RU2588154C2 - Fertiliser and shuttle with dynamic disintegration, method for production and use thereof in agriculture - Google Patents

Abstract

FIELD: agriculture.

SUBSTANCE: invention relates to substances promoting fertility of soil, and more preferably to fertilisers and solid fertilisers, generally acceptable in any agricultural sector. Mineral fertiliser preferably of alkaline nature contains as an alkaline component inorganic carbonate, wherein it also contains at least one “dynamic disintegration” agent capable of causing a breakdown, considerable fragmentation, dispersion, and considerable “dispersion” inside and/or on surface of granule that tends to cause granule to break down or “explode” when said granule contacts water and/or moisture and preferably with soil and more specifically, with water or soil moisture. Method of producing fertiliser in granules with dynamic disintegration and application of fertilisers are disclosed.

EFFECT: invention enables to make granules more “effective” and to avoid or limit need for soil treatment.

10 cl, 8 dwg, 3 ex

Description

FIELD OF THE INVENTION

The present invention relates to the field of substances that promote soil fertility, and more preferably to fertilizers and fertilizers, acceptable, in General, in any agricultural sector, such as growing crops and forage crops, field crops, oilseeds, legumes, including related industries such as forestry, growing trees in general, growing seedlings of trees, growing vegetables and legumes, or any other agricultural sectors, including meadow farming, growing biomass s, designed to generate energy, cultivate vegetation for environmental and domestic purposes or to spend leisure time on lawns or areas covered with grass, and hereinafter in the description and in the claims the term "fertilizers" is used.

More preferably, the present invention non-limitingly relates to fertilizers and fertilizers containing minerals and more preferably calcium carbonate of any kind and any origin (natural or industrially produced, such as, for example, PCC or precipitated calcium carbonate), and more preferably to fertilizers called "alkaline mineral fertilizers."

Finally, the present invention in a particular way relates to the production of such fertilizers or fertilizers in the form of granules, which have a great ability to "capture" the soil, that is, a great ability to cover the surface of the soil.

BACKGROUND OF THE INVENTION

Traditional granular alkaline mineral fertilizers are generally scattered across agricultural land and introduced through tillage. Compared with powder, they have a great advantage for the user: ease of spreading, less sensitivity to wind, a significant reduction in dust emission. Distribution of sales and supplies is also a significant advantage for suppliers.

However, granulation reduces the agronomic efficiency of these fertilizers: on the one hand, due to the lesser coverage of the soil with fine particles (significantly fewer exposure points per square meter), and on the other hand, due to granulation (compaction or otherwise) and / or due to additives added during granulation. Additives favor shock resistance in spreaders, favor the distribution of granules on the soil under the action of centrifugal forces, and limit dust emission during work operations or spreading, but severely damage the dispersion of the components that make up the granules, which reduces the effectiveness of granular fertilizers.

Of course, granular fertilizers are known in the prior art, but their soil behavior (among other disadvantages associated with production, transportation, handling, dust emission, etc.) is determined by "gravitational decay", that is, the granules are disintegrated by moisture, but crumble around, covering only a circle with a diameter of 2-3 mm.

Since calcium carbonate is very slightly soluble in water, it migrates very weakly in the soil. Thus, for good dispersion of this type of granules, it is necessary to cultivate the soil, which is a great inconvenience for the end user, especially in the case of agricultural systems in which soil cultivation is constrained or impossible (natural meadows, vineyards, forests, golf courses, etc. .).

Some granules contain soluble salts, in particular nitrogen compounds in "nitrate" form. They are highly soluble, dissolve very quickly and enrich the soil due to capillary diffusion without the need to cover a large surface area of the soil.

As the opposite case, very poorly soluble fertilizers are also known, which obviously show an effect only at the point of impact and cover only an area whose area approximately corresponds to the size of the granules, i.e., on the order of millimeters.

Although these problems are well known for a long time, it came as a surprise that industry and interested users were satisfied with the products of the prior art, and according to the applicant, there was no product aimed at eliminating these shortcomings in the case of “professional” use.

