PL199317B1 - Method for the manufacture of liquid potassic-phosphatic fertilizers for intraleave fertilization - Google Patents

Abstract

a method for producing liquid potassium and phosphorus fertilizers for foliar fertilization of plants by dissolving the fertilizing macroelements: potassium, phosphorus, nitrogen and chelating substances in water and adding chelated microelements, characterized in that the potassium macroelements: K2CO3 and KOH are reacted with phosphoric acid, preferably 75% orthophosphoric acid in a strongly alkaline medium with a pH above 9 in the presence of sodium polyphosphate to obtain a phosphate mixture, wherein first K2CO3 is dissolved by introducing it in two stages, preferably in equal parts: the first part is dissolved while stirring in water at a temperature slightly above room temperature, preferably 20°C, then sodium polyphosphate is added and after it is completely dissolved, phosphoric acid is poured in alternating with KOH so that the pH of the solution is maintained at a level above 9 and the temperature - within the range of 55-60°C, then sodium polyphosphate is dosed the remaining amount of K2CO3 and after its reaction, the solution is left for a period of ~ 1.5 hours to cool to 40°C, then, while stirring, a mixture of complexing agents is added: urea and after its dissolution, a solution of 4-sodium salt of edetate acid, preferably 40%, and after cooling the whole to a temperature of 25°C ± 1°C, a separately prepared known solution containing 3% of chelated Cu and optionally water is added in an amount to make up its loss.

Description

Description of the invention

The subject of the invention is a method of producing liquid potassium-phosphorus fertilizers for foliar fertilization intended for fruit, horticultural and agricultural crops.

Potassium and similarly sodium are responsible for the proper water management of plants, regulation of the osmotic potential, the reaction inside the cell, it reduces the adverse effects of water stress and low temperatures. In addition, it affects the physiological strengthening of plants, increases resistance to fungal and bacterial diseases.

In turn, phosphorus is involved in all energy transformations in plants, regulating the processes of respiration, photosynthesis, and thus the processes related to the production of sugar and fats, and intensifies the growth of the root system.

Due to the shortage of potassium and the decreasing phosphorus content in soils and the poor absorption of phosphorus in cold weather - below 12 °, as well as during the period of water deficiency and excess, there is a need to supply plants with these nutrients - most effectively by foliar fertilization, i.e. by foliar fertilization.

There is known from the Polish patent specification No. 137 297 a method of obtaining a multi-component agent for fertilizing plants. The method consists in using, as one of the components, a separately prepared solution of phosphoric acid, potassium nitrate and potassium hydroxide or preferably potassium carbonate in order to produce monobasic potassium phosphate, with carbon dioxide partially dissolved in the solution when potassium carbonate is used. The obtained solution is introduced into the second component, which is neutralized with lime milk to a pH of about 4.5, the waste solution remaining after precipitation with dilute nitric acid ammonium paratungstate additionally enriched with magnesium salts containing ultramicroelements, such as: Ti, V, W, Ca and Na cations and nitrogen and sulfur. The third component is a micronutrient solution prepared separately from zinc and molybdenum salts and chelated with ethylenediaminetetraacetic acid or its salts and citric and / or ascorbic acid, iron, copper, manganese and boron compounds. The components are mixed together and additional nitrogen in the form of urea is optionally introduced into the resulting composition.

Moreover, the Polish patent specification No. 178 364 describes a method of obtaining a liquid fertilizer concentrate with microelements, especially for foliar feeding of potatoes. The method is characterized in that in dilute ammonia water in a strongly alkaline medium, citric acid, preferably and / or ammonium citrate, and / or sodium citrate and / or potassium citrate and / or EDTA and / or EDTA, and / or or sodium EDTA and the following microelements are introduced: copper, zinc, manganese in the form of sulphate and / or chloride and urea, and then boric acid dissolved in sodium hydroxide solution is added in such an amount that the fertilizer contains 0.45-0 , 55% boron with the mutual ratio of micronutrients Cu: Zn: Mn: B = 1: 3: 3: 1 with the tolerance of individual components ± 10%, the micronutrients being complexed with ammonia and the above-mentioned organic complexones.

Also known from Polish patent specification No. 195 176 is a method of producing a foliar fertilizer containing a phosphorus compound, preferably orthophosphoric acid. It consists in the fact that phosphoric acid, preferably 75% orthophosphoric acid at a temperature of at most 60 ° C, is chelated with an aliphatic amino alcohol in the amount of 60-85% by weight in relation to P2O5, dosed at the rate of 50 l / h at most, then the solution is cooled to 20 ° C ± 2 and made up with water in an amount of 3-12.5% by weight, preferably 8-12% by weight.

