DE1075642B - Process for the production of power-clumping, power-caking and free-flowing mixed fertilizers - Google Patents

Description

Process for making non-clumping, non-caking and free-flowing mixed fertilizers The invention relates to a method of production of non-clumping, non-caking and free-flowing mixed fertilizers, especially NPK fertilizers, by adding caking agents Fabrics. This method is characterized in that the mixed fertilizer grains with about 0.025 to about 2 kg / ton of a cationic amine of the formulas RNH2 or RNHCH2CH2CH2NH2, in which R is an aliphatic hydrocarbon radical with 8 to 22 carbon atoms, or with salts of these amines with hydrochloric acid, acetic acid or fatty acids having 6 to 22 carbon atoms using 25 to 750/0 but Solutions of these amines and treatment temperatures of 65 to 121 "C coated in this way that on each mixed fertilizer grain a more uniform and coherent one Amine filin is formed.

In the method according to the invention is preferably used as a solvent for the cation-active amine, at least one aliphatic nitrile having 6 to 22 carbon atoms is used, and it is also preferable to add a surfactant to use.

The formation of lumps during storage has occurred with mineral fertilizers presented a serious and annoying problem for a long time. A mineral one The fertilizer can become so hard that the caked fertilizer is in the sack becomes rock hard. The consumer has to smash the mass with a sledgehammer in order to be able to spread the fertilizer in spreaders. Even then, clog the remaining lumps often still reach the spreader and thus prevent them from becoming even Spread the fertilizer, and this also leads to a loss of time during the Time of spring ordering.

For the fertilizer industry itself, however, the clumping does lead also to economic problems.

During deposition, a heap of manure can become so hard that Before the bagging, the mass has to be blown open. This appearance also prevents the industry from storing its products for a very long time, and They also cannot take advantage of the usual treatment devices of bulk goods, such as those used in the grain industry, for example be used.

Various approaches to solving this problem have already been tried some with some success. Perhaps the most significant The recent development has been the manufacture of granulated fertilizers. When granulating, the fertilizer is broken down into small individual particles of roughly more uniformity Split size, the diameter of which is between 1 and 4 mm. For fertilizer mixtures the granulation prevents separation of the individual components and reduces their Tendency to form lumps and become sticky. These improved properties the granulated or granulated fertilizers in terms of their tendency to form lumps are likely due entirely to the reduced area of contact between the single particles.

However, even the granulation does not always lead to a complete one free flowing product. In the case of fertilizers with higher levels of plant nutrients, like 12-12-12 [d. H. 12 O / o nitrogen (N), 120 / o phosphorus pentoxide (P2O) and 120/0 Potassium Oxide (K2O)], becomes the ideal state of a free flowing fertilizer most of the time even with the granulation - not achieved.

The hygroscopic salts of such fertilizers absorb moisture from the air, and this creates caking in the sacks. To such To make fertilizers flow better, you already have the particle surfaces with you covered with mineral dust, for example with finely divided clay, lime, magnesium oxide, Vermiculite dust and various other similar materials. To better adhesion to get, these inerts have also been used with binders, e.g. B. finely powdered Polysaccharide glycolic acid ether. It will be around 5 to 10 kg / ton and even up to 25 kg of such substances per ton of fertilizer are required, and although some these additives have somewhat improved properties in terms of lump formation give, but at the same time they reduce the concentration of the actual plant nutrients and therefore result in end products of lesser value.

An additional drying of the fertilizer is sometimes effective to reduce the tendency to lump formation, but at the same time the capital requirement enlarged, if additional devices have to be procured for this, or the The capacity of the plant is reduced if the product is dried for additional purposes is passed through the existing devices several times in the circuit. These measures also increase fuel costs.

Various researchers have tried this problem by using of special materials such as oils, waxes, soaps and synthetic detergents and Detergents such as sodium alkylarylsulfonate. None of these means but has proven to be very effective, and the fertilizers treated with them have the favorable properties initially bestowed on them with respect to Lump formation is lost again after a short storage period. To prevent A wide variety of substances have already been proposed for the formation of clumps. With these were they either acidic compounds such as naphthalene sulfonic acids or Sulfamic acid. Surfactants have also been used. With these they are anion-active substances such as polyacrylic acid or water-soluble ones Ethylenecarboxylic acids, and it is already known that used for granulation Binding agents also add wetting agents, i.e. surface-active substances.