TECHNICAL PROBLEM

Thus, in the present invention, the known advantages of the granules should be preserved, and their disadvantages should be minimized by giving them greater ability to cover the soil, but so that they are not significantly sensitive to moisture before spreading, while maintaining resistance to shock when production, loading into bags or in bulk, transportation and final spreading over the soil. Naturally, the requirement is also unconditional regarding the maximum reduction of dust emission and, of course, the preservation of the properties of alkaline mineral fertilizers or fertilizers for "nutrition" or "soil fertilizer".

In addition, the present invention is also directed to making such fertilizers effective even when soil cultivation is not possible or difficult, for example, in the case of natural meadows or vineyards.

The granule must also be mechanically strong at the same time to withstand the production process and transportation, as discussed earlier, and nevertheless be able to "disintegrate" on the soil with a very large soil coverage area, which avoids or limits the tillage (with the exception of some types of agricultural crops, in the case of which, for other reasons, tillage in any case is necessary).

In the following description, only the term “fertilizer” is used to refer to alkaline mineral fertilizers, preferably based on carbonates and more preferably calcium carbonate PCC (precipitated calcium carbonate) and / or GCC (crushed natural calcium carbonate), however, those skilled in the art will understand that the proposed solution also applies, with reservations, to nitrogen, phosphate, potash or other fertilizers, taken alone or mixed with fertilizers, and in the broadest sense, to substances that contribute to soil lodorodiya. The word "fertilizer" for simplicity means all of these options.

It should be noted that the present invention is mainly aimed at making granules more "effective" and avoiding or limiting the need for tillage. The invention is not aimed at reducing the dose, but at making the introduced dose more effective. The end user is likely to continue to use the “usual” doses, but the present invention will allow him not to increase the doses necessary due to the effectiveness reduced due to insufficient dispersion; however, he will be able to clearly notice all the improvements associated with liming or increasing soil fertility, including a higher beneficial effect due to a better action against natural acidification of the soil.

TECHNICAL SOLUTION

The main principle proposed in the present invention is the "dynamic disintegration" of the granules.

By "dynamic disintegration" is understood any form of application of force capable of generating microgranules on a large soil surface near granules deposited on the soil (extended "soil" coverage area), due to cracking, strong fragmentation, and strong "dispersion", acting due to internal force tending to crack or “explode” the granule during its contact with the soil, and more precisely with water and / or soil moisture. The following is an explanation to simplify the concept of “strong fragmentation”.

The adjective “strong” or “strong” means in this case an order of magnitude that is clearly superior to, as will be seen from the examples, the degree of dispersion closest to the known one.

From the following description it will be seen that the purpose of the present invention is a coverage area of the soil, which can reach a diameter of from 2 to 5 cm compared to the coverage area with a diameter of 0.3 to 0.7 cm provided by granules of the prior art.

The comparative sample in this case, of course, is granules of the prior art, while, of course, it is possible to obtain a very good coverage area, especially in the case of powders, but with great drawbacks, such as dust emission, sensitivity to wind, etc. d.

Thus, the present invention uses a feature of the main principle, the purpose of which is to cause the dynamic disintegration of the granules "fertilizer" that occurs when in contact with water and / or soil moisture, that is, to cause cracking or dispersion, or "explosion" of the components (i.e. the parts that make up each individual granule). Thus, the product / soil / water contact area is significantly increased and, consequently, the size, or surface, or volume of the zone of influence of the granule is increased, thus favoring the neutralization reaction that is expected from alkaline mineral fertilizers, or supplying the plant with nutrients contained in granular fertilizers.

Thus, the present invention relates to a mineral fertilizer, preferably of an alkaline nature, containing an inorganic carbonate as an alkaline component and characterized in that it contains at least one “dynamic disintegration agent” which is capable of inducing in the presence of water and / or moisture in the granule and / or on its surface cracking, strong fragmentation, dispersion, strong "dispersion", acting inside and / or on the surface of the granule due to the force tending to split or "look "granulate, when the granule is in contact with water and / or moisture, and preferably with soil, and more specifically with water or soil moisture.

