EP1331213A2 - Process for making additives containing ammonium dinitramide - Google Patents

Abstract

Production of additive-modified ammonium dinitramide (ADN) involves emulsifying molten ADN in a hot dispersion of the additive (I) in a non-solvent for (I) and ADN so that (I) migrates into the ADN droplets, after which the mixture is cooled and separated. A method for the production of ammonium dinitramide (ADN) particles modified with finely-divided additive particles (I), especially stabilisers, combustion modifiers and/or energy carriers, involves dispersing (I) in a matrix liquid in which both (I) and ADN are insoluble or only sparingly soluble, heating to a temperature close to or above the m.pt. (T1) of ADN, adding ADN, emulsifying it in the molten state and bringing it into contact with (I), cooling to below T1 and separating the solid ADN particles with incorporated (I) from the matrix liquid.

Description

The invention relates to a method for producing with fine particulate additives, especially stabilizers, Burning modifiers and / or energy sources Particles of ammonium dinitramide (ADN).

Ammonium dinitramide (ADN) is an oxidizer for fuels and of great importance as an explosive. In the application are for both the manufacture and the processing compactible particles with regular grain shape and narrow particle size distribution desirable. In many There is a need to add additives in order to in particular to improve the shelf life and / or the Burning properties individually to the desired purpose adapt. On the one hand, there are stabilizers, which shows the tendency of ADN to autocatalytic decomposition inhibit or even completely prevent, on the other hand Burn-up modifiers are provided which control the burn-up rate of ADN. Furthermore is to increase the power or the specific impulse often the addition of energy sources such as explosives or oxidizers, an advantage.

The solid, mostly powdery additives are in the Usually in the desired mass ratio with the crystalline ADN mixed in the form of a solid mixture. The disadvantage is that due to the cohesive forces of the fine particulate Additive agglomerates are formed and thereby achieved an inhomogeneous mixture with the ADN is, so that the burning properties of a propellant of such a mixture vary widely locally and cannot be reproduced are. In particular, fine particulate additives unfold their effect depending on their with the ADN in contact surface, so that a possible homogeneous distribution of the fine particles in the ADN is necessary.

It is also known to melt the ADN and the powder Disperse additives into the melt. Subsequently the dispersion is atomized by means of nozzles. On this way, it becomes a much more homogeneous distribution of the additives in the generated ADN particles, but relatively irregular particles arise and come it to segregate the continuous during atomization (ADN) and the disperse phase (additives). In particular ADN tends above its melting temperature of about 93 ° C to decompose, so that the ADN basically only possible should be melted briefly. In contrast, however, the ADN must remain in the molten liquid for a sufficiently long time Condition kept to be a homogeneous distribution to achieve the additives in the ADN melt and this the Supply atomization. The same applies to the use of additives soluble in molten ADN.

The invention has for its object a method of type mentioned to the extent that a homogeneous distribution of the additives in the ADN particles below avoidance of thermal impairment as far as possible the same is achieved.

According to the invention, this object is achieved in a method of type mentioned at the outset in that solid, finely particulate, Hydrophilic additives migrated into the ADN particles by adding the additives into a matrix liquid, in which either or not the additives as well as the ADN are hardly soluble, are dispersed and the dispersion to a temperature in the range or above the Melting temperature of the ADN heated, the ADN into the dispersion introduced and emulsified in the molten state and brought into contact with the solid additives, the dispersion then to a temperature below the melting temperature of the ADN is cooled and the solid ADN particles with the incorporated additives from the matrix liquid be separated.

Processes in which an explosive or oxidizer is dispersed and crystallized out in a continuous phase are known for producing pure particles or for improving the grain properties by recrystallizing the particles. No. 3,522,334 A describes a process for the production of crystals from a mixture of nitryl perchlorate and lithium perchlorate, the mixture being melted and dispersed in an inert liquid which is immiscible with LiClO ₄ and NO ₂ ClO ₄ , in particular halogenated hydrocarbons. After the particles have cooled and solidified, they are separated from the liquid. WO 97/47571 A1 describes a corresponding method for producing spherical particles from explosives, in particular ADN.

DE 1 467 203 A1 is a process for the production of spherical, non-caking ammonium nitrate (AN) Removable, the AN melted at about 170 ° C to 180 ° C. and dispersed in an indifferent suspending agent becomes. After cooling the suspension to about 130 ° C the suspension medium is removed from the spherical AN by means of a Continuous centrifuge separated and recirculated. To one Counteract clumping of the finished product, the suspension is not specified in particular Anti-caking agents added that adhere to the AN by adsorption.

