EP1616845A1 - Pourable propellant powder - Google Patents

Abstract

Pourable propellant powder comprising nitrocellulose-based grains includes 0.1-2 wt.% bismuth as a decoppering additive. Independent claims are also included for: (1) producing a propellant powder as above by adding bismuth or a bismuth compound in an amount of 0.1-2 wt.% in a polishing process together with graphite so that the bismuth is incorporated into a surface layer of the grain; (2) producing a propellent powder as above by extruding green grains from a kneadable mass containing 0.1-2 wt.% bismuth and surface-treating the green grains to produce powder grains with a bismuth-containing matrix; (3) small-, medium- and large-caliber munitions with a lead-free projectile and a lead-free propellant as above.

Description

Technical area

The invention relates to a pourable propellant charge powder with grains based on nitrocellulose containing bismuth as Entkupferungsadditiv. Furthermore, the invention relates to a process for the preparation of the propellant charge powder and to an ammunition with such a propellant powder.

State of the art

Free-flowing, nitrated cellulose-based propellant powders are used in the caliber ranges from 5.56 mm (small caliber) to 80 mm (medium caliber) in a wide front as drive for accelerating the respective projectile. Such bulk powders have been routinely used for several years and have proven themselves due to their high ballistic performance (high muzzle velocity), excellent chemical and ballistic stability (use in warm climates), cheap availability (good price / performance ratio, renewable raw materials, available in large quantities ) and good properties with respect to bombardment resistance (no detonative reaction when exposed to hollow charge jet or hot splinters).

Especially in the small caliber area, the use of lead has been widely used in several ammunition components. Thus, the bullet often contained lead to improve end-effect and trajectory. As an example, see mentions the double-core projectile, which is made up of two lead cores of different hardness and a bullet jacket made of Tombak. The tombac sheath ensures a lower throughput resistance of the projectile and thus a reduced running load, since tombac alloys, which are composed of the elements copper and tin (Tombak is thus brass with a copper content of 70-90%), are very good cold formable. Lead compounds have also often been used for ignition, e.g. Bleiazide.

More recently, with respect to polluting emissions, which by the application resp. Use of leaded ammunition emanated, tightened regulations introduced. For example, Sweden decided to allow only unleaded bullets from 2007 onwards.

For several years now, developments have been underway aimed at completely circumventing the use of lead and its compounds. Thus, a new generation of lead-free bullets and lead-free ignitions has recently been developed. Characteristic of such modern projectiles is the absence of the traditional lead core. This was replaced by plastically deformable, homogeneous materials, which typically made of copper or a copper alloy. Even with these new floors, the bullet jacket can consist of Tombak. On the ignition side, toxicologically improved variants have now been developed, for example the lead- and barium-free Sintox ignition set from RUAG Ammotec.

It is known from experience that when copper-containing projectiles are fired, unwanted narrowing can occur in the barrel. These consist of deposits of copper, which can not be completely removed even with great cleaning effort and cause the pipe to be replaced after a relatively low load. The bullet is driven through the barrel by the tremendous gas pressure resulting in an extremely strong friction between the bullet material and the steel of the barrel. A mirror-like barrel also has microfine pores, which are smeared by the bullet material. In addition, it has been shown that lubricated material leads to further deposits. Trace and field edges are rounded off over time, which of course gradually reduces the precision of the barrel. The frictional resistance increases and the projectile velocity drops accordingly. Increasing deposits lead to precision waste. These general considerations apply in principle to large, medium and small caliber applications.

It is also known that lead or its compounds, which are shot together with the ammunition, can effectively suppress such tube copper plating (WM Robertson, Decoppering of gun tubes by lead, Army Armament Command, Rock Island, IL, USA, Gov Rep. Announce Index (US) 1975, 75 (23), 164, CAS 1976: 139485). It goes without saying that there is no possibility of lead addition to prevent the unwanted copper-up effect of lead-free ammunition.

One possible approach to circumvent the copper-plating problem is to shoot a so-called "decoupling bullet" at intervals. However, this approach has significant logistical disadvantages. To achieve a maximum Entkupferungseffekts the "Entkopferungsgeschoss" may also contain high levels of lead compounds, which is not environmentally toxicologically desirable. Another possibility is the mechanical removal with special cleaning equipment, which may be constructed, for example, as a brush with highly abrasive wire material.

