DE1115225B - Method and device for the production of cores coated with a powdery material - Google Patents

Description

Method and device for the production of with a powdery Coated Grain Material The invention relates to a method of manufacture of uniformly sized grains of molten material coated with a powdery material Substances, especially those made from ammonium nitrate, by allowing the Melt with simultaneous conveyance of the drop-shaped melt by vibration impulses; it consists in transferring the still molten droplets into a fluidized bed drops the powdery material used for coating the grains, wherein the droplets are of such a size and temperature that they can pass through the fluidized bed fall and solidify in the process.

This is how the new way of working differs from the familiar Process in which one rains a liquid onto a fluidized bed of a powder and thereby can be absorbed in this, while according to the invention large liquid droplets get through cooling to crystallization and thereby to solidification, wherein at the same time, without creating a homogeneous mixture, with a coat the second substance. Therefore, according to the new method of operation, the drops are applied in a size that they fall through the fluidized bed, with the temperature the drop may only be so high that the drops can penetrate the fluidized bed Solidify cooling, while in the known method the z. B. by melting Liquids obtained coat the individual powder particles of the fluidized bed.

Have the granulating chambers used according to the new invention in contrast to the chambers created for this purpose, customary in technology much smaller dimensions. The devices to be used according to the invention consist of a small vessel that has a spout in its lower end and a nozzle connected to an electromagnetic vibrator is, and from a vortex blade, which is from a constantly moving Suspension of the powdery material with which the grains are to be coated, exists in a gaseous medium. It is the first time in accordance with the present invention possible with a facility which is also much cheaper than that known such devices can be made two operations at the same time perform, namely both granulating and coating.

Regarding the state of the art, it should be remembered that per se for graining of ammonium nitrate and other substances (which are generally used as fertilizers different procedures are known. One of them is particularly applicable on ammonium nitrate and other substances, which when they have a low water content (of a few percent) at temperatures generally below 2000 C melt, in which they do not decompose in any case (e.g. urea). One such known method is that you first have a highly concentrated aqueous solution at a temperature a little above the freezing point in drops divided. The solution is under a pressure of a few kg / cm2 at the top of a Chamber pressed out through cylindrical holes, with an ascending stream of air in the Chamber is initiated. During the fall, the natural ones solidify Subdivision of the thread-like rivulets resulting drops into grains of spherical ones Shape.

If it is desired, as is done in the art, the grains to be coated with a powdery substance, this measure must be followed carried out and the amount of powder adhering to the grains without glue is large low or equal to zero.

As when falling from a height of 20 to 30m during which the drops take possession, some of the grains break when hitting the chamber floor, cannot use the entire granulation product in the known processes and part of it must be discarded by sieving and treated again will.

The method according to the invention now eliminates the disadvantages mentioned and enables the use of granulation chambers of considerably reduced Size, the application of a coating on the grains simultaneously with the actual Granulating and finally obtaining more uniformly sized grains.

The method according to the invention thus consists in that one drops from z. B. Forms ammonium nitrate by flowing it out through vertical nozzles and at the same time transmits rhythmic impulses to the pressure of the liquid or vibrate the nozzles and then drop the formed drops into a bed leaves, which consists of a fluidized bed of the powdery substance with which the grains to be coated, there is, so that the droplets solidify in the fluidized bed.

A vibration in the through the Nozzle openings running horizontal plane proved. When such a vibration has a sufficient amplitude, it causes the detachment of calibrated drops and also creates multiple trajectories, so that a higher production capacity is possible per nozzle. With straight-line vibration, two trajectories arise.

One or more transverse, rotary, vibratory etc.

Movements issued, which together are both a constant renewal of the powdery material in the places where the drops fall as well as a progression the finished grains mixed with the powdery material towards one allow intended outlet.

The drops whose specific gravity is higher than that of the Suspensions of the powdery material fall through it, cooling them down and at the same time be coated with the powder, while maintaining their spherical shape Shape. When the thus formed and coated grains hit the bottom of the bed of powdery Reach substance, they are taken together by means provided for this purpose with a certain amount of powdery substance, of which they then, for example separated by sieving.