EP 0 953 555 A1 describes a process for the production of spherical particles more meltable, more sensitive to moisture Fuels and explosives and oxidizers, in particular ADN, known by melting the ADN, the Molten material in an indifferent matrix liquid emulsified, the emulsion below the melting point of the ADN Recrystallization of the disperse drops into solid particles is cooled and the solid particles from the matrix liquid be separated. To produce Fine particles for an emulsion with fine droplets too the matrix liquid becomes a hydrophobic emulsifier added in the form of silicon dioxide.

However, the known methods have so far been unsuccessful to experts no suggestions for solving the basis of the invention Problems. Surprisingly, it was found that when using fine particulate additives with a sufficient hydrophilic character to from the emulsified ADN to be wetted, a spontaneous migration of the additives into the ADN droplet takes place what - after it solidifies - to ADN particles with additives incorporated in these leads. It becomes a homogeneous and in a short time uniform distribution of the additives in the emulsified ADN droplets reached, with all ADN particles generated an identical and in particular reproducible Have proportion of additives. A control of the percentage The proportion of additives in the ADN particles is on simple way about the amount of the matrix liquid or additives added to the emulsion. By means of the The methods according to the invention thus become regular ADN particles with homogeneous in these distributed additives and consequently the best possible contact of the additives with the ADN, with a thermal impairment of the ADN is largely avoided because of the ADN particles the large surface available for mass transfer only melted briefly and immediately cooled again can be. Agglomerations of additives and ADNs are avoided just as safely as local segregation of the components mentioned. In addition, the matrix fluid provides sure that the strongly hygroscopic ADN during no water, e.g. Humidity, receives. A rapid crystallization of the ADN particles added to the additives when the Dispersion is ensured by the fine particulate additives, which act as crystallization nuclei. The separation the phase mixture takes place exclusively on the basis of different melting points of ADN and matrix liquid.

The ADN can be in the crystalline state in the heated matrix liquid introduced and melted, or the ADN is melted in advance and the ADN melt immediately introduced into the matrix liquid. The additives and the ADN can also the matrix liquid at the same time or added sequentially, only for that Care must be taken that the ADN does not overheat and after the migration of the additives is quickly cooled again.

The preparation of the dispersion from matrix liquid and Additives or ADN occurs through the entry of energy into the fluid system. This can be done by agitation, e.g. by shaking, Stirring etc., or by coupling vibrations into the system, e.g. by means of ultrasound. If the ADN is melted before being introduced into the matrix liquid, it can also be done by injecting the melt be emulsified into the matrix liquid or vice versa.

To make the drop of the emulsified ADN phase as large as possible Volume to form a finely dispersed emulsion or dispersion and thus a large mass transfer area to provide the concentration of the ADNs in the matrix liquid preferably to at most 50% by mass and in particular set to a maximum of 40% by mass. The solid ADN particles interspersed with additives separated matrix liquid can be reused, for example with fresh additives and be recirculated.

In a preferred embodiment it is provided that emulsifiers for adjusting the droplet size of the melted ADN are added to the matrix liquid. By adding different emulsifiers, the interfacial tension between the components and the viscosity of the continuous phase can be changed and the stability of the emulsion (ADN / matrix liquid) can be influenced. The emulsifier known from EP 0 953 555 A1 in the form of hydrophobicized silicon dioxide has proven to be particularly advantageous, by means of which the stability of the emulsion is increased and the coalescence at which the emulsified ADN droplets flow together to form a continuous phase is reduced. The SiO ₂ , which remains in the matrix liquid due to its hydrophobic character and does not migrate into the emulsified ADN, also serves to modify the viscosity of the continuous phase.

The crystallization process of the additives ADN droplets can be set in addition to a suitable one Temperature gradients due to mechanical energy input be controlled in the dispersion. Preferably the Dispersion agitates on cooling and / or with ultrasound acted upon in order to produce a product which is as fine-crystalline as possible receive.

The matrix liquid is selected so that the melted Allows ADN to emulsify. Preferably be used as the matrix liquid non-polar organic liquids are used, mainly oils, especially paraffin oil and / or silicone oil and / or low-reaction halogenated oils, primarily fluorinated oils.