Another approach is the direct incorporation of the Entkupferungsadditivs in the bulk powder (WO 03/066544, Nexplo Bofors AB). In this case, combinations of tin and bismuth are used, with tin or bismuth being proposed in metallic form, in alloyed form or in compounds. The tin content should be 10-62% and the bismuth fraction 38-90%. However, since the environmental toxicity of tin compounds is significantly higher than that of bismuth compounds, this approach has limited environmental toxicological progress.

It is known from EP 1 031 547 A1 or US 2001/0042576 A1 that Bi203 is suitable as an additive in the production of perforated propellant charge powder for decoppering. The additives should be in a range of 0-15 wt .-% move.

In large caliber applications, the decoloring additive may be added separately to the powder mass. In the past lead foils were used, which due to their toxicity may not be used in the future. As an alternative, the addition of an additive composite compound (= additive) is described in which the Entkupferungsadditiv is incorporated in amounts of 5-95% in an energetic binder (US 5,565,643, EP 0 805 943 B1). As Entkupferungsadditive be bismuth, indium, zinc and titanium metal resp. Alloys thereof mentioned. In practice, however, the application of the described method is problematic, since the significant difference in density between the additive composite and the bulk powder known to lead to a separation of the two different types of grain, resulting in an uncontrolled respectively. incomplete burning of the powder mass result. In addition, the addition of an additive composite to a normal bulk powder is technically more complex and therefore more expensive than the use of a uniformly structured drive. Furthermore, the additive composite burns only incomplete because of its high content of inert material, which can lead to increased residue formation.

There is therefore still a clear need in the bulk powder technology for an efficient technical solution with which the copper oxide copper can be effectively and cost effectively prevented and which have the disadvantages described above such as low toxicological advantage over existing lead compounds, expensive manufacturing process or limited use does not have heat and cold.

Presentation of the invention

The object of the invention is to provide a pourable propellant powder belonging to the technical field mentioned at the outset, which leaves less copper deposits in the barrel of the rifle or gun and is environmentally harmless.

The solution of the problem is defined by the features of claim 1. According to the invention, the bismuth compound is contained in the grains in an amount of 0.1-2% by weight. Also, metallic / elemental bismuth may be used alone (i.e., without any other metal such as tin or the like) as a decoloring additive.

• Kostengünstige Herstellung der die Rohraufkupferung unterbindenden Schüttpulvers (analog konventionellem Schüttpulver ohne Additiv)
• Keine Entmischung während Lagerung (da kein Zusatzstoff notwendig)
• Keine Empfindlichkeit gegenüber Einwirkung von Wärme und Kälte (Liner an Patronenwand, bei welchem Additiv in Binder eingearbeitet ist)
• Regelmässiger und rückstandfreier Abbrand der gesamten Pulvermasse (kein schwerverbrennbarer Additivzusatz, welcher das Entkupferungsadditiv enthält)
• Bestmögliche umwelttoxikologische Entlastung, da das Entkupferungsadditiv eine reine Bismuth-Verbindung ist, keine Zinnverbindungen enthält und bei tiefen Additiv-Konzentrationen von ca. 0.2-1.0 Gew.-% eingesetzt werden kann.
• Überraschenderweise tritt bei den erfindungsgemässen, das Entkupferungs-Additiv enthaltenden Schüttpulvern zusätzlich ein rohrschonender Effekt auf.

Compared with the prior art, the present invention offers, inter alia, the following advantages:

• Cost-effective production of bulk bulk copper powder (analog conventional bulk powder without additive)
• No segregation during storage (no additive necessary)
• No sensitivity to the effects of heat and cold (liner on cartridge wall, in which additive is incorporated in binder)
• Regular and residue-free burning off of the entire powder mass (no heavy-burnable additive additive containing the de-coppering additive)
• Best possible environmental toxicological relief, since the Entkupferungsadditiv is a pure bismuth compound, contains no tin compounds and can be used at low additive concentrations of about 0.2-1.0 wt .-%.
• Surprisingly, in addition, a tube-sparing effect occurs in the bulk powders according to the invention containing the de-coupling additive.

