HU192754B - Process for producing suspension containing nitrogen, calcium and if desired potassium - Google Patents

Abstract

According to the present invention, in the case of phosphorus-free calcium nitrate, at least once, an aqueous solution or melt of calcium nitrate having a pH of from 5.5 to 5.0 is present in an amount of 0-1.5% by weight of phosphorus-free calcium nitrate, but in other cases, up to three times the excess is reacted simultaneously or repeatedly at 50-8 ° C with 40-50% ammonium carbonate solution or solid ammonium carbonate or a mixture of ammonia and carbon dioxide. The resulting 72-78% by weight ammonium nitrate, calcium nitrate and calcium carbonate slurry are optionally mixed with 18% by weight of potassium chloride and up to 1.3% by weight of metal. The pH of the suspension is adjusted to pH 6.5-7.5 in a known manner. 192 754

Description

FIELD OF THE INVENTION The present invention relates to a process for preparing a slurry of nitrogen, calcium and, where appropriate, potassium in agriculture, which, unlike the stoichiometric ratio, contains up to 3 times the excess of 0-1.6% by weight of phosphorus At -80 ° C with a solution of ammonium carbonate or solid ammonium carbonate or a mixture of ammonia and carbon dioxide gas, followed by optionally potassium compound, e.g. potassium chloride; and the pH of the suspension is adjusted to 6.5-7.5.

The application of the composition according to the present invention is indicated in the field of agriculture, where the composition is particularly suitable for the nutritional replacement of acidic soils, but can also be applied to other soils.

Before describing the subject matter of the present invention, the prior art will be described.

It is known that liquid or slurry fertilizers are used worldwide. These have the indisputable advantage over solid fertilizers that they can be moved, transported and applied in a simpler, virtually labor-free way. Another great advantage of their application to the soil is that the surface is evenly covered with nutrients. (Scott, W.c., Wilbanka, JA: Fertilizer Solutions, 4, 20, 1976, pp. 54-64, Todorovic, Milan: Production and Application of Liquid Fertilizers. Tech., Beograd, 1974, 29, 10 12.

1840-1845 p.)

It is also known that scientific practice and experience show that one of the prerequisites for improving acidic soils and preventing them from spreading is to maintain and maintain the calcium supply of the soils by calcium fertilization, as without which fertilizers, primarily nitrogen and phosphorus, count. The importance of liming is evidenced by the large number of publications and lectures on the topic. (Eg Avdonyin N „Sz .: Improving the fertility of acidic soils. Agricultural Publisher, Budapest, 1972 or Dr. László Nyíri: New guidelines for the liming of acidic soils. 46).

The author of the latter article, analyzing the conditions in Hungary, states that in Hungary there are still approx. 1.2 million ha. it is imperative to liming the soil, for which it recommends the use of calcium carbonate as a by-product as a by-product of some factory technologies.

Dr. László Nyíri: Practical aspects and results of the effective application of lime fertilizers. Chemistry of Agriculture Both publications, Heavy Chemical Industry! Research Institute Veszprém, 1978, pp. 164-168, states that due to fertilization, especially in more rainy and humus-poor areas, such as the northern European country and the US, the Soviet Union, etc. - there is a new acidification of already calcareous soils. For these reasons, the demand for lime drinks in these countries is increasing.

As is known, calcium nitrate, as one of the possible lime fertilizers, in itself, in solid form, has poor physical properties (adhesion, hygroscopicity, etc.). Therefore, calcium nitrate, e.g. conversion (in the case of digestion of crude phosphates with nitric acid, the so-called Norsk-Hydro process) is converted to ammonium nitrate, the resulting calcium carbonate is filtered off, or otherwise mixed by various processes and evaporated, crystallized, granulated, granulated. Several methods are known for such solutions (eg, German Patent No. 1C16733, 11112) 8. s. US Patent Specification or T. W. Segar, Shem. Eng. Progress 62, No. 2, 1966, pp. 123-126. However, these procedures are extremely energy intensive and complicated.

The slurry produced by the process of the present invention is free of the above-mentioned disadvantages.

