NO150037B - GROWTH SOLUTION AND PROCEDURE FOR ITS MANUFACTURING - Google Patents

Description

The invention relates to a new and advantageous growth nutrient solution with macronutrients consisting of Mg and P intended for use in the preparation of a liquid nutrient stock solution which is complete with regard to the content of growth nutrients such as N, P, K, S, Ca, Mg, Fe, Mn, Zn, Cu, B, Mo and Co, for nutrient enrichment of irrigation water. The invention also relates to a method for producing said growth nutrient solution.

Within certain types of crop cultivation, it is advantageous and

it is common to add the necessary growth nutrients in connection with irrigation, often at each watering event, dissolved in the raw water used for irrigation. A complete stock solution is usually prepared from one or more commercially available water-soluble solid and/or liquid growth nutrients and water relatively concentrated with regard to its content of growth nutrients. This stock solution, which is mainly in the form of dissolved salts, also contains macronutrients, e.g. N, K, P, S, Ca and Mg,

as micronizing substances, e.g. Fe, Mn, Zn, Cu, B, Mo and Co are then dosed to the raw water to form dissolved nutrients of, for example, a few or more tenths of a weight-%, although higher concentrations may occur. By worshiping

prepared the stock solution at the cultivation site from several different growth nutrients, the grower can adjust the composition of the stock solution according to the current nutrient needs of the cultivated plants, in the relevant cultivation environment, taking into account any nutrients already present in the raw water available for irrigation.

To rationalize the preparation of such stock solutions, ready-made micronutrient mixtures are available in the form of dry products, resp. a water solution, with a dry content of approx. 25% by weight, in which the micronutrients are combined with chelating organic compounds. Furthermore, there is an approx.

50% growth nutrient solution, containing Mg and P in et

approximated to the consumption of these nutrients' corresponding ratios. Necessary temperature stability (no crystallization of salts at the usual processing temperature) has, however, only been achieved by the addition of nitric acid or another strong acid, which complicates the preparation of the stock solution in that the solution containing Mg and P becomes corrosive and also necessitates great care by adding the chelated micronutrient which, in contact with the Mg and P containing solution strong, oxidizing acid, could be broken down during the precipitation of very poorly soluble micronutrients,

without value for the growths in stock solution. A method to avoid these disadvantages would be to use a solution containing Mg and P with an excess of phosphoric acid sufficient to achieve acceptable temperature stability instead of the aforementioned strong acids. This will, however, necessitate an additional working moment for supplementing the stock solution with regard to the Mg content, whereby part of the intended rationalization gain will go

lost. Blue. from a practical and economic point of view, available Mg sources, namely MgSO^ and magnesium nitrate, the bitter salt entails the disadvantage that sulphur, if too high a content is also previously difficult to avoid, is also added to the stock solution, while from a compositional point of view the more acceptable, but price-wise disadvantageous magnesium nitrate is difficult to store and handle due to its highly hygroscopic properties.

An object of the invention is therefore to provide a

new growth nutrient solution containing the macronutrients Mg and P in the desired high molar ratio, if used

use of this for the preparation of plant nutrient stock solutions does not result in the above-mentioned disadvantages.

The invention is thereby characterized by the growth nutrient solution of the type mentioned at the outset that it consists of a magnesium phosphate solution with a total water content of 20-45, preferably approx. 35-42% by weight, and a molar ratio between Mg and P of 0.9-1.2:2, preferably approx. 1-1,2:2, as well as containing the micronutrients such as Fe, Mn, Zn, Cu, B, Mo and Co, in relation to its P content, in a sufficient amount, to cover the micronutrient needs in such a complete nutrient stock<p> solution, the total P content of which is added to said growth nutrient solution, as well as one or more chelating substances in a total amount sufficient to bind the micronutrients as a chelate. Thereby, the growth nutrient solution suitably contains micronutrients in an amount that exceeds 5% of the P weight, suitably in the order of 10-12% of the P weight. The growth nutrient solution proposed according to the invention has surprisingly good stability, also at a high concentration and the excess content of Mg, i.e. at a molar ratio between Mg and P exceeding 1:2. With the high concentration, further benefits are achieved in the form of reduced transport costs and reduced packaging costs per amount of growth nutrients. By the fact that the growth nutrient solution contains both the necessary Mg and P as well as the necessary micronutrients in amounts adapted to each other, considerable rationalization advantages are also achieved when preparing stock solutions without the degree of freedom in their composition being significantly affected in practice.