Very good results have resulted from the use of bismuth (III) oxide as bismuth compound. In practice, bismuth oxide (Bi ₂ O ₃ , melting point 817 ° C, boiling point 1'890 ° C, Density 8.9 g / ccm, CAS no. 1304-76-3, EINECS no. 215-134-7) with a mean grain diameter of 10 microns. Also, elemental bismuth (CAS No. 7440-69-9, EINECS No. 231-177-4) and bismuth carbonate oxide (CAS No. 5891-10-4, EINECS No. 227-567-9) a surprisingly clear decolouring effect. The bismuth or the bismuth compound should in any case be present in the form of very fine grains (<100 microns). A particle size of less than 20 micrometers is preferred.

The bismuth compound (or elemental bismuth) may be distributed in the grain matrix underlying the grains or on the surface or in a surface forming layer of the grains. In the former case, the bismuth compound is added to the kneading mass during the preparation of the TLP (TLP = propellant charge powder). In the latter case, the bismuth compound is added during the surface treatment so that the bismuth compound and the metallic bismuth, respectively, have a higher concentration in the near-surface layer than in the grain matrix. The surface layer in question is e.g. formed together with the graphite powder and has a thickness of typically up to 50 microns. However, other solids may also be included in the surface layer (such as lime or potassium sulfate). The graphite powder is used in a known amount (<1 wt .-%).

The bismuth compound or metallic bismuth should be present as powders having a particle size of less than 100 microns, more preferably 20 microns or less. Fine bismuth powders have proven to be particularly effective.

According to a preferred embodiment, the total amount of bismuth compound contained in the powder grain is incorporated in about half of the total amount in the grain matrix and about half in the near-surface layer. The concentration is thus greater immediately below the surface than inside the grain.

The bismuth (III) oxide is preferably present in a concentration of between 0.5% and 1.2% by weight.

The small, medium and large caliber based bulk powder is based on nitrocellulose with a nitrogen content between 11-13.5% by weight and can be used as further energetic additives Explosive oils (NGL or DEGN or their combination) or energetic plasticizers (Bu-NENA, Et-NENA or Me-NENA or their combination). Preferably, nitroglycerin (NGL) is provided in an amount between 3-20% by weight in a near-surface layer. The size of the near-surface layer depends on the depth of diffusion that the NGL achieves during surface treatment (eg, diffusion depth d between 100-500 microns). Preferably, the nitroglycerin content is in the range of 4-8 wt% for medium caliber and 10-17 wt% for small caliber. Optionally in the grain matrix existing energetic plasticizer resp. Blasting oils can be homogeneously distributed in the grain matrix (2-base bulk powder) or concentrated in the outer layer of the grain matrix (so-called EI® powder, see EP 1 164 116 A1). If the grain matrix no energetic plasticizer resp. Contains explosive oils, it is 1-base bulk powders.

The shape of the bulk powders is adapted to the respective application and can be: Cylindrical with axial channels running in the axial direction (number of holes = 0-30), spherical or sheet-like flat (rolled).

The grains have e.g. a maximum geometric extension of 20 mm. If the geometry of the grains is cylindrical, the ratio of length (L) to diameter (D) is 0.25-5, with a length of the grain between 0.3-10 mm and the diameter of the circular cylindrical grain between 0.3-10 mm. If the geometry of the grains is spherical, the diameter of the grains usually ranges between 0.2-20 mm, preferably between 1-5 mm.

If the geometry of the grains is leaf-shaped, the thickness is between 0.3-5 mm and the diagonal between 1-15 mm.

In addition to nitrocellulose, the grains may contain crystalline energy carriers and / or energetic plasticizers or blasting oils as further main components. As a crystalline energy carrier, for example, one of the following substances is used: nitroguanidine (CAS #: 556-88-7), hexogen (CAS #: 121-82-4) and octogen (CAS #: 2691-41-0). Suitable energy softeners are nitroglycerin, diethylene glycol dinitrate, Me-NENA, Et-NENA, Bu-NENA. Of course, two or more of these substances can be combined.

The total amount of these energetic liquid additives is between 0-40 wt .-% compared to the nitrocellulose, preferably between 5-20 wt .-%. The crystalline energy carriers can be added during the kneading of the dough mass.

The weight percentages of the crystalline energy carriers are between 0-45 wt .-% of the powder mass, the weight percentages of energy plasticizers between 0-45 wt .-%. Together, the weight should not be more than 75 wt .-% of the powder mass.