The use of cationic amines in the manufacture of Potash-containing fertilizers have also been proposed. It is about in this case, however, it is not about the coating of the granules, but about these surface-active substances Amines were used as flotation agents in the production of the potash salt in the dissolving process used.

A particular advantage of the method according to the invention is that that even with high moisture contents in the air and in the fertilizer itself, non-clumping, free flowing fertilizers can be obtained.

Because untreated fertilizer mixtures stick together the faster, the greater the moisture content, it was considered that there was practically no lump formation more would occur if the final product had a moisture content of 0.5 0 /, maintained. However, this moisture content of 0.5 01o is already for economic reasons not desirable because the drying devices the factory would have to be expanded to accommodate such a low moisture content to achieve, or one would have to significantly reduce production, for example by about 500 / o. Even if such an end product is produced in an economical manner protection from atmospheric moisture would be required, because the hygroscopic salts contained in the fertilizer mixture are not attached can be prevented from absorbing the moisture from the air except one pack them in a moisture-proof bag. It has been shown that the improved Fertilizers according to the invention have a moisture content of up to 30 / o can and yet sufficient for commercial use, a clump formation have counteracting properties.

In the present description and claims, the means Expression)> fertilizer mixture «a mixture of two or more of the common ones Fertilizer components in divided form. The usual fertilizer components consist of water-soluble, inorganic salts, such as acid-treated phosphate rock, superphosphate, Triple superphosphate and nitrophosphate, ammonium sulfate, ammonium nitrate, sodium nitrate, Potassium nitrate and potassium carbonate and potassium chloride.

Examples of amines suitable for the purposes of the present invention are octylamine, decylamine, dodecylamine, tetradecylamine, hexadecylamine, octadecylamine, Octadecenylamine, octadecadienylamine, octadecatrienylamine, eicosylamine and mixtures such amines as mixed by ammonolysis, dehydration, and hydrogenation Fatty acids are obtained from the hydrolysis of naturally occurring vegetable and animal fats, for example from coconut oil, soybean oil, tallow, Cottonseed Oil and the like Two particularly suitable amine mixtures are commercially available. One of these mixtures contains about 2 ° lo tetradecylamine, 240 / o hexadecylamine, 280 / o Octadecylamine and 46 ovo Octadecenylamine and is made from sebum, the other contains about 200 / o hexadecylamine, 170 / o octadecylamine, 260 / o octadecenylamine and 370 /, octadecadienylamine and is made from soybean oil.

Suitable aliphatic trimethylenediamines, which in the context of the present Invention can be used in implementing the specifics mentioned above primary aliphatic amines with acrylonitrile and subsequent reduction of the nitrile group obtained by means of hydrogen. Connections of this type are also commercially available, z. B. two mixtures of aliphatic triniethylenediamines, which are preferred in the context of the present invention find use, and they are obtained by adding Acrylonitrile to the mixtures of primary aliphatic amines described above made from tallow or soybean oil, and subsequent Get hydrogenation.

For the purpose of producing the fertilizer mixtures improved according to the invention the individual particles of fertilizer are coated by the untreated fertilizer particles with the aliphatic amine-containing compounds brings into contact under such conditions that a uniform coating support financially. The uniform coating of the fertilizer grains can be done in different ways Species happen. With the concrete mixer used in Example 2 below the grains z. B. uniformly and continuously coated within 3 to 5 minutes. Other methods that have been tried so far are spraying the particles while they are on the conveyor belt or while they are leaving the conveyor belt, or you just need to drip (spray) the pulling substance onto the particles while they move on the conveyor belt. It can also be a rotary kiln can be used with a number of layers, with the coating substance in the rotary kiln is sprayed onto the particles. After each of these procedures, the one you want Result achieved in a short time. Many of the amine-containing substances described are solid bodies or viscous liquids at ordinary temperature, which im generally on the number of carbon atoms in the hydrocarbon chain or on the ratio of the proportion of short-chain compounds to the proportion of longer-chain compounds Compounds in the mix depends. Preferably, therefore, the contact takes place at elevated temperatures, for example between about 65.6 and 1210 C, instead of so to increase the spreadability of the amine-containing material. As the untreated fertilizer at the usual procedure is dried with the application of heat, there is one preferred measure for coating therein, the amine-containing agent about that Preheat temperature at which the fertilizer particles enter the dryer leave, and then mix it carefully with the same before they have time, to cool down significantly.