Solids are preferably used as stabilizers, which act as proton and / or radical acceptors and the Prevent autocatalytic decomposition of ADN in this way or at least delay. Have proven to be suitable metal oxides, in particular magnesium and / or Zinc oxide. On the other hand there are stabilizers from the group of urea, alkylated and / or phenylated Urea derivatives, e.g. N, N-diphenylurea (acardite I), N-methyl-N, N'-diphenylurea (Akardit II) etc., and from the group of organic amines, in particular Hexamethylenetetramine (urotropin), diphenylamine and / or nitrodiphenylamine, advantageous. Stabilizers are also suitable from the group purine and / or its bases (purines), e.g. Adenine, guanine, xanthine, uric acid etc. from the group Diazines, especially pyrimidine (1,3-diazine), and / or its derivatives, especially pyrimidine bases, e.g. cytosine, Uracil, thymine etc., and from the triazine group (1,2,3-, 1,2,4- and / or 1,3,5-triazine) and / or its derivatives, e.g. Cyanuric acid, melamine, guanamine, etc. Finally can also be used as stabilizers from the group the primary, secondary and / or tertiary amides or combinations of the aforementioned substances are used.

The combustion modifiers are preferably from the group the catalytically active metal oxides, in particular copper, Lead and / or alumina, chosen, which the burning rate from ADN under certain printing conditions can influence.

In addition to finely particulate aluminum, the energy sources are in principle any known solid explosives and oxidizers in question, which has a sufficiently hydrophilic character have to be wetted by ADN in the molten state to become. The energy sources are preferred the group of nitramines, in particular cyclotetramethylene tetranitramine (Octogen, HMX), cyclotrimethylene trinitramine (Hexogen, RDX), nitroguanidine (NQ) and / or trinitrophenylmethylnitramine (Tetryl) and / or from the group of nitrates and / or perchlorates, in particular ammonium nitrate and / or -perchlorate, chosen.

Otherwise, the method according to the invention can be both continuous as well as semi-continuously or in batches be performed.

Fig. 1

eine vergrößerte Detailansicht einer Dispersion aus ADN in Paraffinöl mit in diesem dispergierten Magnesiumoxid und

Fig. 2

eine vergrößerte Detailansicht von mit N-Methyl-N,N'-diphenylharnstoff versetzten ADN-Partikeln.

The invention is explained in more detail below on the basis of exemplary embodiments with reference to the figures.
Show it:

Fig. 1

an enlarged detail view of a dispersion of ADN in paraffin oil with magnesium oxide and dispersed in this

Fig. 2

an enlarged detail view of ADN particles mixed with N-methyl-N, N'-diphenylurea.

example 1

To produce stabilized ADN particles, fine particulate magnesium oxide (MgO) is dispersed in paraffin oil as the matrix liquid. Various stirrers, such as blade or propeller stirrers etc., or ultrasound are suitable for producing the dispersion. The dispersion is heated to about 100 ° C. with continuous stirring. Then 20% by mass of solid ADN are added and the ADN is melted and emulsified in the matrix liquid. Hydrophobized silicon dioxide (SiO ₂ ) is used as the emulsifier. As soon as the disperse phase of molten, finely emulsified ADN comes into contact with the MgO particles dispersed in the continuous phase, the MgO particles are wetted by the ADN and migrate into the interior of the ADN droplets. The SiO ₂ added as an emulsifier is not wetted by this because of the polarity different from ADN and remains in the continuous phase. After a few minutes, the dispersion is then cooled to room temperature with continuous introduction of stirring energy and / or ultrasound and the solid, MgO-containing ADN particles are separated from the matrix liquid and the MgO remaining there, for example by filtration, centrifugation, sedimentation or the like. After separation, the ADN particles can still be washed with a suitable solvent and dried.

In this way, spherical ADN particles are also defined Particle properties, such as average particle size, Particle size distribution and specific surface with a proportion of 3.3% by mass of homogeneously distributed MgO. The one determined by atomic emission spectroscopy (ICP-ACS) MgO content can be found in the matrix liquid Adjust the total amount of MgO dispersed, whereby the minimum percentage necessary to stabilize ADN care should be taken of about 2% by mass of MgO. The average particle size of the obtained can also be stabilized ADN particles by appropriate agitation the dispersion on cooling and / or by type and amount of the emulsifiers used in a wide range Taxes. In the present embodiment, a obtained average particle size of 360 microns. A homogeneous Distribution of the additive (MgO) in the ADN particles leaves for example by light microscopic examination detect the product obtained in different light levels.

