NO123464B - - Google Patents

Description

Non-dusting, non-caking fertilizer

agent with good storage capacity.

The storage of mineral fertilizers often leads to caking of the individual fertilizer grains or salt crystals, whereby in many cases a complete hardening of the initially loosely stored products is produced. The combination is effected i.a. by dissolution on the salt surface by absorption of moisture, during which the influence of weather and wind during transport and during storage is of significant importance. It is understandable that agriculture finds the spreading ability of mineral fertilizers to be of the greatest importance.

There has been no shortage of attempts to remove the aforementioned difficulties, during which so-called powdering of the fertilizers with a protective layer of a finely divided or powdered substance brought about improvements (cf. DBP 925 298). When handling such powder-treated fertilizer grains, however, it is unavoidable that dust formation occurs.

It is also known to counteract the caking of fertilizers by coating the grain surfaces with paraffin oil, tar oil, vegetable oil, etc. (Coll. British patent specification 583 388, US patent specification 2 118 438 and German patent specification 1 062 713). However, the adhesiveness of such oils is less satisfactory, often the substance layer is also destroyed, which must presumably be attributed to the fact that the oils are at least partially or completely absorbed by the porous salt surface.

It is also known to coat fertilizers with a protective layer of film-forming compounds, under which e.g. have been used urea-formaldehyde condensates and polyoxyalkylene nsr. (Compare US patents 2,502,996 and 2,734,002 as well as Belgian patent specification 600,133). Below, it is a prerequisite that in order to achieve a good protective effect, a protective layer must be applied in quantities of more than 1 percent by weight, based on the weight of the fertiliser. These relatively large amounts of protective layer substance mean increased costs.

From the German specification 1 467 381 it is known to produce non-dusting and non-caking fertilizers by applying a layer of drying, oily substances to the fertilizers and then drying the coatings, applying to the fertilizers 0.01 to 0, 6 percent by weight, based on the amount of fertilizer, of drying oily polyene polymers, which are isomerized and/or made reactive by the passage of air or oxygen, after which the coatings are dried in the usual way. With this method of working, one can apparently manage with smaller quantities of layer-forming substances, but these must, however, be subjected to special special work steps before application to make them reactive.

There was therefore the task of providing non-dusty, non-caking, well-storable mineral fertilisers, which are surrounded by a protective layer of substances which do not require any special pre-treatment before their processing.

The invention is directed to non-dusting, non-caking, well-storable fertilizers that are enveloped with a protective layer. The characteristic feature is that the protective layer is present in amounts of 0.02 to 0.5% by weight, in particular from 0.05 to 0.25% by weight, based on the fertilizer mass, and entirely or at least 75% by weight consists of waxy polyethylene with a molecular weight of 500 to 10,000, while the possible remainder consists of aliphatic, primary amines with C-numbers from 6 to 24, and/or aliphatic, secondary amines with C-numbers from 12 to 48 and/or aliphatic, tertiary amines with C-numbers from 12 to 60 and/or polymerization products of propylene oxide and ethylene oxide with a proportion of 10 to 80 weight percent ethylene oxide and molecular weight of 1,800 to 10,000.

The technical effect can be achieved in a simple way, because the protective layer on the granulate prevents the influence of atmospheric moisture on the hygroscopic fertilizer salt, without, however, adversely affecting the excellent dissolution properties of the fertilizer salt. It could be determined by comparative tests that the water absorption of the fertilizers provided with a protective coating according to the invention is approximately equal to the corresponding powder-treated fertilizers, while their tendency to cake is significantly less. The grains held according to the invention exhibit an excellent trickling or spreading ability. Powder treatment of the products is no longer necessary, although of course if desired, powder substances can also be used.

According to one embodiment of the invention, the starting point is waxy polyethylenes which have melting points from 50 to 120, especially 85 to 115°C. The use of low-pressure polyethylenes produced according to the Ziegler process is particularly suitable.

Within the scope of the invention are covers that contain at least 85% by weight of the waxy polyethylene and at most 15% by weight of at least one of the amines, which are of particular technical importance.

According to one embodiment of the invention, the coating contains at least 85 percent by weight of waxy polyethylene, while the remainder consists of the polymerization product of propylene oxide and ethylene oxide.