In addition to this hot mixing or when the application of Heat is detrimental to the stability of the agent in question, as in In the case of amine acetates, it has proven advantageous to use the amine-containing agent to be used together with a solvent and / or a surfactant, so as to facilitate the coating of the individual particles with the amine. examples for preferred solvents are mineral oil, luminous oil, pine oil and aliphatic nitriles, which by ammonolysis and dehydration of fatty acids with 6 to 22 carbon atoms in the molecule and mixtures of such fatty acids are obtained during hydrolysis naturally occurring oils such as soybean oil, tallow, coconut oil and cottonseed oil, develop. Particularly preferably used solvents which are commercially available consist of a mixture of aliphatic nitriles, which in ammonolysis and dehydration of fatty acid mixtures from the hydrolysis of soybean oil and tallow develop.

Examples of surfactants that can be used together with the here Amine-containing agents described above are surface-active Substances such as mahogany soap, sodium or potassium alkylarylsulfonates, condensation products of fatty acid amines and ethylene oxide, for example those described above primary, aliphatic amines, which have been condensed with 2 to 50 moles of ethylene oxide, as well as polymers of ethylene oxide and propylene oxide and condensation products of fatty acids with ethylene oxide.

A particularly preferably used surfactant is a condensation product of about 10 moles of ethylene oxide with 1 mole of a mixture of Fatty acids, which include about 500/0 oleic acid, 400 / o linoleic acid, 50 / o linolenic acid and Contains 50 / o resin acids. Experience has shown that the use of a surfactant Means is advantageous if the individual particles of the fertilizer mixture contain normal or larger amounts of moisture. Although surface active Means can also be used if the fertilizer is only low Contains a lot of moisture, adding a small amount of water will work in Direction of increased spreadability of the coating agent. It has already been mentioned that the amine-containing used according to the invention for coating the fertilizer mixture Agent either as such or together with a solvent or with a surfactants can be used. In general, a surfactant is used Means the surface tension between the hydrophobic, amine-containing agent and the usually moist surface of the fertilizer grains. The solvent liquefies the amine-containing agent to a liquid product at low temperatures. The agent used to coat the fertilizer particles therefore consists of about 5 to 100 percent by weight, preferably about 25 to 75 percent by weight, of the amine-containing Means, from 0 to 95 percent by weight, preferably 25 to 75 percent by weight, one Solvent and from 0 to 15 percent by weight, preferably 0.5 to 3 percent by weight, a surfactant. The following agents are examples of mixtures these compounds, which are particularly advantageous in the context of the present invention are.

Composition Amine mixture from soybean oil fatty acids .. .. S9 ° / 0 Nitriles from soybean oil fatty acids ....

Surface-active agent (condensation product of 10 moles of ethylene oxide + 1 mole of fatty acids). 1 ° / o amine mixture from tallow fatty acids ............. 590 / o Nitriles from tallow fatty acids ........................ 40% surfactant (Condensation product of 10 moles of ethylene oxide + 1 mole of fatty acids). . 1% mixture raw amines from sebum fatty acids ....... 600 / o Secondary sebum amine. .... .. 20 to 300 / o amine polymers ............................ 10 to 20% amines from soybean oil fatty acids 70 ° / o nitriles from soybean oil fatty acids, 30 ° / o acetate of amines from soybean oil fatty acids . . 59% nitriles from soybean oil fatty acids 40% surfactant (condensation product from 10 moles of ethylene oxide + 1 mole of fatty acids). . 1 ° / o amines from soybean oil fatty acids 60% nitriles from tallow fatty acids ....................... 40% amines from tallow fatty acids 60% nitriles from tallow fatty acids 40% amines from soybean oil fatty acids 400% mineral oil ........................................ 59% surface active agent (condensation product from 10 moles of ethylene oxide + 1 mole of fatty acids).

The following examples illustrate the invention.

Example I From a mixed and granular fertilizer with a Test samples were produced with a content of 12% N, 120 / o P205 and 120 / o K2O. Ever 100 g of the fertilizer was heated to about 82 "C and then placed in a bottle of 0.5 kg contents are introduced, whereupon the relevant reagent is added with a pipette became.