The present invention is based on the discovery that calcium carbonate, when removed under appropriate conditions, remains floating in solution and, surprisingly, depending on the phosphorus and calcium nitrate content of the suspension, remains suspended in the solution and can be varied in composition. , calcium nitrate, ammonium nitrate, is a very stable slurry which can be directly applied, ie without filtration and evaporation.

In our investigations, it was found that the properties of the suspension are significantly influenced by the preparation conditions and the ratio of the components: thus, calcium carbonate is precipitated at 50-80 ° C, preferably at 60-70 ° C. with partial pre-neutralization of calcium nitrate, whereby the presence of phosphorus in reaction with calcium significantly improves the conditions for the formation of a suspension. It has further been found that, when using phosphorus-free calcium nitrate, the reaction must be carried out with an excess of calcium nitrate, at least one excess, to give a good suspension, but not more than three times the excess or calcium carbonate containing ammonium nitrate. in the absence of phosphorus, at least the same amount of calcium nitrate as the moles of calcium carbonate must be added, so the presence of calcium nitrate in the suspension is essential.

The inverse relationship has also been found that when using high calcium nitrate above 1% by weight, the excess of calcium nitrate can be up to a single, but at 1.5% by weight, no excess of calcium nitrate is possible.

Based on these findings, the suspension prepared according to our method has a favorable density and viscosity, even when cooled to 0 ° C, so it does not change much even at low temperatures during the head-fertilization period. With respect to the useful components of the resulting suspension, it has a surprisingly high content of active ingredient (up to 30% by weight of water) in comparison to a conventional suspension fertilizer. Suitable micronutrients may also be included in the suspension, and the potassium compound, e.g. potassium chloride. Thus, a suspension of nitrogen, calcium and potassium fertilizers can be prepared.

Several variations of our procedure are possible and are illustrated in the examples. It has been mentioned that the calcium nitrate tetrahydrate [Ca (NO3) 2.4H2O] formed by the Norsk-Hydro process is converted to calcium carbonate and ammonium nitrate, and then the calcium carbonate is filtered off and the ammonium nitrate solution formed as its hair is filtered off. part of it is evaporated and the dry residue is processed into fertilizer. Filtered calcium carbonate is used by agriculture, among other things - for liming soils. In the process, the calcium nitrate tetrahydrate melt is mixed with an ammonium nitrate solution containing ammonium carbonate. This process has the disadvantage of having a phosphorus content of more than 0.3% by weight of calcium nitrate tetrahydrate, which can cause malfunctions in the calcium carbonate filtration (e.g., clogging of the filter surface). This disadvantage can only be avoided by very careful operating parameters. It is also possible to process such phosphorous-containing calcium nitrate by the process, which has the advantage that the filtration and the resulting ammonium nitrate solution do not require energy-intensive evaporation.

According to the present invention, the slurry, which has become unfiltered due to the high content of calcium nitrate, is mixed with calcium nitrate tetrahydrate melt in a stirred reactor - and the pH of the suspension is adjusted to 6.5-7.5. No separate suspending agent is used.

In another embodiment of the process, the calcium carbonate slurry is prepared in one step by adjusting the solution or melt of excess phosphorous calcium nitrate in a stirred reactor to pH 5.5-6.0 by adding 50 g of ammonia gas. At a temperature in the range of 80 DEG C., a solid ammonium carbonate solution or a solution containing ammonium carbonate or a mixture of ammonia and carbon dioxide gas is added and the pH of the suspension is adjusted to 6.5-7.5 at the end of the process. or an acid, preferably by the addition of nitric acid. No separate suspending agent is used here either.

The K (K2O) -containing suspension is prepared by mixing the basic suspension prepared above with potassium chloride (55-60 wt. K2O) used in fertilizer production at 40-60 ° C, in suitable proportions. Likewise, conventional micronutrients may be incorporated, preferably in the form of inorganic salts.

Variations of the process and the composition of the suspensions which may be prepared are also illustrated in the Examples.

Example 1

500 g of 0.5% (w / w) P (Ca ₃ NO ₂ ) 2.4H ₂ O in 92 g of water are treated with 203 g of NH ₄ NO ₃ and 203 g of NkbhCO 2 in a suitable composition and the resulting slurry is indicated. of a composition melted in another vessel with 0.2 wt% P content of 500 g Ca (NO3) 2.4H2O in a melt at 70 ° C adjusted to a pH of 5.5 to 6.0 .