1 shows an enlarged detailed view of the ADN droplets emulsified in paraffin oil immediately before cooling. As can be seen from FIG. 1, the fine particulate MgO 1 initially accumulates on the surface and then in particular also in the interior of the ADN droplets 2, while the SiO ₂ 3 remains in the paraffin oil.

Example 2

Stabilized ADN particles are produced according to Example 1, where instead of MgO powder finely particulate N-methyl-N, N'-diphenylurea (Akardit II) as a stabilizer is used.

2 is an enlarged detailed view of the obtained stabilized ADN particles are shown. As in FIG. 2 removable, the spherical ADN particles 4 have a Variety of fine Akardit II particles 5 that are homogeneous are distributed in the ADN matrix.

Claims (22)

Process for the production of particles of ammonium dinitramide (ADN) mixed with fine particulate additives, in particular stabilizers, burn-off modifiers and / or energy carriers, characterized in that solid, fine particulate, hydrophilic additives are migrated into the ADN particles by the additives being added to a matrix liquid, in which both the additives and the ADN are insoluble or only sparingly soluble, are dispersed in and the dispersion is heated to a temperature in the range or above the melting temperature of the ADN, the ADN is introduced into the dispersion and emulsified in the molten state and with the solid additives brought into contact, the dispersion is then cooled to a temperature below the melting temperature of the ADN and the solid ADN particles with the incorporated additives are separated from the matrix liquid. A method according to claim 1, characterized in that the ADN is introduced and melted in the heated matrix liquid in the crystalline state. A method according to claim 1, characterized in that the ADN is melted and the ADN melt is introduced directly into the matrix liquid. Method according to one of claims 1 to 3, characterized in that the matrix liquid is agitated to disperse the additives and / or to emulsify the ADN. Method according to one of claims 1 to 3, characterized in that ultrasound is introduced into the matrix liquid for dispersing the additives and / or for emulsifying the ADN. A method according to claim 3, characterized in that the molten ADN is emulsified by injection into the matrix liquid. Method according to one of Claims 1 to 6, characterized in that the concentration of the ADN in the matrix liquid is adjusted to at most 50% by mass, in particular at most 40% by mass, based on the matrix liquid. Method according to one of claims 1 to 7, characterized in that emulsifiers for adjusting the droplet size of the molten ADN are added to the matrix liquid. Method according to one of claims 1 to 8, characterized in that the emulsion is agitated during cooling and / or subjected to ultrasound. Method according to one of claims 1 to 9, characterized in that non-polar organic liquids are used as the matrix liquid. Method according to one of claims 1 to 10, characterized in that oils, in particular paraffin oil and / or silicone oil and / or low-reaction halogenated, in particular fluorinated oils, are used as the matrix liquid. Method according to one of claims 1 to 11, characterized in that the stabilizers are selected from the group consisting of metal oxides, in particular magnesium and / or zinc oxide. Method according to one of claims 1 to 11, characterized in that the stabilizers are selected from the group of urea, alkylated and / or phenylated urea derivatives. Process according to one of claims 1 to 11, characterized in that the stabilizers are selected from the group consisting of organic amines, in particular hexamethylenetetramine (urotropin), diphenylamine and / or nitrodiphenylamine. Method according to one of claims 1 to 11, characterized in that the stabilizers are selected from the group of purine and / or its bases (purines). Process according to one of claims 1 to 11, characterized in that the stabilizers are selected from the group of diazines and / or their derivatives. Method according to one of claims 1 to 11, characterized in that the stabilizers are selected from the group triazines and / or its derivatives. Method according to one of claims 1 to 11, characterized in that the stabilizers are selected from the group of amides. Method according to one of claims 1 to 18, characterized in that the burn-off modifiers are selected from the group of catalytically active metal oxides, in particular copper, lead and / or aluminum oxide. Method according to one of claims 1 to 19, characterized in that finely particulate aluminum is used as the energy source. Method according to one of claims 1 to 19, characterized in that the energy sources from the group of nitramines, in particular cyclotetramethylene tetranitramine (octogen, HMX), cyclotrimethylene trinitramine (hexogen, RDX), nitroguanidine (NQ) and / or trinitrophenylmethylnitramine (tetryl) are selected. Method according to one of claims 1 to 19, characterized in that the energy sources are selected from the group of nitrates and / or perchlorates, in particular ammonium nitrate and / or perchlorate.

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