The bottle with the granules and reagent was then put on rollers and shaken back and forth for about 5 minutes. After mixing it was The sample is removed again and placed in a drying cabinet at about 82 "C for 2 hours dried. If no moisture was added to the sample, it was filled Fertilizer off without further drying. If in the course of donning moisture was added, the sample was dried for 2 hours at 82 ° C to remove excess Remove moisture.

In the tests summarized in Table I, 10 / o was always used Water is added to the fertilizer, except for the examples with an asterisk are designated.

Before the samples are placed in bottles of about 124 g content and Loosely capped, they were allowed to cool to about 38 "C. After the bottles during different periods of time, namely 24 hours, 48 hours, 72 hours, 1 week, Having stood for 2 weeks and 1 month without any disturbance, they were slowly inclined and tapped lightly, if necessary, and at the same time it was noted whether the individual grains were free flowing, caked or partially clumped. The following rating scale was used to determine the propensity of the test specimens produced to judge for caking.

Rating Description grade 1 Completely free flowing.

2 Slightly clumping, the grains separate from each other when the Bottle is turned over.

3 Clumping, light tapping of the bottle is required to remove the Separate grains from each other.

4 Solid clumping. Multiple knocks are required to get the Separate grains from each other.

5., Very firm caking. There are several hard knocks on that Bottle required to separate the grains from each other.

Note Some of the results related to the tendency to form lumps appeared to be between the integers given above, and so they became evaluated using half intervals, e.g. 1.5 etc.

The results of these experiments are summarized in Table I below. In the following tables, amine S means those made from soybean oil fatty acids Amines and, correspondingly, amine T from tallow fatty acids and amine C from coconut fatty acids recovered amines. The latter contains about 801, octyl, 9% decyl, 47% dodecyl, 18% tetradecyl, 8% hexadecyl, 5% octadecyl and 5% octadecenyl amine.

The same applies to the nitriles used as solvents d. i.e., S, T and C each indicate the fatty acids from which these nitriles are made became. The surfactant was used in the first eight trials each the same used, namely a condensation product of 10 moles of ethylene oxide and 1 mole of fatty acid.