The described phenomenon means "dynamic disintegration", unless otherwise indicated.

The present invention preferably relates to a mineral fertilizer, characterized in that the aforementioned carbonate is a natural or precipitated calcium carbonate.

DESCRIPTION OF THE INVENTION

In the following text, several embodiments of the present invention are described based on the “main principle” indicated above with the same “strong fragmentation of a single granule” function, the function due to the principle being realized due to the internal force arising from contact with free water or air moisture ( for obvious reasons, such contact with environmental moisture should be avoided as much as possible during the entire production, storage and transportation process, as well as during spreading, in order to so that dynamic disintegration occurs on the soil or as close to it as possible for maximum effect) and / or most preferably with soil moisture inside and, if necessary, on the surface of the granule, but mainly inside the granule due to the reaction of at least one of the components of the granule with soil water ( or its moisture) and most preferably with water, which is contained in the granule and which can better carry out its action in the depths of the granule.

The applicant, in accordance with the “main principle” described previously, intended to “dope” an alkaline mineral fertilizer, preferably calcium fertilizer, quicklime (CaO).

However, this ended in obvious failure, since quicklime can, of course, swell when in contact with soil water and crack granules, but before that, since it is an extremely reactive and greedy water-absorbing product, it also reacts when it comes in contact with air moisture and swells . Thus, the granules crack, for example, during transportation or storage, which represents a result that is the opposite of what is desired.

Thanks to this example, it can be seen that the same water, which could favor dynamic disintegration, interferes with the long-term durability of the granules.

This logical solution has already been tested experimentally and discarded for obviousness, which created a prejudice regarding this “swelling” technology; in practice, it is neither possible to remove environmental moisture, nor to transport granules in bags in a vacuum or in an atmosphere of nitrogen or using other solutions that are also impossible.

Thus, the industry once and for all refused such a decision, therefore, the merit of the applicant is to continue all the same this way.

In fact, the applicant took the path of very strong fragmentation as previously determined, but trying to use not a chemically active base such as lime, but at least one acidic additive. This additive, reacting with fertilizer carbonate, can intensively produce bubbles outside and preferably inside the granule, thus causing it to crack.

One would think that an acid supplement, reacting with an alkaline calcium fertilizer, will reduce effectiveness; however, with a low content (about 0.5-2%, and preferably about 1% wt., calculated on the dry matter) used by the applicant, this effect is quantitatively negligible.

It would be logical to use strong acids to maximize the cracking reaction, but they are dangerous to handle, react very strongly according to the test results and, in addition, because of their high reactivity, they create difficulties when introduced during the “process” of production.

One might think about using strong acids, microencapsulated, for example, with a polymer and the like, but such solutions are obviously incompatible with another unconditional requirement of the present invention, that is, with the requirement of economic acceptability. In practice, the technical solutions found should not lead to an excessively significant increase in the cost of granules.

The applicant has considered the use of phosphoric acid, but phosphorus is already commercially available in other embodiments and in this case would be present in very small quantities to be of value to agriculture. The difficulty of introducing a product of this type into the industrial “process” and its corrosive effect led the applicant to decide not to consider this route preferred.

Thus, this solution is possible, but obviously less preferable, since it is difficult to foresee its consequences in relation to its competitive ability described earlier.

The applicant has also tested other acids that are at the same time “weak” so as not to be overly reactive and do not compete with the components of fertilizers or fertilizers of the species described herein.

The applicant has tested known acids that are readily available for sale, such as formic and citric acids, but the evolution of the resulting gas turned out to be insufficient to cause proper dispersion of the granule components in the field; however, under laboratory conditions, fragmentation was achieved, covering a zone of approximately 8-10 mm, which was therefore better than in the case of gravitational disintegration, but did not meet the desire to achieve very strong fragmentation, which was conceived by the applicant.