As mentioned, the invention also relates to another method

to produce a growth nutrient solution with macronutrients consisting of Mg and P, as well as containing micronutrients such as Fe, Mn, Zn, Cu, B, Mo and Co, and one or more chelating substances in a dressing of the micronutrient which chelate sufficient amount. With the method according to the invention, a growth nutrient solution with a high concentration and a high molar ratio between Mg and P is produced without the risk of precipitation of poorly soluble salts that are overactive as growth nutrients in connection with the preparation, and the subsequent handling and use of the growth nutrient solution. The method according to the invention is mainly characterized by the chelating micronutrient

substance or substances, is added to a slurry of magnesium oxide in water, after which phosphorus is added in the form of phosphoric acid and any further slurry of magnesium oxide in water is added, whereby the magnesium oxide slurry is prepared and possibly diluted using water to a final water content in the growth nutrient solution of 20- 45, preferably approx. 35-42% by weight, and the amount of magnesium oxide and phosphoric acid is adjusted so that a molar ratio between Mg and P of 0.9-1.2:2 is obtained in the solution, preferably approx. 1-1,2:2. It is therefore within the scope of the invention to use magnesium oxide in a previously diluted form for said slurry. The quantity or the composition of the micronutrient is thereby preferably chosen such that it covers the micronutrient requirement in a complete complete fertiliser, whose total P content and preferably also Mg content have been added using a growth nutrient solution prepared according to the above-mentioned method. Appropriately, the micronutrients are added in an amount that exceeds 5% of the weight of the growth nutrient solution's P content, preferably in the order of 10-12% of the P weight.

According to one embodiment of the method according to the invention, 10-20% of the total amount of slurry of magnesium oxide has first and the rest been added after or in connection with the addition of phosphoric acid.

Of micronutrients, i.e. mainly Fe, Mn, Cu, B,

Zn, Mo and Co, which are necessary for the plants only in very small quantities, are added according to one embodiment of the invention, one or more in the form of a sulphate except for boron and molybdenum. Boron is preferably added in the form of boric acid, while the appropriate addition form for molybdenum according to the invention is ammonium molybdate. A preferred alternative form of addition for iron is a complex of iron with the trisodium salt of hydroxyethylenediaminetriacetic acid, which complex is a commercial product. As chelating substance or substances, any substance can be used, which has been used in other connection for the formation of chelate with micronutrients in various fertilizers or growth nutrients. Examples of such substances are ethylenediaminetetraacetic acid (EDTA) in the form of free acid, hydroxyethylenediaminetriacetic acid (HEEDTA) in the form of free acid or the trisodium salt, citric acid, tartaric acid, nitrilotriacetic acid and other chelating agents that have good solubility

hot in acidic environment. It can therefore be advantageous to use particularly easily soluble chelating agents or supplement less soluble chelating agents with a more soluble one.

Thus, it may be appropriate that in those cases

in which EDTA is used as a chelating agent, while also using HEEDTA, the weight part of EDTA being calculated on the weight of the mixture, is expediently a maximum of 2/3.

The amount of chelating substance or substances is adapted to

the amount of micronutrients, so that the latter can be completely bound in the form of a chelate. The amount of micronutrient

substance f is, in turn, adapted to each other, and to the amount of P, so that the conditions that usually prevail between the micronutrients and between these and P in complete fertilizer are fulfilled.

