EP1164116A1 - Process for producing a functional high-energy material - Google Patents

Abstract

In the production of a functional, high-energy material with laminar grains containing an energy-rich plasticizer (I) and polymeric desensitizer (II), (I) and (II) is diffused into the absorbent grains in the form of an aqueous emulsion. Independent claims are also included for: (a) functional high-energy material with laminar grains, obtained by introducing (I) and (II) into a green powder, which contains 5-20% of is a specified 2-nitroxyethyl-nitramine (IA) or dinitro-diazaalkane (IB) as (I) with respect to the green powder; (b) green grains for producing a functional high-energy material of this type.

Description

Technical field

The invention relates to a method for producing a functional high-energy Material with a layered grain containing an energy-rich plasticizer and a polymeric desensitizer. The invention further relates to such material.

State of the art

The knowledge gained on the occasion of the recent international military Conflicts were won that covered the need for reorientation which, especially in the field of mobile weapon systems in the medium-caliber range (Caliber size between 12-50 mm) is of particular importance. Here are Performance increases, which are bought by means of new weapon developments must, very expensive, because massive improvements in material technology are necessary to the successfully withstand the resulting higher peak gas pressures.

For cost reasons, there is therefore great interest in defense technology, the desired ones Performance improvements in existing weapon platforms to accomplish. An innovative concept for this is based on a family of new sub-calibrators Ammunition (frangible, arrow). This provides the desired target impact by conversion of kinetic energy, i.e. without additional explosives. Still leaves fire this new type of ammunition out of common weapons. Because of this new type of ammunition only the kinetic projectile energy to achieve the desired target effect is available is the muzzle velocity, i.e. the speed at which the ammunition component leaves the gun barrel, resp. with what kinetic Energy hits the projectile on the target, of greatest importance here. The higher the Muzzle velocity is, the more effective is the effective effect, in particular in such kinetic bullets the loss of speed (small drag coefficient) is very low. A reduction in flight time and a trajectory stabilization are other important positive aspects resulting from a high muzzle velocity, which also has a lower wind sensitivity and an increase in the first hit probability causes.

The new sub-caliber high-performance ammunition described above The required muzzle velocities are new in defense technology Propellant powder (TLP) requires that compared to single-base nitrocellulose-based Propellant powders have a higher kinetic energy on the ammunition component can transmit. The problem with deploying this required new high performance TLP is now to avoid unwanted side effects, i.e. on the required increased performance level still the full extended system compatibility regarding pipe (erosion, corrosion), weapon (peak gas pressures, cadence) and environment (avoidance to ensure environmentally problematic recipe components). That too should ballistic stability, i.e. the length of time within which the propellant powder filled ammunition can be fired safely and in accordance with requirements conventional propellant powders cannot be reduced. After all, it is desirable that the required high-performance TLPs can be manufactured cost-effectively, i.e. starting from easily accessible, inexpensive starting materials and in particular no complex processing (such as rolling processes with multi-base TLP) need.

With powders, which contain large amounts of crystalline explosives such as hexogen, octogen or contain CL-20 (nitramine powder), although high muzzle velocities can be achieved, but the pipe life will be unacceptably low Reduced number of shots. The reason for this undesirable behavior is that the Flame temperature of the combustion gases in the gun barrel due to the high energy content this powder is very high as well as the high hydrogen content in the resulting Combustion gases.

Another approach to increasing the energy content is to add a suitable one high-energy explosive oil to the grain matrix. In this context First of all, the so-called spherical powder. The maximum size of the spherical However, powder particles are limited. Therefore, however, these powders are inherently explosive and very explosive have gained technical importance especially in the small caliber sector. Furthermore compared to single-base TLP, these powders mostly have a severely restricted ballistic and chemical stability.

So-called two-base TLP are known from US 4,963,296. You make a second Powder type, which contains an explosive oil incorporated in the grain matrix. As a result of elaborate manufacturing process, however, these powders are very expensive. Furthermore For medium-caliber applications, this powder type causes strong pipe erosion and has therefore practically of no technical importance in this area.