Molasses (a suspension of sugar obtained from beets), used with a content of 2-3% in terms of dry matter and used as an additive during granulation, well meets the requirements for granulation, but the disintegration of the obtained granules occurs only due to gravity without any dynamic or active.

According to another option, the applicant tested in laboratory and field conditions granules made by introducing acrylic polymers called “anionic superabsorbent” based on net copolymers of acrylamide and potassium acrylate with different particle sizes (from 300 microns to 3 mm) and with different content in the range from 0.1 to 2%. Disintegration tests performed have shown interesting results on dynamic disintegration (see field test results). However, the cost of such a technology and the nature of the polymers used themselves prompted the applicant to show interest in alternative technology, which is less costly and more natural, that is, not resorting to chemical synthesis.

As a result, after all these tests, the decision made by the applicant is to go most preferably and with unexpected results in a completely different way, that is, using a product with medium swellability such as intumescent clay, preferably bentonite type (a well-known intumescent clay that does not make sense to describe ) This clay is used both as a binding agent and as a secondary retention agent in some systems called “dual”, for the manufacture of sheets of paper or cardboard, or as a weighting agent in drilling and similar solutions. Its well-known properties of swelling in water have never been used to effect the "dynamic" fragmentation of the present invention. Quite unexpectedly, the use of bentonite for this specific application revealed the potential for cracking, that is, a very active contribution to the so-called “dynamic disintegration” to a degree noticeably higher than what its simple swelling would suggest in relation to cracking as during control experiments in laboratory conditions , and especially during field tests: after considering unexpected results, but not tied to theory, the applicant came to the conclusion that there is synergy between the natural swelling force and the physical compression stress applied to the carbonate during compaction during production.

This “force” with an unexpected value is unexpected and plays a large role in the present invention.

The traditional granulation method was used, which included adding and adding molasses, then mixing dry fertilizer and bentonite, mixing at high speed, and then feeding between two sealing rollers to form a continuous plate, a kind of “carpet” with a thickness of about 2 to 3 mm, which is then crushed to obtain polygonal granules, which are further eroded and passed through a sieve before obtaining the final granules of a more or less regular shape with a diameter of about t 2 to 5 mm.

The expression "polygonal granules of a more or less regular shape" means granules whose three-dimensional figure, viewed at an angle, has the form of a regular polygon, as well as a polygon whose faces (or planes) are not completely flat, that is, they can be damaged, broken, chipped at the stages of manufacturing, and / or packaging, and / or transportation, and / or scattering.

The first series of tests for the manufacture of IMPERSOL ™ bentonite with different contents from 5 to 1% of the mass. carried out with batches with an initial mass of 10 kg in an experimental setup. These tests made it possible to evaluate the manufacturing method (lack of dust emission, compactability, lack of equipment clogging, good solidity and good moisture resistance during storage, transportation, handling and spreading). With a content of 2%, an excellent technical and economic compromise was achieved with good results on dynamic disintegration in the laboratory. A field test (see the end of the description) on muddy soil after model rain (15 mm spraying) showed excellent dynamic disintegration and fragmentation characteristics, expressed in coverage areas with a diameter of about 3.5 cm.

Then, other manufacturing tests were carried out with batches of 10 tons under industrial production conditions. The obtained granules also showed very favorable cracking ranges in the field, generally amounting to 2 to 4 cm and even more when the content was in the range of 1.5 to 3% by weight, with a spread of results from 2 to 3 cm at a similar content in 2% of the mass.

In the technical data sheet on IMPERSOL ™, this product is characterized as clay belonging to the smectite group. In appearance, it is a light powder with a water content of not more than 14%, a sieve residue of 75 μm (in a dry sample) not more than 30% and a density of 2.3 g / cm ³ .

Other usable clay

Other clays are acceptable if they are capable of swelling due to their structure and cause cracking of the granules. In practice, tests conducted by the applicant with other clays did not provide a systematic obtainment of the expected effects.

