methods of their preparation are known.

Polish patent description No. 160 585 describes a multi-component liquid fertilizer for foliar feeding of beetroot, rape and legumes. The fertilizer is in the form of an aqueous solution containing magnesium introduced in the form of chloride and chelated with citric acid or its ammonium, sodium or potassium salt microelements: Fe, Zn, Cu, Mn, B and Mo, of which Zn, Cu and Mn are introduced as chloride, Fe as sulphate and Mo as ammonium molybdate. The essence of the solution is boron in the form of sodium metaborate.

On the other hand, the Polish patent in 168 045 shows a method of producing a fertilizer micronutrient concentrate by dissolving known microelements in an aqueous solution containing salts of ethylenediaminetetraacetic acid, preferably in the amount of 10% to 75% in a stoichiometric ratio to the introduced microelements. The production method consists in dissolving boron in an amount corresponding to 0.9% by weight in the finished product, molybdenum in an amount corresponding to 0.02% by weight of Mo in the finished product, and cobalt in an amount corresponding to 0.003% by weight in the solution. What is in the finished product, copper in an amount corresponding to 0.05% by weight to 1.2% by weight of Cu in the finished product, zinc in an amount corresponding to 0.05% by weight to 1.5% by weight of Zn in the finished product, manganese in the amount of corresponding to 0.05% by mass to 2.0% by mass of Mn in the finished product and at a neutral or slightly acidic reaction of the solution and a temperature from 308K to 363K. Then, iron in the solution is dissolved in an amount corresponding to 1.8% by mass of Fe in the finished product, at the pH of the solution lower than 6 and the temperature from 308K to 363K. In turn, magnesium is dissolved in an amount corresponding to 0.5% by weight to 6.0% by weight of Mg in the finished product and urea is added in an amount corresponding to 0.5% by weight to 15% by weight of nitrogen in the finished product, keeping the temperature above 308K, then the pH of the finished product is adjusted to a value in the range from 3 to 7. Boron is introduced into the solution in the form of boric acid or sodium borate.

There is also known from Polish patent description No. 178 364 a method of obtaining a liquid fertilizer concentrate with microelements, especially for foliar feeding, in the form of an aqueous clear solution consisting of nitrogen introduced in the form of ammonia and urea, and boron in the form of sodium metaborate and micronutrients: copper, zinc, manganese introduced as sulphate and / or chloride. A process characterized in that citric acid, preferably and / or ammonium citrate and / or sodium citrate and / or potassium citrate, and / or EDTA, and / or salt are successively dissolved in a strongly alkaline medium in a strongly alkaline dilute ammonia water with continuous stirring. EDTA sodium. The following microelements are introduced into the solution: copper, zinc, manganese in the form of sulphate and / or chloride and urea, and then dissolved boric acid in sodium hydroxide solution is added in such an amount that the fertilizer contains 0.45-0.55% boron maintaining the mutual ratio of microelements Cu: Zn: Mn: B = 1: 3: 3: 1 with the tolerance of individual components ± 10%, where the microelements are complexed with ammonia and the above-mentioned organic complexons.

In the fertilizers mentioned, the chelation of boron in a mixture of cations and anions is carried out with the use of known chelating agents, mainly: ethylenediaminetetraacetic acid and its derivatives and citric acid and its derivatives. As a result, it is true that chelated boron is obtained, but in an amount of at most 0.9% by weight and with a structure not very stable.

PL 195 177 B1

The action taken - dictated by the needs of the market - to increase the content of chelated boron in the fertilizer with the use of the chelating substances used so far, did not bring any results, both due to the difficulties in chelation of boron occurring individually and in higher concentration, as well as adverse effects on the soil resulting from the increase in the amount of chelator.

When solving this problem, attention was drawn to the method of producing a chelated iron fertilizer, preferably crystalline, described in the Polish patent application P.342553.

The method according to the application P.342553 of the invention consists in using at least two chelating substances in the process and first producing at least one of the sodium salts of ethylenediaminetetraacetic acid and / or its derivatives. During the formation of this salt, it is added to it until a clear solution of another chelating substance is obtained - monoethanolamine, which also reacts with the acid from the ethylenediaminetetraacetic group. Then, almost immediately after the completion of the reaction, an aqueous solution of the iron salt, suitably ferrous sulfate, is introduced into the solution, and after chelation of the Fe ²⁺ ion, the pH of the solution is adjusted to a stabilized level of 4-4.7, preferably with lactic acid and / or citric acid and possibly spray-dried. In this process, one of the amines of an aliphatic alcohol, monoethanolamine, was used as an aid to chelate the iron.