In the publication by B. Vogelsanger, K. Ryf, Int. Annu. Conf. ICT (1998), 29th (Energetic Materials), 38.1-38.14 are new types of functional, high-energy materials described, which thanks to a functional, layer-like structure in the grain matrix Disadvantages described above do not have. Based on this novel Functional materials have succeeded in creating a new generation of high performance TLP (Bulk powder), which among other things successful as drive components for sub-caliber High-performance ammunition can be used and the achievement of allow high muzzle velocity required by technology. The beneficial Characteristics of this new TLP generation is achieved through a targeted, layer by layer Structure of the cylindrical powder grain reached. There is the energetic one Plasticizers or explosive oils and a polymeric desensitizer in the desired outer 100-500 microns of the powder grain. There is also a portion of the Explosive oil also in the perforated zones of the TLP. Thanks to this specifically adjustable, layer by layer Construction were now accessible for the first time TLP, which is a special, specifically controllable Burning behavior, which brings several positive properties: So can unacceptably high peak gas pressures can be avoided because of the stratified The structure of the outer and inner zones of the powder grain advantageously influences the combustion behavior becomes. As a result of this property, the energy content of this functional Materials are better converted into kinetic muzzle energy. By the possibility a targeted adjustment of the distribution profiles of explosive oil and desensitizer TLP can be realized with optimal burning behavior for different caliber sizes. This provides maximum flexibility with regard to adaptation for different Weapon and ammunition types possible. As a result, the powders have a high kinetic Muzzle energy and a high thermal efficiency.

In addition, the layered structure of the outer skin and the inner zones of the new types Powder has a burning behavior that is largely independent of the temperature of the powder body. This means that within a wide temperature range similarly high muzzle velocities and peak gas pressures result. This has to Consequence that regardless of the ambient temperature at which the ammunition fired a similarly high muzzle energy is available, i.e. the propellant powder behaves largely independent of temperature.

Finally, the functional materials have very high bulk densities. The bulk density is a measure of which weight of propellant powder can be accommodated in a certain volume unit and is typically given in the unit g _TLP / l. This positive property is of great importance because the shell volume of a given ammunition component is predetermined. The more amount of powder that can be accommodated in this given sleeve volume, the higher the potential that can be converted into kinetic energy. For example, with comparable peak gas pressure, a muzzle energy increased by up to 12% compared to conventional single-base TLP can be achieved.

Presentation of the invention

The object of the invention is to provide a method of the type mentioned at the outset, which allows the precise adjustment of the layer structure.

The solution is defined by the features of claim 1. According to the invention the plasticizer and / or the desensitizer in the form of an aqueous emulsion in the absorbent (unimpregnated) grain, i.e. diffused into the so-called green powder.

The invention is based on the surprising finding that the impregnation The functional materials are also produced in an aqueous emulsion can, which also TLP with the desired layer-like structure result. The The present invention therefore involves the process of impregnating an untreated single-base green powder in aqueous emulsion, as well as the subsequent completion to provide the functional, layered TLP.

The invention thus differs significantly from the known methods in which Impregnations, by means of which the layer-like distribution of the explosive oil and the Have the desensitizers set specifically, typically in so-called polishing drums be performed. In these known methods, a batch of unimpregnated Powder (green powder) a liquid impregnating substance (or, if necessary, a solution of a solid impregnating substance, dissolved in a suitable solvent), added, wherein the impregnating substance into the powder grain under rotation and at elevated temperature is diffused. The problem with diffusion in these known methods of highly sensitive explosive oils such as nitroglycerin due to acute safety risks would arise and the production of larger quantities of functional high-energy Materials would complicate, if not make impossible avoided in the method according to the invention.

The impregnation process can be carried out in a 2-step process or in a 1-step process be performed. In the 2-step process, the green grain is first in one aqueous emulsion treated with the explosive oil. After the exposure is finished the excess emulsion is pumped out. The liquid proportions in the reactor can by a Strainer to be drained. Then the powder mass (remaining in the reactor) is combined in one Another process step of an aqueous emulsion containing the polymeric desensitizer exposed. This procedure allows good control of the process parameters.

In the 1-step process, analogous to the 2-step process, the green grain is first of all with a treated aqueous emulsion of the explosive oil. After the exposure time, the the remaining emulsion is not separated from the powder, but with the addition of the polymer Phlegmatizers continue to be used. By varying the addition times of the explosive oil or the polymeric desensitizer and the time, the concentration profiles be changed in a targeted manner. The 1-step process includes fewer process steps and is therefore more economical.