Characteristics of suspension (at 25 ° C):

pH 6.9; density - 1511 kg / m ³ ; viscosity 17 m Pa.s; fluid, easy to pump. Floatability is 98% after 24 hours and 89% after 7 days.

composition of the main components: 36.2% by weight 23.2% by weight 14.2% by weight 26.4% by weight NH4NO3 Ca (NO ₃ ) 2 CaCO3 water 16.6% by weight sum. N Example 2 To the .A 'composition described in Example 1, a melt of' 0.4% w / w 750 g / Ca (NO ₃ ) 2.4H ₂ O in ammonia gas to pH 5.5-6.0 was added with stirring at 50 ° C. . Characteristics of suspension (at 25 ° C): pH = 6.7; density - 1577 kg / m ³ ; viscosity 21 m Pa.s; liquid, easy to pump. Floatability is 98% after 24 hours and 92% after 7 days. composition of the more 31.0% by weight 29.8% by weight g% 12.1% by weight 27.1% by weight for components: NH4NO3 Ca (NOs) z CaC03 water

15.9% w / w. N

Example 3

To the composition A 'described in Example 1, a melt of 0.3 wt% 1500 g / Ca (NO3) 2.4H2O in ammonia at pH 5.5-6.0 was added at 80 ° C with stirring.

composition of the main components:

28.2 Weight » 28.9 weight » 17.5 weight » Weight 25.4 » NH4NO3 CaíNOa) ' CaCO3 water 14.8 Weight » sum. H

Characteristics of suspension (at 25 ° C):

pH = 7.0; density = 1607 kg / m ³ ; viscosity 25 m Pa.s; liquid, easy to pump. Floatability after 24 hours 99 », After 7 days 95 ». composition of the main components for: 21.7 weight » NH4NO3 41.8 weight » Ca (NO ₃ ) 2 8.5 weight » CaCOs 28.0 weight » water 14.7 weight » sum. N

Example 4

0.5 g »P-containing 500 g Ca (NOa) 2.4H2O ammonia gas neutralized to pH 5.5-6.0 with stirring at 55 ° C in 25 g water, 50 g ΝΗ <Ν03-ΐ and 50 g g / (NH4) 2CO3.

Characteristics of suspension (at 25 ° C):

pH = 7.3; density = 1610 kg / m ³ ; viscosity 26 m Pa.s; liquid, easy to pump.

Floatability after 24 hours 99 », After 7 days 98 ». composition of the main components for: 20.1 weight » NH4NO3 42.6 weight » Ca (NO3) 2 8.5 weight » CaCC> 3 28.8 Weight » WATER 14.3 weight » sum. N

Example 6

A mixture of NH3 and CO2 gas was stirred at 50 ° C into a solution of 500 g Ca (NC> 3) 2.412O ammonia gas, 1.5 wt% P, at pH 5.5-5.0, while stirring until carbonate was removed it is.

Characteristics of suspension (at 25 ° C):

pH 6.5; density = 1574 kg / m ³ ; viscosity 560 m Pa.s; dense, difficult to pump. Floating ability 100 »after 24 hours, 95» after 7 days.

composition of the main components:

48.2 wt

30.0% by weight »CaCC> 3

21.8% water

16.9 wt. N

Example 7

Dissolve 350 g of Ca (NOa) 2 in 0.1 wt% P in 100 g of water, adjust the pH to 5.5-6.0 with weakly acidic saline, and dissolve 51 g of (NH4) 2CO3 in 50 g of water and the solutions were stirred at 65 ° C with stirring.

Characteristics of suspension (at 25 ° C):

pH = 6.8; density = 1676 kg / m ³ ; viscosity 58 m Pa.s; liquid, easy to pump. Floatability is 98 »after 24 hours, 91» after 7 days.

composition of the main components:

EXAMPLE 5 To a solution of 500 g Ca (NO3) 2-4H2O containing 5% by weight of p-mass was added 101 g of powdered ammonium carbonate under vigorous stirring at 60 ° C with vigorous stirring.