In addition to the above-mentioned patent, the known liquid foliar fertilizers contain phosphorus with a concentration of ~ 80 g P2O5 / l, which is not present together with sufficiently high potassium.

The attempts to dissolve the KH2PO4 crystalline potassium phosphate did not give the desired effects, as the required phosphorus concentration was not obtained.

Due to the phosphorus and potassium deficiencies in the soil as well as frequent acidification, research was undertaken on the possibility of obtaining alkaline fertilizers.

The object of the invention resulting from the accomplishment of the aim is to develop a method for obtaining a relatively high liquid potassium-phosphorus foliar fertilizer with chelated copper, maintaining a clear form and basicity.

PL 199 317 B1

Surprisingly, it turned out that the alkaline pH of the solution in combination with the macronutrients containing potassium and phosphorus influences the synthesis of salicylic acid, which is a kind of "signal" for plants to enhance immunity, and that the high pH reduces the infestation of pathogenic fungi.

The method according to the invention consists in reacting the macronutrients KCO3 and KOH with phosphoric acid, preferably 75% orthophosphoric acid in a strongly alkaline medium with a pH above 9 in the presence of sodium polyphosphate to obtain a mixture of phosphates. First, KCO3 is dissolved by introducing it in two stages, preferably in equal parts: the first part is dissolved, while stirring, in water at a temperature slightly above room temperature, preferably 20 ° C, then sodium polyphosphate is added and after its complete dissolution, phosphoric acid is poured alternately with KOH, that the pH of the solution is kept above 9, and the temperature - in the range of 55-60 ° C. Then the remaining amount of KCO3 is dosed and after its reaction, the solution is left for ~ 1.5 hours to cool down to 40 ° C, then, while stirring, a mixture of chelating substances, urea and, after dissolving it, a solution of 4-sodium salt of verse acid are added. , preferably 40%, and after cooling to 25 ° C ± 1 ° C, a separately prepared known solution containing 3% chelated Cu and optionally water to make up for the loss is added.

For the production of the fertilizer determined by the ratio P2O5: K2O = 10:20 (PK 10:20), phosphorus macronutrients are used in terms of P2O5 in the weight ratio H3PO4: sodium polyphosphate = 5.53: 1 with a tolerance of ± 2% and potassium macronutrients converted to K2O in the weight ratio K2CO3: KOH = 1.36: 1 with a tolerance of ± 2% and the mixture of chelating substances in the weight ratio urea: 40% solution of the 4-sodium salt of edetic acid = 13: 1, with urea content in the fertilizer is 2.62% by weight with a tolerance of ± 2%. However, for the production of the fertilizer determined by the ratio P2O5: K2O = 5:25 (PK 5:25), phosphorus macronutrients are used in terms of P2O5 in the weight ratio H3PO4: sodium polyphosphate = 3.48: 1 with a tolerance of ± 2% and potassium macronutrients in converted to K2O in the weight ratio K2CO3: KOH = 5.67: 1 with a tolerance of ± 2% and the mixture of chelating substances in the weight ratio urea: 40% solution of 4-sodium salt of edetic acid = 3.64: 1, with urea content % in fertilizer is 2.48 wt.%. with a tolerance of ± 2%.

The chelated Cu in the form of a 3% solution is introduced in the amount of ~ 0.34% by weight with respect to the total weight of the fertilizer PK 10:20 and PK 5:25. The mixture of chelating substances is used with a surplus of over a dozen percent resulting from taking into account, apart from the need to stabilize, Cu chelates and chelation of microelements: Ca Mg, Mn, Fe and Zn, present in the water used for production additionally - for chelation of these microelements in the water used for the preparation of the working liquid.

Sodium polyphosphate, which is a carrier of reactive sodium, influencing the hydration status of plant cell colloids, is slowly dosed with a thin stream to prevent the formation of sparingly soluble agglomerates. Phosphoric acid is administered near the bottom of the tank to distribute it throughout the volume of the solution and prevent a violent reaction. Before the addition of the chelating agent mixture, the foam formed on its surface along with impurities is removed from the solution.