The aqueous emulsion used can be used in both the 1-stage and the 2-stage process known auxiliaries (stabilizers and / or wetting agents) are added as required which, among other things, suppress foam formation, stabilize the emulsion or can specifically influence the penetration behavior of the active components.

The advantages of the layered TLP compared to a conventional single-base TLP are illustrated in the following table. It can clearly be seen that the new manufacturing process to be protected produces TLPs which have a layered structure and have similar advantageous properties to the materials described in EP 0 960 083 A1, ie a markedly increased performance potential can be achieved under weapon-compatible conditions over the entire temperature range (see Table 1).

Another aspect of the present invention is the provision of novel functional Materials that improved over the materials described above Have properties. In the case of B. Vogelsanger, K. Ryf, Int. Annu. Conf. ICT (1998), 29th (Energetic Materials), 38.1-38.14, materials described for the Impregnation uses only explosive oils such as nitroglycerin. However, these point are known to have some drawbacks. One such disadvantage is the extremely high sensitivity of these explosive oils. Nitroglycerin and dinitrodiglycol each have a sensitivity to impact from just 0.2 Nm to what their handling during processing very difficult and restricted. Another disadvantage of these explosive oils is their high level Energy content (heat of explosion) for nitroglycerin 6542 J / g and for dinitrodiglycol Is 4527 J / g. If the powder now contains large amounts of these explosive oils, the amount increases the flame temperature during combustion and thus leads to an increase in pipe erosion.

It has now surprisingly been found that these explosive oils can be replaced in the impregnation process by energetic plasticizers which have a lower energy content and advantageous thermodynamic properties and which are additionally less sensitive to impact. The novel powders resulting from this are surprisingly distinguished by a significantly improved ratio of Vo / Pmax, that is to say higher muzzle velocities can be achieved when the pressure reserves are used. In addition, functional materials of this type also have a favorable ratio of _{ΔVo gTLP} / ΔPmax _gTLP , that is to say, per gram of charge increase, the muzzle velocity increases more than the pressure than with TLP based on explosive oils. This effect is illustrated in Example 3 below.

A large number of energetic plasticizers are known in powder technology. These include, in particular, low-molecular aliphatic nitric acid esters, nitro compounds, nitramines and azides. A class of substances which is particularly suitable for this purpose are the so-called 2-nitroxyethyl-nitramaines (alkyl-NENA) with the general structural formula I, where R _{1 is} an aliphatic radical. Another particularly suitable class of substances for this are the so-called dinitro-diazaalkanes of the general formula II, where R ₂ and R _{3 are} aliphatic radicals. The use of substances of the general structure II is known in powder technology, but so far these substances have never been built into the powder matrix in layers, but were distributed homogeneously in the powder matrix analogously to a 2-based TLP (cf. EP 960083A1). The plasticizers can be introduced into the green grain individually or as a mixture.

The present invention also relates to novel functional materials which additionally contain a crystalline energy carrier in the basic matrix made of nitrocellulose. Such crystalline energy sources are known per se. These are, for example, so-called crystalline nitramines of the general formula III. The radical R _{4 forms} part of a ring system and can preferably contain further units of the structure (-CH ₂ -N-NO ₂ ).

Particularly preferred compounds of structure III are hexogen IV, octogen V and CL-20 VI.

The upper limit of the crystalline energy content is such that the maintain mechanical strength of the resulting powder grain even at low temperature remains. In order to ballistically recognize the expected positive effect, the amount should not be less than about 5%. These compounds of general structure III or mixtures of these, therefore, in amounts between 5-80%, preferably 10-50% of the total powder mass, mixed with the nitrocellulose matrix and are homogeneously distributed in the finished grain. The powders pretreated in this way (which functionally correspond to the green powder) then through an impregnation process which corresponds to that described above results in layered grain structure and is also part of the present invention, treated with an energetic plasticizer and a desensitizer. The advantage of these layered functional materials is that they are opposite the functional materials that do not contain any crystalline energy in the grain matrix included, have an increased energy content, which thanks to the special Layer structure optimally converted into kinetic energy in a system-compatible manner can be.