Characteristics of suspension (at 25 ° C):

pH 7.5; density = 1624 kg / m ³ ; viscosity 50 m Pa.s; liquid, easy to pump. Floatability is 100 »after 24 hours, 98» after 7 days.

Weight 15.5 » 47.6 weight » 9.7 weight » 27.2 Weight » NH4NO3 Ca (NOs) 2 CaCŰ3 water 13.6 Weight » sum. N

Example 8

Phosphorus-free 350 g Ca (NO3) a-c is dissolved in 50 g water, the weak acid solution is adjusted to pH 5.5-6.0 and 102 g (NH4) jCO3 is dissolved in 100 g water and stirring the solutions at 70 ° C with stirring.

Characteristics of suspension (at 25 ° C):

pH = 7.0; density = 1544 kg / πι ³ ; viscosity 28 m Pa.s; liquid, easy to pump. Floatability is 94% after 24 hours and 67% after 7 days.

composition of the main components:

28.3% by weight NH4NO3 29.1% by weight Ca (NO ₃ ) z 17.7% by weight CaCOs 24.9 mass water

14.85% wt. N

Example 9

To the suspension of Example 3 (2000 g) was stirred 440 g of 60 wt% K 2 O in mineral potassium chloride while warm (50-60 ° C), and then the large granular, adhered potassium chloride was added. from the solid impurities introduced, the final suspension is filtered.

Characteristics of suspension (at 25 ° C):

pH = 7.0; density = 1620 kg / m ³ ; viscosity 70 m Pa.s; liquid, easy to pump. Floatability after 24 hours 98%; low, non-compact sediment; after storage for several days, it is advisable to mix the suspension to ensure homogeneity.

composition ! the main for components: 17.9 crowd% NH4NO3 34.2 crowd% Ca (NO ₃ ) z 7.0 crowd% CaCC> 3 18.0 crowd% KCI 22.9 crowd% water

12.1% w / w. N

Example 10

An amount of manganese nitrate, zinc sulphate, cobalt nitrate, copper sulphate and borax is mixed with any amount of the suspension prepared in Example 3 with stirring while warm, so that the suspension is diluted to 0.2 manganese, zinc, cobalt, copper and 0.2-0.5 wt. The characteristics of the suspension thus produced and the proportions of the principal components are not altered by the micronutrients incorporated.

The advantage of the process is that cheap raw materials or raw materials are used. pulsating pasts, in a state-of-the-art form, technically simple and extremely economical - can be flexibly adapted to existing plant technologies to produce a new multi-component fertilizer, which, in addition to existing fertilizers, offers ¹⁵ additional expansions while incorporating proven calcium carbonate lime. A further advantage of the suspension prepared by our process is that it has a high concentration of active ingredients and a high density of ² θ (1500-1650 kg / m ³ ), so it is economical to transport it in a tanker.

Claims (1)

A process for preparing a suspension containing 13.5 to 17% by weight of nitrogen, 11.0 to 15.5% by weight of calcium, 0 to 108.8% by weight of potassium oxide and optionally micronutrients, calcium nitrate, ammonium carbonate and the like. by reaction of ammonia and carbon dioxide, wherein the aqueous solution or melt of calcium nitrate having a pH of 0 to 1.5% by weight of pH 5.5 to 6.0, preferably calcium nitrate tetrahydrate, differs from the stoichiometric ratio. in the case of phosphate-containing calcium nitrate, at least once, but in other cases not more than three times, in excess or in several administrations at 50-80 ° C4 0 -on, preferably at 60-70 ° C, with a solution containing 40-50% by weight of ammonium carbonate, optionally containing up to 40% by weight of ammonium nitrate, or solid ammonium carbonate, or ammonia and carbon dioxide reacting a gas mixture, and then the thus prepared containing 72-78% by weight of ammonium nitrate, calcium nitrate and calcium carbonate suspension - which, where appropriate, 40 to 60 ° C, 18 wt% potassium chloride, PHI ³ to not more than 1, 3% by weight of a metal micronutrient salt is also mixed - the pH is adjusted to pH 6.5-7.5 by addition of alkali or acid in known manner.