Using the method according to the invention, a liquid, clear potassium fertilizer for foliar fertilization is obtained, even in the form of a working liquid. This is achieved thanks to the use of an appropriate amount of chelating agent, also taking into account the chelation of micronutrients in the water used to prepare the working liquid.

An important advantage of the produced fertilizer resulting from its alkaline nature is its effect reducing the infestation with pathogenic fungi, which allows for lower costs related to plant protection, lower contamination of products and the environment with plant protection products.

The PK fertilizer with a ratio of P2O5: K2O = 10:20, having a pH of 11.3 ± 0.3, is especially recommended in the period of intensive plant development, and a PK fertilizer with a ratio of P2O5: K2O = 5:25, with a pH of 12.3 ± 0.3 - for the fruiting period.

The subject matter of the invention is explained in more detail on the basis of its embodiments.

P r z k ł a d 1

700 l of water are poured into a reactor equipped with a water jacket for temperature control in the range of 20-60 ° C and a stirrer and heated to a temperature of 20 ° C. Then, after switching on the stirrer, the dosing of 128.5 kg of granulated K2CO3 - half of the required amount. After complete dissolution of the K2CO3, 40 kg of sodium polyphosphate is dosed slowly in a thin stream so as to prevent the formation of poor dissolving agglomerates. And successively, after chapter 4

After discharging sodium polyphosphate, 147 L of 75% H3PO4 are poured into the reactor by feeding it through an acid-resistant tube near the bottom of the tank to distribute the acid throughout the solution volume and to prevent vigorous reaction on the surface of the solution.

Phosphoric acid is introduced with the agitator turned off at such a flow rate that the temperature remains within the range of 55-60 ° C, and the pH of the solution does not drop too much and is above the level of 9. The pH of the solution is adjusted by alternating dosing with KOH in the amount of 170 kg and the remaining amount of K2CO3, i.e. 128.5 kg. The processes of dissolving potassium carbonate and potassium hydroxide are exothermic and as neutralization reactions - rapid, associated with the release of large amounts of CO2, therefore they should be carried out very carefully.

The resulting solution is allowed to stand for about 1.5 hours. until it is cooled to 40 ° C, after which the foam and impurities are removed from the surface. Then, while stirring, the chelating substances are added: 80 kg of urea, and after dissolving it - 5 l of a 40% solution of 4-sodium salt of edetic acid. In parallel, in a known manner, a 3% chelated copper solution is prepared by adding CuSO4 · 5H2O to a chelating mixture containing 5% citric acid, 10% monoethanolamine and 6% urea.

liters of the prepared 3% chelated copper solution are added to the cooled solution to 25 ° C, which is then made up to 1000 l with water (due to water losses during the process). The obtained fertilizer has a specific weight = 1.40 g / cm ³ , pH = 11.3 and the content of 151.8 g P2O5 / I and 303.56 g K2O / I, thus meeting the requirements for an alkaline potassium-phosphorus fertilizer with a mutual ratio P2O5: K2O = 10:20.

For spraying, a working liquid with a concentration of 0.5-0.8% by volume is used. Spraying is performed in cloudy weather in the morning or in the evening, for example for strawberries, raspberries, two sprayings are recommended:

I - spraying before flowering,

II - spraying after flowering, in the amount of 500-1000 l of working liquid / ha.

P r z k ł a d 2

As in example 1, 650 l of water are poured into the reactor and heated to a temperature of 20 ° C, and then, after switching on the stirrer, 240 g of granulated K2CO3 are dosed. After complete dissolution of the K2CO3, 30 kg of sodium polyphosphate are metered in as in Example 1 - slowly in a thin stream. Then, after dissolving the sodium polyphosphate, 73 l of 75% H3PO4 are poured into the reactor, dosing it in the same way as in example 1 so as to distribute the acid in the entire volume of the solution and prevent a violent reaction on the surface of the solution, and also that the pH of the solution is not lower than 9, and the temperature remained in the range of 55-60 ° C.

As in example 1, the pH of the solution is adjusted by alternating dosing with 80 kg of KOH and the remaining amount, i.e. 254 kg of K2CO3. After the stirrer is turned off, the resulting solution is left to stand for about 1.5 hours. until it is cooled to a temperature of about 40 ° C, after which the foam and impurities are removed from the surface. Then, while stirring, the chelating substances are added: 80 kg of urea, and after dissolving it - 20 liters of a 40% solution of the 4-sodium salt of edetic acid.