Other usable minerals

Tests were conducted with various materials as a carrier: with calcium carbonate of natural origin obtained from different quarries, dolomites and a mixture of dolomite with calcium carbonate.

These natural or precipitated (PCC) carbonates can be used in mixtures with each other, and other minerals other than natural or precipitated (PCC) calcium carbonate can be used, replacing fully or partially one or more of these carbonates with minerals such as dolomites, natural phosphates in mixtures with fertilizer (for the use of P ₂ O ₅ introduced for plant nutrition, and not because of its acidifying effect), ammonia nitrogen fertilizers or other fertilizers. These substances are well known to specialists in this field of technology, therefore, in this description they are not described in detail.

Nitrogen fertilizers and potassium salts are not considered, as they are readily soluble in a natural way.

The present invention can be better understood by reading the following examples which are given in a non-restrictive manner.

A. Compaction Examples

The applicant has carried out compacting tests using various components designed to impart dynamic disintegration properties.

In these compacting tests, the following indicators were adopted to evaluate the prospects and results for each product tested and to select products depending on various indicators:

• resistance of the plates;

• hot disintegration quality;

• cold tests in water and wet cotton;

• cost of products.

B. Dosage Examples and Results

Impersol ™ bentonite was tested at a content of 5, 2, 1 and 0.5% of the mass. powder material serving as a carrier.

In the case of other products, the effectively investigated range was wider to a lower content: 0.01%. The upper limit was dictated by a decrease depending on the content of elements contributing to soil fertility, or on the value of the neutralizing ability of the granules and on the increase in cost.

An additive content of about 10% is possible and has been investigated, but is associated with unnecessary costs compared to improved properties.

Then the content was gradually lowered.

A lower bound with a value of 0.5% corresponds to an improvement that is almost imperceptible with respect to the untreated control sample and, thus, defines a lower bound (a value of 1% seems more realistic).

The previous examples limit the effective range (including the rise in price for the end user), which is preferably around a value of 2%.

C. Results for bentonite

Granules with the addition of the previously described Impersol ™ bentonite in varying amounts were used.

In the case of each content value and also the variant without additives (control sample), 16 granules were placed on agricultural land on a lattice with 5 × 5 cm cells. A piece of the plate obtained after the compaction rollers was also placed in the middle of the lattice (then the plate was crushed to obtain granules ) The study of this piece of plate is of interest, although, of course, it represents granules that are used in the field.

By means of a Berthoud ™ knapsack sprayer equipped with a slot nozzle, an irrigation of 15 mm was carried out above this grate.

The amount of model rain was controlled by a rain gauge.

Photographing was carried out before and especially after modeling rain in the case of each of the tested values of the content and control sample.

The attached figure 1 (zone 67) shows the test of control granules, that is, without bentonite. The granules and a piece of the plate remained intact or almost intact even after rain in an amount of 15 mm.

The attached figure 2 (zone 70) shows granules containing 1% bentonite. You can see visible traces of the dynamic disintegration of the present invention already with good coverage of the zone.

The attached figure 3 (zone 69) shows the results when the content of 2% bentonite. You can see the disintegration in excess of the disintegration shown in figure 2, while some of the granules turned into powder, covering already a significant area. You can also see the dynamic disintegration manifested on a piece of the plate.

The attached figure 4 (zone 68) shows the results when the content of 5% bentonite. You can see that there is only one granule left (bottom left), which seems to be destroyed less than others, nevertheless traces of white color cover a wide area around it.

A comparison of documents, photographs and graphs shows very good consistency.

Surface Survey Technique

1) Measurement of soil capture surface

The resulting photographs were brought to a single scale.

When comparing overlay, deviations are visible visually.

For greater accuracy and factuality, the boundaries of soil capture of each of the 16 granules in the case of each test variant were noted by two vertical lines:

untreated control granule before rain;

untreated control pellet after rain in an amount of 15 mm;

treated pellet with 1% Impersol ™ after rain in an amount of 15 mm;

treated pellet with 2% Impersol ™ after rain in an amount of 15 mm;

treated pellet with 5% Impersol ™ after rain in an amount of 15 mm.