Good results were also obtained with coatings that contain at least 85% by weight of waxy polyethylene, up to 10% by weight of amine and up to 5% by weight of the polymerization product of propylene oxide and ethylene oxide. The polymerization product of propylene oxide and ethylene oxide, which is optionally incorporated into the protective layers, then gives particularly favorable results when it contains 70 to 90, especially 80 percent by weight of ethylene oxide and exhibits a molecular weight of 6,000 to 9,000, especially 8,000 to 9,000.

Among primary amines with C-numbers from 6 to 24, those with 9 to 22, especially 12 to 20 C atoms are of particular importance.

Of the aliphatic secondary amines, those with 18 to 30 C atoms are of particular technical interest. Of the aliphatic, tertiary amines, those with 18 to 39 C atoms are preferred.

The amines listed below have proven to be particularly valuable:

Stearylamine

Cetylamine

Mono-iso-tridecylamine

Mono-i so-nony1amine

n-propy1-i so-nony1amine

Dimethyl-iso-tridecylamine

Di-iso-tridecylamine

Tri-iso-tridecylamine

The production of the fertilizer according to the invention conveniently takes place in such a way that at least 80°C hot, shaped fertilizers are mixed with the coating mass heated to 120°C, preferably in liquid form, and the mixture is allowed to cool under constant mechanical movement.

Fertilizers that must be coated according to the invention are, for example, the following: mineral fertilizers, such as inorganic salts or mixtures thereof where alkali or alkaline earth metals or ammonium are present as cations, while those containing chlorides, sulfates, phosphates, nitrates or carbonates as anions, urea, derivatives thereof and salts. Support elements can of course also be present.

The fertilisers, which are generally available in ball form, granulated form or in crystalline form, can be enveloped with the protective layers according to the invention in equipment which is usually used in plants for the production of fertilisers.

The determination of the molecular weight takes place by indirect determination of the vapor pressure reduction, e.g. by means of ebullio-scopy or vapor pressure osmometry.

In order to be able to comment on the storage conditions, the fertilizers were subjected to a laboratory test as can be seen from the subsequent data in the examples, during which the fertilizer to be examined was first treated for 30 minutes in a climate cabinet with air of 40°C and 75% relative humidity . In connection with this, the fertilizer was introduced into a mold and dried under nitrogen. The mold was then removed from the baked sample and the sample was broken into pieces in a test apparatus of the type used in the metal industry to measure chip impact strength. The measure of the degree of compaction applies to the loss of kinetic energy when passing through

_3

the sample, which is indicated in 10 m kp. For the assessment, each time four samples of the material to be examined were compared with two comparison samples.

The application of the coating took place in a laboratory drum without built-ins at 42 rpm. Here, each time 5 kg of fertilizer was taken hot from the ongoing production and introduced into the drum preheated to 90°C. After the filling had assumed a temperature of 90°C, the mostly 120 to 130°C preheated protective layer mass was added in an amount of up to 0.25% by weight. The drum then rotated for 1.5 minutes, after which it was cooled to 45°C. Further cooling to 30°C took place by spreading the fertilizer on the floor.

The results obtained are reproduced in the examples. A mineral fertilizer consisting of granulate was used in all cases. The diameter of the balls was 2 to 4 mm.

Example 1

This example illustrates the results obtained with a protective layer consisting exclusively of waxy polyethylene.

Fertilizer: Multi-component fertilizer containing 18 parts

N : 9 parts P205 : 18 parts K20.

Applied protective layer compound: Polyethylene.

Wrapping temperature: 90°C.

Wrapping time: 1.5 minutes.

Example 2

This example illustrates results obtained with protective layers of combinations of polyethylene with stearylamine. Fertilizer: Multi-component fertilizer, containing 13 parts

N : 13 parts P205 : 21 parts K20

The sample was two different samples I and II. The protective layer consisted of 90 weight percent polyethylene and 10 weight percent stearylamine.

Total amount applied: 0.16

Wrapping temperature: 90°

Wrapping time: 1.5 min.

Example 3

This example gives results obtained in a large-scale trial with a protective layer of combinations of waxy polyethylene with stearylamine.

Fertilizer: NP fertilizer, containing 20 parts N :

20 parts P205.

The protective layer consisted of 90 weight percent waxy polyethylene and 10 weight percent stearylamine. 320 kg of the mixture of polyethylene and stearylamine was applied to 200 tonnes of the fertiliser.

Total amount applied: 0.16% by weight

Wrapping time: 1.5 to 2.0 min.

Trial duration: approx. 10 hours

Example 4

This example reproduces results obtained with protective layers of combinations of polyethylene with a polymerization product of propylene oxide and ethylene oxide.