1) Imprägnierungsprozess: Behandlung in wässriger Emulsion eines "Grünpulvers" aus Nitrocellulose beliebiger Form mit einem Sprengöl als energetischem Weichmacher und einem Phlegmatisator in 1- oder 2-Stufenprozess.

2) Neuartige funktionale energetische Materialien mit schichtartigem Aufbau hergestellt gemäss 1), welche aber anstelle von Sprengöl einen unempfindlichen energetischen Weichmacher des Typs I oder II oder Mischungen davon enthalten, sowie deren Herstellungsprozess in wässriger Emulsion und deren Verwendung als Treibladungspulver.

3) Neuartige funktionale energetische Materialien hergestellt gemäss 1) oder 2), welche zusätzlich einen kristallinen Energieträger des Typs III, homogen verteilt in der Korn-Matrix, enthält, deren Herstellungsprozess in wässriger Emulsion und deren Verwendung für die Herstellung von Treibladungspulver.

In summary, the invention can be described as follows:

1) Impregnation process: Treatment in an aqueous emulsion of a "green powder" of nitrocellulose of any shape with an explosive oil as an energetic plasticizer and a desensitizer in a 1 or 2 step process.

2) Novel functional energetic materials with a layer-like structure produced according to 1), but which instead of explosive oil contain an insensitive energetic plasticizer of type I or II or mixtures thereof, as well as their manufacturing process in aqueous emulsion and their use as propellant charge powder.

3) Novel functional energetic materials produced according to 1) or 2), which additionally contains a crystalline energy carrier of type III, homogeneously distributed in the grain matrix, their production process in aqueous emulsion and their use for the production of propellant charge powder.

The impregnation process for the production of high-energy functional materials is described below. The impregnation process goes from untreated Green powder of any shape, which essentially consists of nitrocellulose with an N content between 11-13.5%. The green powder used can optionally be used in powder technology well-known additives for stabilization, pipe protection, softening and flare control contain. Known additives which are suitably used are sodium bicarbonate (CAS- #: 144-55-8), calcium carbonate to increase stability (CAS- #: 471-34-1), magnesium oxide (CAS- #: 1309-48-4), Akardit II (CAS- #: 724-18-5), Centralit I (CAS- #: 90-93-7), Centralit II (CAS- #: 611-92-7), 2-nitrodiphenylamine (CAS- #: 836-30-6) and diphenylamine (CAS- #: 122-39-4), for softening about diethyl phthalate (CAS- #: 84-66-2), camphor (CAS- #: 76-22-2), dibutyl phthalate (CAS- #: 84-74-2), Di-n-propyl adipate (CAS- #: 106-19-4) or methylphenyl urethane (CAS- #: 261-79-6), for Tube protection, e.g. magnesium oxide (CAS- #: 1303-48-4), molybdenum trioxide (CAS- #: 1313-27-5), Magnesium silicate (CAS- #: 14807-96-6), calcium carbonate (CAS- #: 471-34-1) or Titanium dioxide (CAS- #: 13463-67-7), and for fire suppression about sodium oxalate (CAS- #: 62-76-0), potassium bitarate (CAS- #: 868-14-4), sodium hydrogen carbonate (CAS- #: 144-55-8), Potassium hydrogen carbonate (CAS- #: 298-14-6), sodium oxalate (CAS- #: 62-76-0), potassium sulfate (CAS- #: 7778-80-5) or potassium nitrate (CAS- #: 7757-79-1). Furthermore, the green powder other known additives, for example to improve the ignition behavior and Modulation of the burning behavior, included. All of the additives mentioned are during added to the powder dough during green grain production, i.e. they are even in distributed the grain matrix. The total amount of these additives in the green grain is between 0-20% the nitrocellulose, preferably between 5-15%.

Green powder is typically cylindrical single or multi-hole powder with a ratio of diameter / grain length between 0.5-2.0, preferably 0.9-1.5. The The outside diameter of the green powder is in the range between 0.5-10 mm, preferably 0.5-5 mm. The hole diameter is between 0.03-0.7 mm. The green grain can known way by pressing a solvent-containing powder dough in an extruder or obtained by extrusion.