Then measured the distance between the two features.

Next, the values of 16 diameters were summarized, which gives a sufficiently representative and in all cases reproducible value of the capture of the soil surface.

These values are fully confirmed visually.

These values were used as performance indicators.

The value of the one-dimensional variable “sum of diameters over 16 granules” was squared to determine a two-dimensional surface parameter closer to the desired result (“surface coverage” parameter).

The obtained values were compared between different options.

You can see that the options "untreated control pellet before rain" and "untreated control pellet after rain in the amount of 15 mm" are identical. Thus, with all other conditions being equal, the results of dynamic disintegration can be associated only with the influence of the additives used.

2) The resulting curves

Based on the results obtained, several curves were plotted depending on the content of Impersol ™:

- the value of the neutralizing ability (figure 5);

- appreciation (Fig.6);

- the sum of the diameters of 16 granules (Fig.7);

- covered surface (previous value squared) (Fig. 8).

The values of the areas covered by the surfaces were multiplied by a coefficient in the range from 1 to approximately 10, depending on the test variant.

From placing the curves under each other, it becomes clear that for the optimal range you need to find a compromise between:

increase in the covered surface;

increase in value;

a decrease in the value of neutralizing ability.

These curves can help those skilled in the art adapt the values and ranges of contents described previously to the particular application they provide.

3) Selection of the range of content of the additive

Taking into account the curves, this compromise was found by the applicant at a content of about 2% and preferably in the range from 1 to 3%, since at a content of about 2% there is an inflection point of the area increase curve (the point from which the cost increases faster and the value of the neutralizing ability decreases faster than the increase in the covered surface).

It clearly follows from this that when the content of the additive is more than 5%, the effect will not increase to a large extent, while the slope of the “surface” curve becomes very small.

One can note the appearance of an asymptotic plateau with a content of more than 5%.

Thus, the curves given in the appendix fully confirm the values of the content and its ranges described earlier.

At the same time, it was unexpected to state that with a content of approximately 4-6% and especially 5-6%, a “plateau” appears on the curve “Sum of diameters of 16 granules - f (% of additive content)”.

This plateau is shown in Fig.7 "Change in the sum of the diameters of 16 granules."

Regarding the reduction in the fraction of fine particles that must be recycled during the process (since the Impersol ™ treated granules at the outlet of the seal seem to produce less dust (particles with a diameter of less than 1 mm), it should be noted that this reduction in dust generation represents a significant advantage in this industry.

The lower limit of the range is near the value of 0.5-0.7% (the result is very mediocre, but the cost is low), and the upper limit is near the value of 5-6% or 6-7%, because with a higher value, two harmful effects can be noted. consisting in the fact that the value of the neutralizing ability or the content of useful fertilizer elements decreases when the clay content increases, while the cost becomes so high that the effect of additional disintegration does not justify this rise in price.

Thus, the range, which is effective and fairly low-cost and does not lead to an excessive "decrease" in the value of neutralizing ability or content, is from 2 to 4%, preferably 2-3%, and the optimal value, apparently, is about 2%, that is from 1.8 to 2.3% according to the attached figures.

Those skilled in the art can understand that the lower bound is dictated by the appearance of a noticeable dynamic disintegration effect, while the upper bound is rather dictated by the fact that the additional dynamic disintegration is not significant enough to justify the extra cost.

Those skilled in the art can also understand that these ranges can vary from one clay to another, however deviating slightly from the previously given values, and that they can therefore adjust the content depending on the intumescent clay used, by performing a few simple tests using standard program and comparing them with the examples given in the present description. Finally, those skilled in the art can extrapolate the previously obtained values to other intumescent clays, as the manufacturer indicates the percentage swelling in their technical passports: for example, you can easily count in comparison with the Impersol ™ product, for which the technical passport Edition 02 of 08/23/2002, a swelling of at least 11 ml / g is indicated (CTIF test, recommendation 403).