Table I. Valuation grade Coating (mean Composition mix of per ton of storage the coating mixture of the try Fertilizer during 24, 48 and kg / t 72 hours) Fertilizer grains ......... - 4.0 Fertilizer grains, Addition of 1% water ... - 3.0 # 0.05 1.0 Amin @ ................ 500/0 0.1 1.0 Nitrile S ............. 49% 0.2 1 Surface active Mean 10 / o 0.25 1.0 Amine T ............. 59% 0.05 2.0 Nitrile T ........... 40% 0.1 1.0 Surface active # Medium ............. 1% 0.2 1.0 Amin T ............. 59% Nitrile S ........... 40% # 0.4 1.0 Surface active Medium ............. 1% (Continuation of Table I) Valuation grade Coating (mean Composition mix of per ton of storage the coating mixture of the try Fertilizer during 24, 4, 48 and kg / t 72 hours) Amin T ............ 50% Nitrile T ........... 49% 0.1 1.0 Surface active 0.2 1.0 Medium 10 / o Amine C ............. 59% Nitrile S ........... 40% # 0.1 1.0 Surface active Medium ............. 1% Amin T ............. 29% Nitrile S ........... 70% # 0.1 1.0 Surface active 0.15 1.0 Medium ............. 1% Amin T ............. 29% Nitrile T ........... 70% # 0.1 1.0 Surface active Medium ............ 1% Amin T ............ 69% Nitrile T .......... 30% # 0.1 1.2 Surface active Medium ............ 1% Various surfactants Valuation Coating (Average mixture Composition of per ton Storage the coating mixture of the try Fertilizer during 24, 48 and kg / t 72 hours) Amin S ............. 59% 0.1 1.0 Nitrile S ........... 40% # 0.2 1.0 Surface active Medium as above .... 1 0.4 1.0 Amin S ................. 59% Nitrile S ............... 40% # 0.4 1.0 Surface active Medium A ............... 1% Amin S ................. 59% Nitrile S ............... 40% # 0.4 1.0 Surface active Medium B ............... 1% Amin S 590/0 Nitrile S ............... 40% # 0.4 1.0 Surface active Middle C ............... 1% Amin S ................. 59% Nitrile S ............... 40% # 0.6 1.1 Surface active Mean D ............... 1% Amin S ................. 39% Nitrile S ............... 40% # 0.4 1.1 Surface active Mean E ............... 1% (Continuation of various surfactants) Valuation grade Coating (mean Composition mix of per ton of storage the coating mixture of the try Fertilizer during 24, 48 and kg / t 72 hours) Amin S .. 59% Nitrile S .. 400/0 0.4 1.3 Surface active 1.0 Mean F ............... 1% Amine S. 59% Nitrile S ................. 40% # 0.4 1.5 Surface active Mean G ................. 1% Explanation of the surface-active agents: A = dicocosdimethylammonium chloride B = sodium salt of mixed petroleum sulfonates C = condensation product of primary soybean oil amine with 2 moles of ethylene oxide D = condensation product of octadecylamine with 15 moles of ethylene oxide E = condensation product of hydrogenated mixed fatty acids of tallow oxide with 10 moles of ethylene oxide Amide of the mixed fatty acids from coconut oil with 5 moles of ethylene oxide G = Cocostrimethylammoniumchlorid Various solvents Valuation Coating (Average mixture of composition per ton Storage of he try coating mix the coating mixture fertilizer during 24, 48 and kg / t 72 hours) AminT .. ... - 10 0 / o Luminous oil ............ 84.5% Isopropyl alcohol .... 5% 0.2 1.5 Surfactant # 0.5 1.0 (Condensation product of 1.0 1.0 10 moles of ethylene oxide + 1 mole Fatty acids) ....... 1% Amin S ............ 59% Pine oil ......... 40% Surfactant 0.2 1.0 (Condensation product from 0.4 1.5 10 moles of ethylene oxide + 1 mole Fatty acids) ....... 1% Amin S ............ 40% Mineral oil ......... 59% Surfactant 0.05 1.0 (Condensation product of 0.25 1.0 10 moles of ethylene oxide + 1 mole Fatty acids). . 1 % Without surfactant Valuation Coating (Average Composition mix of per ton of storage the coating mixture of the try Fertilizer during 24, 48 and kg / t 72 hours) Amin S ............ 600/0 Nitrile T ............. 40% # 0.2 1.0 Amin T ............... 60% # 0.2 1.0 Nitrile T ............. 40% Amine T ............... 