In the following, the invention will be explained with the help of

some execution examples:

Example_l

A growth nutrient is produced, as per 100 kg of solution is used:

MgQ is prepared into a solution with double the amount of water.

About 20% of the slurry was introduced into a reaction vessel equipped with a recirculator and water cooling, after which the remaining water, Fe-HEEDTA complex and the micromixtures were added while stirring and cooling.

After 4 minutes, phosphoric acid was added, after which the remainder of the MgO slurry was added at such a rate that a homogeneous mixture was obtained, and the temperature did not exceed 85°C.

After all the MgO has been added by stirring and cooling continued for 15 minutes, after which the product after straining was poured into containers.

The product formed had a content of 41.97 wt% 1^0, 12.06 wt% P and 4.7 wt% Mg, corresponding to a Mg:P molar ratio of 1.0:2.

Exert}2el_2

A growth nutrient agent was prepared in the same way as in example 1, but per 100 kg of solution was used:

The product obtained had a content of 41.27 wt% H 2 O, 12.06 wt% P and 5.10 wt% Mg, corresponding to a Mg:p molar ratio of 1.08:2.

Example_3

A growth nutrient was produced in the same way as in example 1, but per 100 kg of solution was used:

The product obtained had a content of 43.2% by weight I^O, 12.06% by weight P and 4.7% by weight Mg, corresponding to a molar ratio Mg:P of 1:2.

The solutions prepared according to the examples were found to be very stable and withstand temperatures below -30°C without salting out occurring.

Claims (7)

1. Growth nutrient solution with macronutrients consisting of Mg and P intended for use in the preparation of liquid nutrient stock solution that is complete with regard to its content of growth nutrients such as N, P, K, S, Ca, Mg, Fe, Mn, Zn, Cu, B , Mo and Co for nutrient enrichment of irrigation water, characterized in that said growth nutrient solution consists of a magnesium phosphate solution with a total water content of 20-45, preferably approx. 35-42% by weight, and a molar ratio between Mg and P of 0.9-1.2:2, preferably 1-1.2:2, and also contains micronutrients such as Fe, Mn, Zn, Cu, B, Mo and Co in a quantity sufficient in relation to the P content, to cover the micronutrient needs in such a complete nutrient stock solution, whose total P content was added through said growth nutrient solution, as well as one or more chelating substances in a for binding the micronutrients which chelate sufficient total amount. 2. Growth nutrient solution according to claim 1, characterized in that it contains micronutrients in an amount that exceeds 5% of the P weight, suitably 10-12% of the P weight. 3. Method for preparing a growth nutrient solution with macronutrients consisting of Mg and P, as well as containing micronutrients such as Fe, Mn, Zn, Cu, B, Mo and Co and one or more chelating substances in an amount sufficient to bind the micronutrient as a chelate, characterized in that the micronutrient and chelating substance or substances are added to a slurry of magnesium oxide in water, after which phosphorus in the form of phosphoric acid is optionally added a slurry of magnesium oxide in water is added, whereby water is used for the preparation of the magnesium oxide slurry and possible dilution to a final water content in the growth nutrient solution of 20-45, preferably approx. 35-42% by weight, and the amount of magnesium oxide and phosphoric acid is adjusted so that a molar ratio between Mg and P of 0.9-1.2:2, preferably 1-1.2:2, is obtained in the solution. 4. Method according to claim 3, characterized in that micronutrients are added in an amount that exceeds 5% of the weight of the growth nutrient solution's P content, preferably 10-12% of the P weight. 5. Method according to claim 3 or 4, characterized in that 10-20% of the total amount of slurry of magnesium oxide is added first, and the remainder is added after or in connection with the addition of phosphoric acid. 6. Method according to one of claims 3-5, characterized in that one or more of the micronutrients, with the exception of boron and molybdenum, are added in the form of a sulphate. 7. Method according to one of claims 3-6, characterized in that iron is added in the form of a complex with trisodium salt of hydroxyethyl-ethylenediaminetriacetic acid.