Detailed test method for field disintegration to characterize the present invention

goal

This test aims to monitor the variation of treated or untreated pellets on moistened agricultural land, which is watered with an equivalent of 15 mm of rain by means of a knapsack.

EXPERIMENTAL PLAN

1st stage

- Preparation of approximately 1 × 1.30 m in size from a nearby adjacent plot of artificial plot with good visibility to facilitate photography without interference from vegetation.

- Initial artificial humidification to achieve moisture comparable to that of the original site, as the selected soil dries out very much.

The initial state is adjusted by drying to the absence of free water and to a state corresponding to field conditions.

- A breakdown into 12 squares measuring approximately 30 × 30 cm.

- Placement of 16 granules in cells with a side of 6 cm in a lattice measuring approximately 24 × 24 cm in each square and placing a fragment of the manufactured plate in the center.

- Testing of three products that were recognized as most effective during previous tests, and photographing in the case of a control sample and three values of the content of additives that differ depending on the product:

• a superabsorbent network copolymer of acrylamide and potassium acrylate, such as the product AQUASORB ™ KC, selected preferably, but not limited to;

• clay with medium swelling of the type previously described, such as IMPERSOL ™, selected preferably, but not limited to;

• lemon acid; as indicated earlier, citric acid is a weak acid that can be used according to the present invention, but, however, is obviously less preferred than intumescent clay or clay with medium swelling or superabsorbent network copolymer. This product is used in this case to better mark the "reasonable" boundaries "of the present invention;

• for better visual comparison, untreated control samples are placed in the upper row, processed samples with a high content (maximum contrast) are placed directly below them, samples with an average content are placed even lower, and finally, samples with a low content are placed at the very bottom.

Each primary square is assigned a number from 63 to 74, first from top to bottom, then along the following columns from left to right.

• Sample A: Aquasorb KC ™:

• control sample A: control sample without Aquasorb KC ™ (No. 63);

• A, 0.1%: contains 0.1% Aquasorb KC ™ (No. 66);

• A, 0.15%: contains 0, 15% Aquasorb KC ™ (No. 65);

• A, 0.2%: Contains 0.2% Aquasorb KC ™ (No. 64).

• Sample B: Impersol ™:

• control sample B: control sample without Impersol ™ (67);

• B, 1%: contains 1% Impersol ™ (70);

• B, 2%: contains 2% Impersol ™ (69);

• B, 5%: contains 5% Impersol ™ (68).

• Sample C: citric acid, powder:

• control sample C: control sample without citric acid (71);

• C, 0.5%: contains 0.5% citric acid (74);

• C, 1%: contains 1% citric acid (73);

• C, 2%: contains 2% citric acid (72).

- Obtaining photographs for each square for the purpose of subsequent comparison of changes.

2nd stage

- Taking photographs at the following stages:

• T1 at 0 mm of artificial precipitation;

• T2 at 5 mm of artificial precipitation;

• T3 at 15 mm of artificial precipitation.

ANALYSIS OF RESULTS

The differences are clearly identified:

between control samples and samples with additives;

between cases of different contents of the same additive;

between different additives.

- Comparison in the case of three values of the percentage of Aquasorb ™ (+ control sample) at 15 mm.

In the case of Aquasorb ™, very good disintegration at 0.2% is much more distinct than at 0.1 and 0.15%.

- Comparison in the case of three values of the percentage of intumescent clays (+ control sample) at 15 mm.

Excellent disintegration achieved.

> Comparison in the case of three values of the percentage of citric acid (+ control sample) at 15 mm.

There is some effect compared to the control sample, but significantly less noticeable than in the case of other additives. Thus, citric acid is the least effective of the three products tested.

The conclusion corresponds to the estimates indicated earlier.

Specialists in the art can understand that the fertilizer is technically adapted for each individual case in order to form a soil coverage area that can reach from 2 to 5 cm in diameter for standard sized granules with a thickness of 2 to 5 mm, and this granule has the form polygons of a more or less regular shape, and can easily make technical adjustments based on the description and examples given earlier.