The manufacturing method according to the invention can be one-stage or two-stage. The The impregnation process should first be illustrated using the 2-step process: The above Green powder described is placed in a metallic reactor vessel, which with Lid inlet valve, bottom outlet valve, mechanical and static flow fittings and connections for vacuum and which is equipped with 1-5 times the amount Water (compared to the amount of powder to be treated) is loaded. The powder can first Pre-bathed with stirring for 4-24 hours at a temperature of 20-85 ° C become. Then a solution of the is for a period of 10-60 minutes Explosive oil (approx. 20% dissolved in a suitable solvent) was added, the proportion of the Explosive oil compared to the green grain used is in the range of 3-20%. You leave Now continue treating for 2-8 hours before the pressure is raised to 400 - 600 mbar reduced and the solvent is distilled off from the liquor. The recovered If necessary, distillate can be recycled in the process. After that, the approach cooled and the remaining liquid components through the bottom valve in the reactor floor drained. Thereafter, the reactor is again 1-5 times the powder mass Amount of fresh water added and heated to 80 ° C. Then you give during an emulsion of the polymeric desensitizer (approx. 10% in water, proportion compared to green grain between 1-5%). It can be used Small explosive oil and polymer desensitizer solutions Amounts of auxiliaries, for example to stabilize the emulsion or to increase the Stability of the TLP, to be added. With optimal backmix setting (depends on Powder grain) is allowed to continue treatment for 2-6 hours before starting again is cooled to room temperature. After that, the remaining liquid portions through the bottom valve of the reactor vessel, which is covered with a fine-mesh sieve is provided, drained. The impregnated functional remains in the reactor vessel Material that unloads from the reactor vessel after the sieve has been removed and on close-meshed metal screens for drying with warm air flowing through is spread.

The 1-step process is carried out analogously to the 2-step process described above with the only difference that after the exposure time of the explosive oil solution the liquid portions remain in the reactor and the desensitizing emulsion directly is added. By varying the addition times, the exposure times and the time the pressure drop can reduce the burn-off characteristics of the finished powder be influenced in a targeted manner.

It has been shown in practice that the control parameters are more precise in the 1-step process let set. Furthermore, the 1-step process is due to the smaller one Number of process steps much cheaper.

That by means of the 1- or. Functional obtained 2-stage process Material is finally polished by polishing 0.01-2% graphite and, if necessary, more known auxiliaries in amounts of 0-4% in a known manner in a polishing drum completed. It was surprisingly found that the functional Materials in this polishing process in propellant powder with extremely high Have bulk densities of 1060 - 1100 g / l transferred. This allows in a given sleeve volume to bring a maximum amount of cargo.

Suitable explosive oils can be nitroglycerin (CAS- #: 55-63-0) or diethylene glycol dinitrate (Dinitrodiglycol, CAS- #: 693-21-0) can be used. It is a multitude of connections possible, which can be used as suitable desensitizers. On the one hand the affinity with the nitrocellulose must be such that the desensitizer with the appropriate Diffuse solvent as transport medium (carrier) into the powder grain can. On the other hand, no further diffusion is allowed after the removal of the solvent occur, which would lead to a change in the distribution profile. As suitable have organic ether and ester compounds with a molecular weight between 100-100,000, preferably between 1000-10,000.

A previously unknown novel class of functional energetic materials is obtained by replacing the explosive oils described above with less impact-sensitive (simply put: "insensitive") energetic plasticizers of the general structures I or II. On the one hand, it was surprisingly found that these novel functional materials are distinguished by a particularly favorable ratio of Vo / Pmax. In addition, such functional materials have a favorable ratio of _{ΔVo gTLP} / ΔPmax _gTLP , ie the muzzle velocity per gram charge increases compared to the pressure more than with layer-like TLP based on explosive oils.

Second, these insensitive energetic plasticizers perform compared to conventional ones Blasting oils to lower the explosion heat by 150-200 J / g what a lowering of the flame temperature during the powder burn-up and thus an improvement the pipe life.