The task of the invention is to develop a method of obtaining a foliar fertilizer with a chelated boron anion content of at least 5% by weight, recommended for crops on heavily limed soils and slightly sandy soils, especially in the period of drought, cold rainy weather, mainly plants sensitive to boron deficiency: beetroot, flax, rape, tomatoes, cauliflower, celery, as well as legumes and brassica. It turned out that the task could be solved by changing the sequence of the complexation process and using an appropriate amount of an organic chelator - monoethanolamine.

The method according to the invention consists in first preparing a suspension of the boron compound by dissolving it in water at a temperature of 55-65 ° C, and then, while still stirring and maintaining the same temperature range of 55-65 ° C, the suspension is directly subjected to the chelation process with amino alcohol-ethanolamine in an amount of 60-65% by weight relative to the boron compound, dosed at a rate of preferably 1 dm ³ / min. Dissolving the boron compound in water is carried out in at least two stages: in the first stage, 50-65% of the total weight is dissolved at the rate of preferably 5 kg / 4 min, and in the second or final stage - the remaining amount, not faster than 1 kg / min. Boron compounds used are: boric acid, borax, alkali metal metaborate. In the case of using borax, the obtained aqueous suspension is directly chelated with the amino alcohol ethanolamine in an amount of 24-30% by weight relative to borax enriched with 19-23% by weight of citric acid, citric acid being added prior to the introduction of ethanolamine. The dissolution of borax and the subsequent chelation process are carried out at a pH <10, the pH being adjusted with citric acid. In the process of dissolving a boron compound, each successive batch is dosed after the previous one has dissolved. The dissolution of the boron compound is completed when a homogeneous, lump-free suspension is obtained. The chelation process is applied to an aqueous homogeneous suspension of a boron compound with a concentration of at least 8.5%, calculated as the boron ion. The chelation process is carried out in tanks made of copper-free materials. The product is a clear fertilizing agent, the pH of which at 20 ° C is 9.8 ± 0.2; and the specific gravity measured at the same temperature = 1.27 ± 0.01.

In the process according to the invention, a chelating agent of organic origin is used, therefore it is not harmful to the environment and, moreover, is used in a smaller amount relative to the boron ion than with other chelators. Using the method according to the invention, a fertilizer is obtained with a content of preferably 8% chelated boron, i.e. 105 g B / l of fertilizer, which is optimal considering that the solubility of non-chelated boron in water is ~ 5 g / l.

In crops sensitive to boron deficiency, the use of a fertilizer according to the invention in relation to the plants indicated, for example, affects:

- beetroot - resistance to dry rot and increased sugar content in the roots,

- linen - improvement of fiber quality,

- rapeseed - protection against reduced silica growth and low grain content,

- butterfly - protection against undeveloped root nodules,

PL 195 177 B1

- tomatoes - protection against dry top rot and dying of flowers,

- cauliflower - better education of the rose and protection against browning,

- brassica - protection against internal browning of the heads, cabbage keels,

- celery - protection against internal browning and voids in the root.

However, in fruit crops, especially fruit trees: apple, cherry, pear, peach, the described fertilizer strengthens pollen and, moreover, fertilizes the fruit.

The subject of the invention is explained in more detail in the working examples.

Example I. Boric acid containing 99.9% H3BO3 in the amount of 435 kg is poured into 300 l of water in a high-speed mixer, after switching on the stirrer and heating, at a temperature of 63-64 ° C, boric acid containing 99.9% H3BO3 in the amount of 435 kg using an appropriate dosing rate. Namely, 300 kg of acid is poured on at the rate of 25 kg / 20 minutes, and the remaining amount of 135 kg at the rate of 25 kg / 30 minutes. When dissolving, the rule is that successive portions of boric acid are poured after the previous portion has dissolved. When all of the acid has been poured in, the suspension is homogeneous, free from lumps, but not clear and cloudy. While still maintaining the temperature of 63-64 ° C, 250 l of monoethanolamine with a content of 94.6% are dosed to the suspension at a dosing rate of 0.9 kg / min. The chelation process of the boron anion produces a clear solution containing 8% by weight of boron.