In this process, the amount required to solidify the droplets is required Fall height significantly reduced due to the relatively low speed of fall and of the very rapid removal of heat caused by coming into contact with the drops powdery substance comes about.

Also the horizontal dimensions of the for a given output capacity required space are significantly reduced. This is due to the fact that the distance between the drops can be minimized, both because the fall paths in space are clearly defined and the drops along them fall at a certain distance from each other, as well as because, even if the Drops come into weak contact with each other, causing mutual adhesion the presence of the powder is avoided, which is kept in constant motion and so separates the drops from each other.

The grains obtained by the process of the present invention have a very uniform size, as can be seen from the following information.

According to the method according to the invention, it is also possible in the molten Nitrate to suspend certain amounts of other finely divided substances, which thereby can be incorporated into the grains.

The inventive method can be expediently with the help of a Perform device, which has the following essential components: a) A Vessel, which a certain, if desired adjustable amount of melted Contains ammonium nitrate and has outlet nozzles with sharp-edged openings at the bottom. b) An electromagnetic vibrator that allows the above complex Vibrations with essential components in the plane of the outlet openings Issuing nozzles. c) A carrier arranged below the said nozzles for powdery material d) means to the powdery material located on the carrier c) to keep in suspension, as well as means to move said carrier to at the same time the continuous renewal of the powdery material under the nozzles and that Progress of the already formed grains in the direction of a suitable removal point to effect. e) Means to remove the molten ammonium nitrate contained in the vessel a) keep in weak motion. f) Means to the device part described under a) to heat.

The drawing shows an example embodiment of the invention Device for carrying out the method according to the invention.

In this drawing, 1 represents the vessel which the molten Contains ammonium nitrate, which by heating means not shown in liquid State is maintained; 2 is a pipe for the continuous supply of ammonium nitrate, 3 an overflow pipe, which enables the maintenance of a constant liquid level guaranteed in the vessel, 4 a device for temperature control, 5 an outlet nozzle for the molten nitrate, 6 an electromagnetic vibrator which the vessel and thus imparting horizontal vibrations to the nozzle, 7 a into the ammonium nitrate melt Rod immersed above the nozzle, the upper end of which is rigid at one with the vessel 1 connected point, 8 an inlet for the introduction of the powdery substance, which should form the floating bed; 9 is an air-permeable carrier for the powdery substance; 10, 11 is an outlet for removing the powdery substance mixed granulated product, and 12 and 13 are the entrance and the exit, respectively the air The vibrating rod 7 serves to remove the molten mass in a moderate manner to stir to avoid local solidification, even if the medium temperature the solidification temperature is very close.

The carrier 9 is preferably, but not necessarily, oblique arranged to allow the flow of the suspended matter and the grains in the direction to facilitate the extraction point. The figure also shows that the Vibration imparted to the nozzle causes two different fall paths for the drops.

It is clear that the distance between the nozzle opening and the surface of the fluidized bed must be so large that due to the acceleration a sufficient Increase the distance between successive ones on the same fall path falling drops is possible and that the drops also before entering the suspension a sufficient but not too high vertical speed from powdery material reachable.

It was found that the drop size and size range of the drops depend on the diameter of the nozzle, the pressure of the liquid, the Amplitude of the vibration as well as the concentration and temperature of the liquid. If these elements are kept constant, the droplet size is very uniform. A narrow size range is given by a wider amplitude of the vibration, i.e. H. by high acceleration values are beneficial if the other conditions remain the same.

Example With a device of the type described, 93% Ammonium nitrate, which is kept liquid at a temperature of 130 to 30 ° C 30 0C is granulated using a nozzle 1.4 mm in diameter, giving 50 vibrations is exposed per second with an amplitude of 0.5 mm. As a powdery substance one uses ground lime, of which about 750 /, through a sieve with square Pass through meshes with a clear mesh size of 0.21 mm.

The depth of the limestone bed is about 40 mm at rest and about 70 mm when fluidizing with air.