The production of the novel functional materials with energetic plasticizers of the general structures I and II is based on an untreated green grain based on nitrocellulose, analogous to the functional materials containing explosive oil described above. The impregnation step in aqueous emulsion also proceeds analogously as before, with the only exception that energetic plasticizers of the general structures I or II or mixtures thereof are now used instead of the explosive oils. Compounds with R ₁ = C ₁ -C ₁₀ alkyl, C ₁ -C ₁₀ alkoxy or aryl, R ₂ and R ₃ independently of one another have proven to be C ₁ -C ₅ alkyl or C ₁ -C ₅ alkoxy . Particularly preferred are compounds with R ₁ = C ₁ -C ₄ (methyl, ethyl, n-propyl, i-propyl, n-butyl, i-butyl, t-butyl), R ₂ / R ₃ independently of one another C ₁ -C _{4 2} (methyl, ethyl).

Another class of previously unknown functional energetic materials is obtained by adding a crystalline energy source to the green grain described above admits the general formula III. The crystalline energy sources can optionally Before incorporation into the powder dough, the size distribution is adjusted by grinding are or if necessary cleaned by recrystallization. The production The green grain is used to achieve a homogeneous distribution of the crystalline Energy sources in the matrix by means of known methods such as, for example, by extrusion with the help of static mixers or by processing in twin screw extruders.

Using the above novel novel high energy functional materials layer-like grain structure is used as propellant bulk powder, especially for medium and Small caliber applications, suitable.

From the following detailed description and the entirety of the claims there are further advantageous embodiments and combinations of features of the invention.

Ways of Carrying Out the Invention Example 1: Manufacturing process in aqueous emulsion

200 kg of a 7-hole green powder with 2.77 mm outside diameter, 3.17 mm length and 0.12 mm hole diameter, made up of the fixed parts of 1.2% Akardit-II, 1% Calcium carbonate, 0.4% potassium sulfate and 97.4% nitrocellulose with a nitrogen content of 13.15% and produced in a manner known in powder technology by pressing of a solvent-wet kneading paste through a die, are in a 1000 liter Steel reactor equipped with mechanical paddle stirrer, lid inlet valve, bottom outlet valve and and connections for vacuum, mixed with twice the amount of water.

The mixture is then heated to a temperature of 85 ° C and under constant Stir pre-bathed while maintaining the temperature for 15 hours. After that at 80 ° C a mixture containing 12.5 kg nitroglycerin and 0.25 kg 2-nitrodiphenylamine, dissolved in 60 liters of ethanol, added dropwise over a period of 30 minutes. You leave now for 2 1/4 hours with optimal backmix setting (powder bed completely in Treat) and then drip over a period of 15 minutes a suspension containing 1.97 kg of a non-solid, highly viscous at room temperature Average molecular weight polyester of 3000 (which is water soluble and as The desensitizer works in 30 kg of water. Then you leave while stirring Treat for a further 2 hours at a temperature of 80 ° C. Then will the pressure in the reactor vessel is slowly reduced to 600 mbar and parts of the solvent distilled off from the fleet. Then the vacuum is broken and the batch is opened Cooled to room temperature. Then the remaining liquid portions of the Approach drained by opening the bottom valve, the remaining damp Powder mass with 100 liters of fresh water and for 2 hours with the heating switched off continued stirring. Then the liquid components are again through the bottom valve drained and the remaining wet powder matrix then from the reactor away.

The moist powder is now spread evenly on coarse-mesh metal sieves and with warm air flowing through at a temperature of 60 ° C for 24 hours dried. The TLP is finally polished by polishing approx. 0.3% graphite and, if necessary by treatment with special moderators in the known manner in the polishing drum completed.

The completed TLP has an explosion heat of 3999 J / g, its bulk density is 1062 g / liter. In a 25 mm barrel weapon, a muzzle velocity of 1438 m / s can be achieved with a sub-caliber arrow projectile of mass 123 g at 21 ° C while observing the weapon-approved maximum gas pressure, which corresponds to a muzzle energy of 1271 J / g _TLP .

At -32 ° C the same powder with the same charge as before reaches a speed of 1416 m / s, at 62 ° C 1442 m / s. In contrast, there is a conventional single-base TLP, shot in the same weapon system as before with a sub-caliber arrow ammunition of mass 130 g at 21 ° C a muzzle velocity of 1381 m / s, which corresponds to a muzzle energy of 1191 J / g. At -30 ° C a muzzle velocity of 1320 m / s, at 50 ° C that of 1411 m / s.