In the exemplary process, 750 l of a fertilizer with a pH (20 ° C) = 9.8 with an acceptable fluctuation of ± 0.2 and a specific weight (20 ° C) = 1.27 with an acceptable fluctuation of ± 0.01, are obtained. sale under the name of Borvit. Due to the use of amino alcohol-monoethanolamine, devices made of copper-containing materials, for example brass, cannot be used in the process.

Example II. _{Borax (Na2B 4} O ₂ x 10 H ₂ O) in the amount of 660 kg is poured into 200 l of water in a 750-liter reactor, after switching on the stirrer and after heating to 65 ° C, at the appropriate dosing rate and maintaining the pH <10. The first batch of 350 kg is poured relatively quickly and dissolves within 30 minutes. The next batch of 200 kg is poured more slowly at a maximum rate of 2 kg / min, and finally the remaining 110 kg at a maximum rate of 1 kg / min. When borax is dissolved, the temperature is lowered - the heating is increased to maintain the temperature range of 60-65 ° C. Using the dissolution principle as in Example 1 and maintaining the temperature range mentioned above, 20 kg of citric acid are poured into the suspension and, after dissolving it, 80 liters of monoethanolamine are poured at a dosing rate of 1 dm ³ / min and with a simultaneous correction of the pH <10. take 2-3 kg of citric acid. As a result of chelation of boron ion from a milky-colored suspension, a clear solution is obtained, containing 7.5% by weight B. After cooling the solution to 750 liters with water, a fertilizing agent is obtained with a pH (20 ° C) = 9.7 and specific gravity (20 ° C) = 1.27.

In addition to the advantages described above, the fertilizer produced according to Examples 1 and 2, due to its alkaline reaction, has plant protective properties against infection.

Claims (9)

Patent claims A method for producing a foliar fertilizer containing a boron compound by dissolving and chelating an anionic group with boron, characterized in that by first suspending the boron compound by dissolving it in water at 55-65 ° C and then continuing to stir and maintaining the same temperature range of 55-65 ° C, the suspension is directly chelated with the amino alcohol-ethanolamine in an amount of 60-65% by weight relative to the boron compound, dosed at a rate of preferably 1 dm3 / min, the dissolution of the boron compound in water is carried out at least in two stages: in the first stage 50-65% of the total weight is dissolved by dosing at a rate of preferably 5 kg / 4 min, and in the second or final stage the remaining amount, not faster than 1 kg / min. 2. The method according to p. 1, in that the following are used as the boron compound: boric acid, borax, alkali metal metaborate. 3. The method according to z ^^ sr ^^. A method according to claim 1 or 2, characterized in that in borax the obtained aqueous suspension is directly chelated with aminoalcohol-ethanolamine in an amount of 24-30% by weight against anhydrous borax, enriched with an additive PL 195 177 B1 19-23 wt.% Citric acid, the citric acid being added prior to the introduction of the ethanolamine. 4. Sppssb wool with zzstrz. 1 I uU 3, with the difference that the prooce rozpuszzzinia borakks and the subsequent chelation process are carried out at a pH <10, the pH being adjusted with citric acid. 5. Wooluu zzstro. 1, characterized by the fact that the compound 3οω. the next batch is dispensed after dissolving the previous one. 6. Sppsób wełuu zzas-r. 1 I uub, with the fact that zzSoScczsieroozu differentiates the relationship bom occurs after obtaining a homogeneous suspension without lumps. 7. Way weeług zastro. As claimed in claim 1, characterized in that the proocs chelate is administered; an aqueous, fertile suspension of the Oor compound at a concentration of at least 8.5%, based on the Oor ion. 8. Make the wool very well. 1 And ub 3, mummy, be broocs pZetajęaji browaadi sticks made of copper-free Ubw material. 9. Spps0b weeług pzstro. 1, mummy that it is the planned load flow, the pH of which at 20 ° C is 9.8 ± 0.2 and the specific gravity measured at the same temperature = 1.27 + 0.01.