About 100 drops per second with a diameter between 2.0 and 3.3 mm, corresponding to 3.6 kg of end product per hour. The nitrogen content of the The end product makes up about 25 to 300 / o (content of pure ammonium nitrate 350 / o), and the thickness of the lime coating is 0.10 to 0.15 mm.

The obtained grains do not agglomerate even if they do stored for a long time under pressure and in the presence of certain amounts of moisture and they are therefore eminently suitable as fertilizers.

In the following tables the results are given, which were obtained in tests carried out under different conditions.

These experiments were carried out with 93% ammonium nitrate solution, which was kept in the molten state at 130 i3 C.

Table 1 Drop diameter with 50 vibra- Nozzle height of the tions each diameter melting column without a second Vibration amplitude mm mm 0.5 mm 1.4 50 3 1 to 2 1.4 200 2 0.5 3 200 5 3 Table 2 Nozzle height of 50 vibrations Weight percent of the droplets formed Nozzle height of the per second diameter diameter diameter diameter diameter diameter melting column amplitude over 3.3 mm between between between below and 2,3 2,3 and 2mm 2 and 0.85mm 0.85mm mm mm mm ° lo 01o Olo%% 1.4 200 0.25 to 0.30 3.6 48.0 45.5 2.9 0.0 1.4 200 0.3 to 0.4 1.0 56.0 40.5 2.5 0.0 1.4 200 0.4 to 0.5 0.0 52.5 44.0 3.5 0.0 1.4 200 0.5 to 0.6 0.0 18.3 81.0 0.7 0.0 Table 3 Nozzle height of the amplitude required Vibrations minimal diameter melting column (50 per second) height of fall mm mm mm cm 1.4 200 0.0 50 to 55 1.4 200 0.2 40 1.4 200 0.25 40 1.4 200 0.3 35 1.4 200 0.4 30 1.4 200 0.5 20 1.4 200 0.6 5 to 10 1.4 50 0.0 30 1.4 50 0.6 0.01) 3 200 0.0 240 3 200 0.6 100 ) Divided at the nozzle outlet.

The following table shows the values that were obtained in tests carried out with 95 to 97% ammonium nitrate of 135 A 30 became.

The nozzle with a diameter of 1 mm received 50 vibrations each Second with an amplitude of 0.2 or 0.4 or 0.6 mm.

Table 4 Weight percent Diameter of the drop experiment 1 distribution Try 2 Try 3 mm%%% over 3.3 ............. 2 10.5 1 3.3 to 2.3 ....... 13 10 40 2.3 to 2.0 ....... 74 74 57 2.0 to 0.85 ...... 11 4 2 0.85 to 0.5 ...... 0 1.5 0 It can be seen from the data given that it is possible to obtain granules in a very narrow size range.

Claims (4)

PATENT CLAIMS: 1. Process for the production of with a powdery Material coated grains of uniform size from molten substances, in particular from ammonium nitrate, by means of drops allowing the melt to flow out while at the same time Promotion of the drop-shaped melt by means of vibration impulses, characterized in that that the still molten drops in a fluidized bed from the powdery, for covering the grains serving material drops, the drops being a have such a size and temperature that they fall through the fluidized bed and solidify in the process. 2. The method according to claim 1, characterized in that the melt from ammonium nitrate and the powdery material from at least one inert substance, in particular calcium carbonate or diatomaceous earth, and that the fluidized bed is generated by the introduction of air. 3. The method according to claims 1 and 2, characterized in that that the powdery material that forms the fluidized bed, from a mixture of at least an inert substance and the substance forming the grains, which is in unmelted State exists. 4. Device for performing the method according to the claims 1 to 3, characterized by a vessel (1) with an overflow for the molten Substance, at least one nozzle (5) connected to the bottom of the vessel with sharp outlet edges, which can be set into rapid vibratory motion, its components lie in the plane of the outlet opening of the nozzle, a carrier (9) for the powdery Material, which is arranged below the nozzles, means to the powdery Transferring substance to the state of a fluidized bed above the carrier, as well as means, movements around the wearer with movement components that are variable with respect to the usual three main axes granted. Considered publications: German Patent Specifications No. 932 246, 934 771; French patent specification No. 1 077 880.