Separately - in a known manner - a 3% chelated copper solution is prepared, which 6 liters are added to the solution cooled to 25 ° C, which is then made up to 1000 liters with water (due to water losses during the process).

The obtained fertilizer has a specific weight = 1.48 g / cm ³ and pH = 12.3 and the content of 80 g P2O5 / l and 400 g KaO / l, i.e. alkaline potassium-phosphorus fertilizer with a mutual ratio of P2O5: K2O = 5:25.

For spraying, a working liquid with a concentration of 0.5-0.8% by volume is used. Spraying is performed in cloudy weather in the morning or in the evening, for example, for tomatoes, peppers and cucumbers, two sprayings are recommended:

I - spraying after fruit production,

II - spraying after two weeks, in the amount of 300-600 l of working liquid / ha.

Claims (8)

1. Method for the production of liquid potassium-phosphorus fertilizers for foliar fertilization of plants by dissolving in water the macronutrients of fertilizers: potassium, phosphorus, nitrogen and chelating substances and the addition of chelated microelements, characterized in that the potassium macronutrients: K2CO3 and KOH are reacted with phosphoric acid , preferably with 75% orthophosphoric acid in a strongly alkaline medium with a pH above 9 in the presence of sodium polyphosphate to obtain a mixture of phosphates, where K2CO3 is first dissolved by introducing it in two stages, preferably in equal parts: the first part is dissolved in water with a temperature of slightly above room temperature, preferably 20 ° C, then sodium polyphosphate is added and after its complete dissolution, phosphoric acid is poured alternately with KOH, so that the pH of the solution is above 9, and the temperature - within 55-60 ° C, then dosing the remaining amount of K2CO3 appears and, after it has reacted, ro the solution is left for ~ 1.5 hours to cool to 40 ° C, then, while stirring, add to the chelating substances, urea and, after dissolving it, a solution of the 4-sodium salt of edetic acid, preferably 40%, and after cooling it to the temperature At 25 ° C ± 1 ° C, a separately prepared known solution containing 3% chelated Cu and optionally water to make up for the loss is added. 2. The method according to p. 1, characterized in that for the production of the fertilizer determined by the ratio P2O5: K2O = 10:20, phosphorus macronutrients are used in terms of P2O5 in the weight ratio H3PO4: sodium polyphosphate = 5.53: 1 with a tolerance of ± 2% and potassium macronutrients calculated as on K2O in the weight ratio K2CO3: KOH = 1.36: 1 with a tolerance of ± 2% and a mixture of chelating substances in the weight ratio urea: 40% solution of the 4-sodium salt of edetic acid = 13: 1, with the urea content in the fertilizer % is 2.62 wt.%. with a tolerance of ± 2%. 3. The method according to p. 1, characterized in that for the production of the fertilizer determined by the ratio P2O5: K2O = 5:25, phosphorus macronutrients are used in terms of P2O5 in the weight ratio H3PO4: sodium polyphosphate = 3.48: 1 with a content tolerance of ± 2% and potassium macronutrients in terms of K2O in the weight ratio K2CO3: KOH = 5.67: 1 with a tolerance of ± 2% and the mixture of chelating substances in the weight ratio urea: 40% solution of 4-sodium salt of edetic acid = 3.64: 1, with the urea content in the fertilizer being 2.48 wt.% with a tolerance of ± 2%. 4. The method according to p. 3. The method of claim 1 or 2 or 3, wherein chelated Cu in the form of a 3% solution is introduced in an amount of ~ 0.34% by weight relative to the total weight of the fertilizer. 5. The method according to p. 1 or 2, or 3, characterized in that a mixture of chelating substances is used with a surplus of more than ten percent resulting from taking into account, apart from the need for stabilization of Cu chelates and chelation of microelements Ca, Mg, Mn, Fe and Zn, present in the water used for production also additionally - for chelation these micronutrients in the water used to prepare the working liquid. 6. The method according to p. The method of claim 1 or 2, or 3, characterized in that the sodium polyphosphate carrying the reactive sodium influencing the hydration status of plant cell colloids is slowly dosed in a thin stream to prevent the formation of sparingly soluble agglomerates. 7. The method according to p. The method of claim 1 or 2 or 3, characterized in that phosphoric acid is administered near the bottom of the tank to distribute it throughout the volume of the solution and to prevent violent reaction. 8. The method according to p. The method of claim 1 or 2 or 3, characterized in that the foam formed on the surface along with impurities is removed from the solution before adding the mixture of chelating substances.