60% 0.2 1.0 # Nitrile S ............. 40% 0.4 1.8 Amine S ............... 60% 0.2 1.0 # Nitrile S ............. 40% 0.4 1.7 Diamines N-alkyltrimethylenediamines (the letters S and T each mean that alkyl are the residues of the fatty acids from soybean oil and tallow, respectively) Valuation Coating (mean mixture Composition of per ton Storage the coating mixture of the try Fertilizer during 24, 48 and kg / t 72 hours) Diamine S ............... 55% Nitrile S ............... 40% # 0.2 1.2 Diamine T - monooleate 5% Diamine T ............... 20% Nitrile S ............... 79% Surfactant 1.0 3.0 (Condensation product of 2.0 1.0 10 moles of ethylene oxide + 1 mole Fatty acids). . . . 1% Diamine T .................. # 0.25 1.4 Diamine T - monooleate. 0.4 1.0 1.0 1.5 Diamine S ............ 55% Nitrile S ............ 40% # 0.2 1.5 Diamine T - dioleate .. 5% Diamine T - monooleate 60% # 0.4 1.1 Nitrile S ............ 40% Diamine S ............ 59% Nitrile S ............ 40% Surfactant 0.4 1.0 (Condensation product from 10 moles of ethylene oxide + 1 mole Fatty acids). . .. 1 0 / o Diamine T acetate 0.25 3.0 (as a 5% aqueous solution) 2.0 3.0 - Mixed crude amines Valuation grade Coating (mean Composition mix of per ton of storage of try the coating mix Fertilizer while 24, 48 and kg / t 72 hours) Mixed crude amine 0.25 1.8 2.0 1.0 Mixed Crude Amine 20% Nitrile S ............ 79% Surfactant 1.0 1.8 (Condensation product of 2.0 1.1 10 moles of ethylene oxide + 1 mole Fatty acids) ........ 1% Mixed crude amine 590 / o Nitrile S ................ 40% Surfactant 0.25 1.8 (Condensation product of 2.0 1.0 10 moles of ethylene oxide + 1 mole Fatty acids) ...... 1% various Valuation Coating (Average mixture Composition of per ton Storage of the coating mixture try Fertilizer during 24, 48 and kg / t 72 hours) Amine T - acetate 0.125 3.0 (as a 50/0 aqueous solution) 0.5 3.0 Amin S .................. 0.25 2.0 Amin T ...................... 0.25 2.0 2.0 2.0 Amin T .................... Amin T ................ 99% Surfactant 0.2 1.0 # (Condensation product of 0.2 1.0 10 moles of ethylene oxide + 1 mole Fatty acids) ........... 1% Oleylamine. 0.05 1.0 0.125 1.0 0.5 1.0 Amin S ............. 59% Nitrile S ........... 40% Surface active agent # 0.4 2.0 (Condensation product from 10 moles of ethylene oxide + 1 mole Fatty acids) ....... 1% (Continued miscellaneous) Valuation grade (Average mixture Composition of per ton Storage the coating mixture of the try Fertilizer during 24, 48 and kg / t 72 hours) Amine S - acetate. 59% Nitrile S ........... 40% Surface active agent (Condensation product from 0.4 1.0 10 moles of ethylene oxide + 1 mole Fatty acids) .... 1% Amine S - hydrochloride 59% Nitrile S ............ 40% Surface active agent (Condensation product from 0.4 1.5 10 moles of ethylene oxide + 1 mole Fatty acids) ....... 1% Example II Samples each weighing 36.3 kg of a granular fertilizer with a content of 12% N, 12% P2O5 and 12% K2O and a moisture content of 0.35 to 1.75% (on average 1%) were at a temperature between 93 and 121 ° C taken from the outlet of a drying device. The 36.3 kg samples were placed directly in a small concrete mixer and the anti-clumping agent was poured onto the fertilizer sample at about 77 ° C while mixing. The mixing time was about 4 minutes from the time the coating was applied to the fertilizer, after which the granular mass was filled into a sack and the opening was sewn according to standard factory practice. Immediately after the fertilizer was coated, samples were taken for evaluation in the laboratory. For the evaluation of storage tests, the bags with the treated fertilizer were placed in two rows one behind the other on heavy kraft paper, and ten additional bags with untreated fertilizer were piled onto each bag. The rows with the bagged fertilizer were allowed to stand undisturbed in the warehouse for several weeks before an assessment of the tendency to clump was made.