Example 2: Manufacturing process in aqueous emulsion

Analogously to Example 1, 200 kg of a 7-hole green powder with an outside diameter of 2.57 mm, 2.94 mm long and an average hole diameter of 0.16 mm from the solid proportions of 1.2% Akardit-ll, 0.2% calcium carbonate, 1.4% potassium sulfate and 97.2% nitrocellulose with a nitrogen content of 13.15%, with 14.4 kg nitroglycerin and Treated 3.3 kg of the same polyester as in Example 1. That after completion The propellant powder obtained as in Example 1 has a bulk density of 1063 g / l at an explosion heat of 3961 J / g.

In a 20 mm barrel weapon, a muzzle velocity of 126 g and a charge mass of 44.5 g at 21 ° C can achieve a muzzle velocity of 1063 m / s at a peak gas pressure of 4146 bar (compliance with the weapon-permissible peak gas pressure), which is a kinetic muzzle energy of 1601 J / g _TLP and a thermal efficiency of 0.404.

Example 3: TLP with energetic plasticizer

Analogously to Example 2, 200 kg of a 7-hole green powder with an outside diameter of 2.65 mm, a length of 3.06 mm and an average hole diameter of 0.16 mm, built up from the solid proportions of 1.2% Akardit-II, 0.2% calcium carbonate, 1.4% potassium sulfate and 97.2% Nitrocellulose with a nitrogen content of 13.15%, with 14.4 kg of a mixture of 60% methyl-NENA (compound I, R ₁ = methyl) and 40% ethyl-NENA (compound I, R ₁ = ethyl) and with 2.8 kg of the same polyester as treated in Example 1. The resulting propellant powder has a bulk density of 1070 g / l with a heat of explosion of 3799 J / g.

In a 20 mm barrel weapon, a muzzle velocity of 908 m / s can be achieved with a bullet with a mass of 126 g and a load of 44.5 g at 21 ° C, while with a load of 42 g it can reach 853 m / s. This results in a speed increase of 22.0 m / s per gram of load with a pressure increase of 116.4 bar, which corresponds to a ratio Δ Vo _gTLP / Δ Pmax _gTLP of 0.19. In the TLP from example 2, the same ratio has a value of only 0.07. When loading (adding charge) in TLP of example 3, the increase in speed goes hand in hand with a significantly lower increase in pressure than in the case of propellant charge powder in example 2.

Example 4: TLP with grain matrix made of nitrocellulose + crystalline energy carrier

Analogously to Example 3, 200 kg of a 7-hole green powder with an outside diameter of 3.00 mm, a length of 3.50 mm, an average hole diameter of 0.17 mm and a density of 1.62 g / ml, built up from the solid proportions of 20.0% RDX (also referred to as hexogen) ; see structure IV) an average grain size of 5 micrometers, 1.0% Akardit-II, 0.4% calcium carbonate, 0.6% potassium sulfate, 1% residual solvent and 77% nitrocellulose with a nitrogen content of 12.6%, with 14.4 kg of a mixture of 60% methyl -NENA (compound I, R ₁ = methyl) and 40% ethyl-NENA (compound I, R ₁ = ethyl) and treated with 2.8 kg of a non-solid polyester compound with an average molecular weight of 3000 which is viscous at room temperature. The propellant charge powder resulting after completion, as in Example 1, has a bulk density of 1071 g / l with an explosion heat of 3963 J / g.

In summary, it should be noted that in addition to the manufacturing process itself Known TLP also proposed new TLP in which the known explosive oils NGL and DEGN are replaced by reduced-sensitivity energetic plasticizers. These TLPs are less sensitive to vibrations. To optimize performance crystalline energy sources must be added to the grain matrix.

The resulting layered TLPs show full system compatibility a higher level of performance than normal TLP and a balanced temperature behavior on. The TLP are cheaper to manufacture and compared to two-based TLP do not have the disadvantageous burning properties (pipe erosion) of nitramine-containing TLP on.