Claims (10)

1. The mineral fertilizer is preferably alkaline in nature, containing inorganic carbonate as the alkaline component and characterized in that it contains at least one “dynamic disintegration agent” which is capable of causing cracking, strong fragmentation, dispersion, strong “dispersion” in the granule, acting from the inside and / or on the surface of the granule due to the force tending to crack or “explode” the granule when the granule is in contact with water and / or moisture, and preferably with soil and, more precisely, with water or soil moisture,
where the dynamic disintegration agent is selected from weak acids, such as formic, citric, or, less preferably, phosphoric acid, or
the dynamic disintegration agent is a superabsorbent anionic polymer such as net copolymers of acrylamide and potassium acrylate, insoluble in water, or
the dynamic disintegration agent is bentonite with a water content of not more than 14%, a sieve residue of 75 μm (in a dry sample) of not more than 30% and a density of 2.3 g / cm ³ ,
moreover, the granules are made with the possibility of forming zones of soil coverage, which can reach from 2 to 5 cm in diameter for granules of standard size with a thickness of from 2 to 5 mm. 2. Mineral fertilizer according to claim 1, characterized in that the carbonate is a natural or precipitated calcium carbonate (PCC). 3. Mineral fertilizer according to claim 1 or 2, characterized in that the granules are in the form of a polygon of a more or less regular shape. 4. The mineral fertilizer according to claim 1, characterized in that bentonite is a clay belonging to the group of smectites and externally having the appearance of a light powder with a water content of not more than 14%, a sieve residue of 75 microns (in a dry sample) not more than 30% and a density of 2.3 g / cm ³ . 5. Mineral fertilizer according to claim 1, characterized in that bentonite is introduced into the granules in an amount of from 0.5-0.7 to 6-7% by weight. in terms of dry matter of the material to be granulated, preferably from 1 to 6-7% and more preferably from 1 to 5%, preferably about 2, 3 and 4%, or more preferably 2% of the mass. in terms of dry matter. 6. The mineral fertilizer according to claim 2, characterized in that the calcium carbonate is completely or partially replaced by one or more other minerals, such as dolomites, natural phosphates mixed with fertilizer, nitrogen ammonia fertilizers or other substances that promote soil fertility, or mixtures thereof . 7. A method of manufacturing a fertilizer in granules with dynamic disintegration according to any one of paragraphs. 1-6, characterized in that the traditional granulation is carried out by adding and introducing molasses, dry mixing of fertilizer and a dynamic disintegration agent, which is or contains:
bentonite from the calculation of 0.5-0.7 to 6-7%, preferably from 1 to 6-7%, more preferably from 1 to 5%, preferably about 2, 3 and 4%, and more preferably 2% of the mass. in terms of dry matter of the material to be granulated, mixing is carried out at high speed, followed by feeding between two sealing rollers to form a continuous plate, a kind of "carpet" with a thickness of about 2 to 3 mm, which is then crushed to form polygonal granules, which are then eroded and passed through a sieve before obtaining the final granules in the form of more or less regular polygons. 8. The method according to p. 7, characterized in that the fertilizer contains natural calcium carbonate or precipitated calcium carbonate (PCC). 9. The method according to p. 8, characterized in that the calcium carbonate is completely or partially replaced by one or more other minerals, such as dolomites, natural phosphates in a mixture with fertilizer, ammonia nitrogen fertilizers or other substances that contribute to soil fertility, or mixtures thereof. 10. The use of fertilizer in paragraphs. 1-6 in the field of soil fertility enhancing substances, more preferably fertilizers and fertilizers, generally acceptable in all agricultural sectors, such as growing cereals and fodder crops, field crops, oilseeds, legumes, including related industries, such such as forestry, growing trees in general, growing seedlings of trees, growing vegetables and legumes, or in any other branches of agriculture, including meadow farming, growing biomass intended for harvesting heel energy culturing vegetative covers environmental and household purposes or for recreation on lawns or areas covered with grass.

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