After 2 weeks, the bags with the untreated fertilizer were removed, and the sacks of treated fertilizer were allowed to continue to be stored undisturbed.

Each sack of the fertilizer so treated was first carefully checked with regard to sitting in the sack, then cut open and with regard to the Lump formation of caked manure investigated, with simultaneously the size, hardness and number of lumps in each sack were recorded. The sacks were undamaged before opening, with the exception of a few pieces, which are pretty showed severe withdrawal symptoms. Some of these last-mentioned sacks ran out dropped to a height of about 0.9 m on a concrete floor before opening it, so as to mimic the conditions during normal handling.

The results of these tests and their evaluation are summarized in the following Table II: Table II Evaluation Evaluation in the factory (storage of the bags) Coating mixture Composition of the experiments in percent number of per ton of Laboratory set Lump and hardness the condition of the material Coating mixture Fertilizer Lump size lump (caking) free percentage free flowing cm inches flowing Fertilizer as above no coating 50 bag is deposited very hard very bad 50 Amine T acetate 0.05 100 3; 46 18 very hard bad 40 (as 5% aqueous 0.125 96 8; 10 4 hard medium 60 Solution) 0.5 80 No lumps - almost perfect 100 0.25 98 1; 36 14 medium hard medium 60 Amine T 0.05-1; 1.3 1/2 medium hard medium 100 0.125 100 2; 1.3 1/2 medium hard medium 100 0.25 100 3; 10 4 soft medium 70 0.5 100 1; 25 10 soft good 80 Amine S 0.05-5; 2.5 1 soft almost perfect 95 0.125 75 1; 31 12 medium hard good 75 0.25 98 no lumps - excellent 100 0.5 92 1; 31 12 medium hard good 75 Oleylamine 0.05-1; 41 16 soft medium 60 0.051) 100 1; 2.5 1 soft almost perfect 100 0.125 100 2; 2.5 1 soft almost perfect 100 0.25 92 1; 46 18 soft medium 50 0.5 100 1; 25 10 soft medium 50 Mixed crude amines 0.05 100 2; 5.1 2 medium hard almost perfect 99 0.125 100 no lumps - excellent 100 0.25 100 2; 5.1 2 soft almost perfect 98 0.5 100 2; 1.3 1/2 soft almost perfect 100 Diamine monooleate 0.05 100 no lumps - excellent 100 0.125 100 10; 1.3 1/2 soft almost perfect 100 0.25 96 1; 31 12 medium hard good 75 0.5 88 2; 20 8 soft good 75 0.05 98 1; 46 18 soft medium 60 Mixed raw 0.125 100 1; 31 12 soft medium 70 Amines ....... 99% # Surface active 0.25 100 no lumps - excellent 100 Medium ...... 1 1% 0.5 100 1; 25 10 soft good 80 0.05 100 2; 10 4 soft almost perfect 97 Oleylamine ...... 99% Surfactant # 0.125 100 1; 41 16 medium hard medium 60 Mean 1% 0.25 100 1; 25 10 soft good 80 0.5 70 1; 31 12 soft good 75 0.125 80 1; 41 16 medium hard medium 60 Oleylamine ...... 80% # 0.1252) 100 no lumps - excellent 100 Nitrile S ....... 20% 0.55 100 1; 41 16 medium hard medium 60 0.05 100 no lumps - excellent 100 Amin S ......... 70% 0.125 100 no lumps - excellent 100 Nitrile 5 - 30 0 /, 0.25 100 1; 10 4 soft almost perfect 99 0.5 98 1; 36 14 soft medium 70 Amine 5 60% @ 0.25 90 1; 31 12 medium hard good 75 Nitrile S ......... 40% 0.5 85 1; 46 18 medium hard medium 50 Amin S ........... 60% 0.25 100 no lumps - excellent 100 # Nitrile T ......... 40% 0.5 100 3; 2.5 1 very soft almost perfect 99 Amin T ........... 60% 0.25 100 no lumps - excellent 100 # Nitrile T ......... 40% 0.5 100 no lumps - excellent 100 Amin T ........... 60% 0.25 100 no lumps - excellent 100 # Nitrile S ......... 40% 0.5 88 1; 46 18 medium hard medium 60 1) Sack dropped once. 2) Sack dropped. (Continuation of Table II) Evaluation Evaluation in the factory (storage of the bags) the Coating mixture Composition of the experiments in percent number of per ton of Laboratory set Lump and hardness the condition of the material Coating mixture Fertilizer Lump size lump (caking) free percentage fluently free flowing cm inches flowing Amine S ........ 5001, 0.05 1; 10 4 soft almost perfect 99 Nitrile S ......... 49% Surface active 0.25-1; 20 8 soft good 90 Medium ........ 1% # 0.5 - 1; 5.1 2 soft almost perfect 97 0.05 100 no lumps - excellent 100 Amin T ........ 50% 0.125 98 1; 15 6 soft almost perfect 95 Nitrile T ...... 49% # Surface active Medium ....... 101, 0.25 100 1; 31 12 soft good 75 0.5 98 1; 31 12 soft good 75 Amine S ......... 59% 0.125-1; 46 18 medium hard medium 50 0.1251) 88 4; 2.5 1 medium hard almost perfect 100 Nitrile S ....... 40% Surface active Mean 1% .. 0.25 96 1; 41 16 medium hard medium 60 Amine S ........ 59% 0.125 88 1; 51 20 medium hard bad 40 Nitrile S ......... 40% # 0.25 69 2; 25 10 medium hard medium 60 Surface active Mean 1 0 / o 0.5 75 1; 41 16 hard average 60 Amine 5 59% 0.05 1002) 1; 46 18 soft medium 50 Nitrile 5 40% 0.125 88 2; 20 8 medium hard good 85 Surface active Medium ........ 1% 0.25 75 1; 41 16 medium hard medium 60 0.5 1002) 2; 7.6 3 soft almost perfect 97 Diamine S 59% 0.05 88 4; 2.5 1 hard almost perfect 98 Nitrile S 400 / o 0.125 100 1; 31 12 soft good 75 Surface active Medium ........ 1% # 0.5 100 1; 36 14 medium hard medium 70 0.05 100 4; 5 2 very soft almost perfect 97 Amin S ........ 40% # Mineral oil ...... 59% 0.125 100 no lumps - excellent 100 Surfactant 10 0.25 96 1; 41 16 medium hard medium 60 Medium .. 0.25 94 no lumps - excellent 100 Amin T ........ 10% 0.05 100 no lumps - excellent 100 Luminous oil ...... 84.5% 0.125 100 1; 36 14 medium hard medium 70 Isopropanol ... 5% 0.25 100 1; 36 14 soft medium 70 Surface active Medium ........ 1% 0.5 100 no lumps - excellent 100 Amine 5 59% 0.05 100 1; 20 8 medium hard good 85 Pine oil ....... 40% Surface active # 0.25 46 no lumps - excellent 100 Medium .......... 1% 0.5 100 1; 36 14 soft medium 70 0.05 100 no lumps - excellent 100 Amine S-acetate .. 59% 0.125 100 1; 36 14 soft medium 70 Nitrile S ....... 40% Surface active 0.25 100 2; 2.5 1 soft almost perfect 9 @ Medium ........ 1% # 0.5 100 1; 31 12 medium hard almost perfect 97 1) Sack dropped. 2) Excellent condition after the bag was dropped.