Claims (18)

Process for producing a functional, high-energy material with a layer-like structured grain containing an energy-rich plasticizer and a polymeric desensitizer, characterized in that the plasticizer and / or the desensitizer is or are diffused into the absorbent grain in the form of an aqueous emulsion. A method according to claim 1, characterized in that the grain consists essentially of nitrocellulose, in particular that it consists of at least 80% of nitrocellulose with a nitrogen content of 11-13.5%. Method according to one of claims 1 or 2, characterized in that the grain has a cylindrical structure with a ratio of diameter to length between 0.5 and 2.0, an outer diameter between 0.5 and 10 mm and that in particular at least one hole, preferably several holes with one Hole diameter between 0.03 and 0.7 mm is or are. A method according to claim 3, characterized in that the grain is produced by pressing a solvent-containing powder dough from nitrocellulose in an extrusion press or by means of extrusion, the solvent-containing powder dough in particular substances of the general structure III with R4 = (-CH2-N-NO2) n and n = 2 or 3, in a total proportion of 5-80% of the dry matter of the powder dough, the added substances preferably having the structures IV, V or VI and the total proportion in the absorbent grain being between 10-60%.

Method according to one of claims 1 to 4, characterized in that a diffusion depth in the range of 100-500 µm is generated. Method according to one of claims 1 to 5, characterized in that a solution or emulsion of the high-energy plasticizer in an organic solvent is fed to a mixture of untreated green powder in water, followed by the addition of a solution or emulsion of the desensitizer in water, preferably the Add the solution or emulsion of the high-energy plasticizer in an organic solvent and the solution or emulsion of desensitizer in water is carried out at a temperature between 20-85 ° C. A method according to claim 6, characterized in that the green powder to be treated is pre-bathed for 4-24 hours at a temperature of 20-85 ° C before adding the solution or emulsion of the high-energy plasticizer liquid at room temperature in an organic solvent in the reactor with stirring . Method according to one of claims 6 or 7, characterized in that the green powder is placed in 1 to 5 times the amount by weight of water. Method according to one of claims 6 to 8, characterized in that after the addition of the solution or emulsion of the desensitizer has ended, the pressure in the reactor vessel is reduced to 400-800 mbar for 2-6 hours and that the remaining liquid components are removed from the reactor through a bottom sieve drained and that the resulting powder mass is dried with warm air. Method according to one of claims 1 to 9, characterized in that 0.01-2% graphite is applied to the dried powder mass in a polishing drum in order to obtain a bulk powder with a bulk density> 1000 g / l. Method according to one of claims 1 to 10, characterized in that the high-energy plasticizer is nitroglycerin or diethylene glycol dinitrate or in particular structure I or II with R ₁ = C ₁ -C ₁₀ alkyl, C ₁ -C ₁₀ alkoxy or aryl, R ₂ and R ₃ independently of one another have C ₁ -C ₅ -alkyl or C ₁ -C ₅ -alkoxy and are used in an amount of 5-20% compared to the green powder.

A method according to claim 11, characterized in that the high-energy plasticizer has the structure I or II with R ₁ = C ₁ -C ₄ (methyl, ethyl, n-propyl, i-propyl, n-butyl, i-butyl, t-butyl ), and with R ₂ / R ₃ independently of one another has C ₁ -C ₂ (methyl, ethyl).

Method according to one of claims 1 to 12, characterized in that an organic ether and ester compound having a molecular weight between 100-100,000 is used as the polymeric desensitizer. Functional high-energy material with a layer-like structured grain formed by a high-energy plasticizer and a polymeric desensitizer, characterized in that the high-energy plasticizer has structure I or II with R ₁ = C ₁ -C ₁₀ -alkyl, C ₁ -C ₁₀ Alkoxy or aryl, R ₂ and R ₃ independently of one another have C ₁ -C ₅ -alkyl or C ₁ -C ₅ -alkoxy and are used in an amount of 5-20% compared to the green powder.

Functional high-energy material according to claim 14, characterized in that the green powder is produced by pressing a solvent-containing powder dough from nitrocellulose, the solvent-containing powder dough containing substances of structures IV, V or VI, in a total proportion of 10-60% of the dry substance of the powder dough.

Green grain for the production of a functional, high-energy material with a layer-like structured grain containing an energy-rich plasticizer and a polymeric desensitizer, the green grain being formed by pressing a solvent-containing powder dough out of nitrocellulose, characterized in that the solvent-containing powder dough has substances of structure IV, V or VI, in contains a total of 10-60% of the dry matter of the powder dough.

Propellant powder containing a high-energy functional material according to claim 14. Ammunition with a propellant powder according to claim 17.