Fertilizer: Multi-component fertilizer containing 13 parts

N : 13 parts P205 : 21 parts K20

Total amount applied: 0.15%

The polymerization product's content of ethylene oxide:

80 percent by weight, molecular weight approx. 8700. Wrapping temperature: approx. 90°C.

Wrapping time: approx. 1.5 min.

Example 5

The subsequent series of tests of this example reproduced in tables 1 to 8 were carried out with the following multi-component fertilisers:

In all experiments, a protective layer consisting of 90 parts polyethylene of the melting range 85 to 105° and 10 parts amine was applied, unless otherwise stated. The total amount of protective layer applied to the fertilizer grains was 0.15% by weight.

Under the term "powdered" are listed the results of comparison tests, in which the fertilizer grains were powdered with 0.9 weight percent diatomaceous earth.

Under the term "polyethylene + stearylamine" are listed in tabular form results obtained for the same fertilizer taken from production, when this had been enveloped with a mixture of polyethylene and stearylamine.

The test series reproduced in Table 8 relates to the use of C2q - C22-ami-n- After this test series, the application of the coating substances took place in a laboratory drum without built-ins of 17 cm diameter at 50 rpm. Below this, each time 2 kg of fertiliser, the temperature of which varied from 100 to 105°C, was added to the coating substance in solid form as powder and the drum was allowed to rotate for 2 minutes. The enveloped hot fertilizer was transferred to a laboratory cooling drum fitted with built-ins and cooled by passing a large amount of cooling air for 4 minutes to 30°C.

The bonding experiment was carried out according to the method described in the periodical "Chemie-Ingenieur-Technik", vol. 40 (1968) booklet 4, pages 191-192, during which the temperature was changed to 45°C, the load to 20 kg and the duration 6 day and night. The shear stress values listed in Table 8 as measures for the bonding are mean values of each time 10 individual measurements.

Example 6

In this example, the water absorption and caking tendency of multi-compound fertilizers are compared (13 parts N, 13 parts P205 < 2i parts K20). In the case of sample 1, it was a fertilizer only powdered with diatomaceous earth, sample 2 is a fertilizer provided with a polyethylene protective layer containing a stearyl amine. The samples were simultaneously exposed to a stream of air heated to 45°C with 70% relative humidity for different periods of time and then the water content and the tendency to cake were determined.

As can be seen from the examples, the water uptake by powdered fertilizer and by a fertilizer provided with a protective layer is approximately the same, while the caking tendency of the fertilizer enveloped with a protective layer is significantly less. At a relatively high water absorption corresponding to a water-between

content above 5%, one can observe an approximation of the caking tendency measured by the impact number of exclusively powdered fertilizer and fertilizer provided with a polyethylene protective layer. However, under normal storage and transport conditions such a high water absorption is not obtained in any case.

The results reproduced above were also confirmed by dissolution tests. For this purpose, each time 20 g of powdered fertilizer resp. fertilizer provided with a protective layer suspended in 100 ml of water. After the same time was filtered off, and the solution formed was analyzed analytically. It turned out that the same multi-substance concentration was present in both solutions.

Claims (4)

1. Non-dusting, non-caking fertilizer with good storage capacity, with a protective layer containing polyethylene and which envelops the fertiliser, characterized in that the protective layer is present in amounts of 0.02 to 0.5% by weight, in particular from 0.05 to 0, 25 percent by weight, based on the fertilizer mass, and all or at least 75 percent by weight consists of waxy polyethylene with molecular weights from 500 to 10,000, while the possible remainder consists of aliphatic, primary amines with C numbers from 6 to 24 and/or aliphatic , secondary amines with C-numbers from 12 to 48 and/or aliphatic, tertiary amines with C-numbers from 12 to 60 and/or polymerization products of propylene oxide and ethylene oxide with a proportion of ethylene oxide from 10 to 80% by weight and molecular weights from 1,800 to 10,000 . 2. Fertilizer as specified in claim 1, characterized in that the waxy polyethylene used has melting points from 50 to 120°, in particular from 85 to 115°. 3. Fertilizer" as stated in claims 1 and 2, characterized in that the waxy polyethylene used is low-pressure polyethylene. 4. Fertilizer as specified in claims 1 to 3, characterized in that the coating contains at least 85% by weight of waxy polyethylene, up to 10% by weight of amine and up to 5% by weight of the polymerization product of propylene oxide and ethylene oxide.