Example III A further series of tests was carried out as described in Example 1, using a fertilizer mixture with a content of 15% N, 00 / o P2 O5 and 150 / o K2O. The test results are summarized in Table III below. Table III Valuation grade Coating (mean Composition mix of per ton of storage the coating mixture of the try Fertilizer during 24, 48 and kg / t 72 hours) Fertilizers as above ..... no 5.0 coating 0.05 3.7 Amin S ........... 59% # 0.125 3.3 Nitrile S ......... 40% Surface active Medium ........... 1% 0.5 2.5 0.05 1.7 Amin S ........... 59% 0.125 1.0 Nitrile S ......... 40% *) Surface active # 0.25 1.0 Medium ........... 1% 0.5 1.0 Amin S .................. 0.05 2.0 0.125 2.5 0.25 2.5 0.5 1.7 Amine T .................. 0.05 2.8 0.125 2.0 0.25 2.2 0.5 2.7 0.05 3.7 Amin S ........... 40% # 0.125 3.2 Mineral oil 59 ° / o Surface active 0.25 2.3 Medium .............. 1% # 0.5 1.7 0.05 2.7 Amine S .............. 40% 0.125 2.5 # Mineral oil ........... 60% 0.25 2.0 0.5 1.9 0.05 3.3 Amin S .............. 60% 0.125 2.7 Nitrile S ............ 40% # 0.5 2.7 Mixed crude amines ..... 0.05 2.7 0.125 2.3 0.25 2.3 0.5 1.8 (Continuation of Table III) Valuation grade Coating (mean Composition mix of per ton of storage the coating mixture of the try Fertilizer during 24, 48 and kg / t 72 hours) Amine T (distilled) ........ 0.05 3.3 0.125 3.0 0.25 2.0 Soil residue of the amines. 0.05 3.3 0.125 2.7 0.25 2.0 0.5 2.0 *) In this experiment, 0.5% water was added to the fertilizer before the amine was added. In all other tests, the material was treated in the condition in which it was received.

PATENT CLAIM: 1. Process for the production of non-clumping, non-caking and free-flowing mixed fertilizers, especially NPK fertilizers, by adding substances preventing caking, characterized in that, that the mixed fertilizer granules with about 0.025 to about 2 kg / t of a cation-active Amines of the formulas RNH2 or RNHCH2CH2CH2NH2, in which R is an aliphatic hydrocarbon radical with 8 to 22 carbon atoms, or with salts of these amines with hydrochloric acid, Acetic acid or fatty acids having 6 to 22 carbon atoms or mixtures thereof Amines using 25 to 75% solutions of these amines and treatment temperatures from 65 to 121 ° C are coated in such a way that on each mixed fertilizer grain uniform and coherent amine film is formed.

Claims (1)

2. The method according to claim 1, characterized in that at least an aliphatic nitrile having 6 to 22 carbon atoms as a solvent of the cation active Amine is used. 3. The method according to claim 1 and 2, characterized in that in addition a surfactant is used. Considered publications: German Patent Specifications No. 940 985, 944 317, 950 559, 956 959, 967 976.