Overall, bismuth (III) oxide in a concentration between 0.1-2 wt .-%, the energetic plasticizer in a concentration between 0-25 wt .-% and the crystalline energy sources in a concentration between 0-30 wt .-% in front. Together, the energetic plasticizer and the crystalline Energieträeger represent a proportion of not more than 50 wt .-%. If neither an energetic plasticiser nor a crystalline energy source are provided (both 0%), then one speaks of a one-base propellant charge powder (only NC as energy carrier).

A method according to the invention for the production of a propellant charge powder is characterized in a first embodiment in that the bismuth compound or the metallic bismuth is introduced into a near-surface layer of the grain during the polishing process (finishing). If the bismuth or bismuth compound is to be homogeneously distributed in the grain matrix, the said decoloring additive is added to the kneading compound prior to extrusion. Thereafter, the green grain can be formed by extrusion.

The propellant powder makes it possible to produce small, medium and large caliber ammunition which has a lead-free bullet and a lead-free igniter.

• Zusätze zur Stabilitätserhöhung sind z.B. Natriumhydrogenkarbonat (CAS-#: 144-55-8), Calziumkarbonat (CAS-#: 471-34-1), Magnesiumoxid (CAS-#: 1309-48-4), Akardit II (CAS-#: 724-18-5), Centralit I (CAS-#: 90-93-7), Centralit II (CAS-#: 611-92-7), 2-Nitrodiphenylamin (CAS-#: 836-30-6) und Diphenylamin (CAS-#: 122-39-4).
• Zusätze zur Weichmachung sind z.B. Diethylphthalat (CAS-#: 84-66-2), Campher (CAS-#: 76-22-2), Dibutylphthalat (CAS-#: 84-74-2), Di-n-propyladipat (CAS-#: 106-19-4) oder Methylphenylurethan (CAS-#: 261-79-6).
• Zusätze zur Rohrschonung sind z.B. Magnesiumoxid (CAS-#: 1303-48-4), Molybdäntrioxid (CAS-#: 1313-27-5), Magnesiumsilikat (CAS-#: 14807-96-6), Calciumkarbonat (CAS-#: 471-34-1) oder Titandioxid (CAS-#: 13463-67-7).
• Zusätze zur Feuerscheindämpfung sind z.B. Natriumoxalat (CAS-#: 62-76-0), Katiumbitarat (CAS-#: 868-14-4), Natriumhydrogenkarbonat (CAS-#: 144-55-8), Kaliumhydrogenkarbonat (CAS-#: 298-14-6), Natriumoxalat (CAS-#: 62-76-0), Kaliumsulfat (CAS-#: 7778-80-5) oder Kaliumnitrat (CAS-#: 7757-79-1).

Additives known in powder technology for stabilization, pipe preservation, softening and fire-damping can be used:

• Additives for increasing stability include sodium hydrogen carbonate (CAS #: 144-55-8), calcium carbonate (CAS #: 471-34-1), magnesium oxide (CAS #: 1309-48-4), acardite 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).
• Plasticizer additives include, for example, 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 methylphenylurethane (CAS #: 261-79-6).
• For example, 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).
• Additives for fire suppression are, for example, sodium oxalate (CAS #: 62-76-0), catium bitarate (CAS #: 868-14-4), sodium hydrogen carbonate (CAS #: 144-55-8), potassium bicarbonate (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 may contain other known additives, for example for improving the ignition behavior and for modulating the burn-off behavior.

All of the additives mentioned are added to the dough mass during green grain production, i. they are evenly distributed in the grain matrix. The total amount of these additives in the green grain is between 0-20 wt .-% compared to the nitrocellulose, preferably between 5-15 wt .-%. The production of the bulk powders according to the invention comprises the known process steps "kneading with solvents", "extrusion by die", "drying" and "finishing" (surface treatment). The bismuth compound is added either during kneading (homogeneous distribution in the grain matrix) or during finishing (enrichment at grain surface).

The bulk powder may optionally be accompanied by other additives. These include on the one hand the classic blasting oils nitroglycerin (NGL, CAS #: 55-63-0) or diethylene glycol dinitrate (DEGN, CAS #: 693-21-0). In powder technology, a variety of other energetic plasticizers is also known. These include in particular low molecular weight aliphatic nitric acid esters, nitro compounds, nitramines and azides. A particularly suitable class of substances are the so-called 2-nitroxyethyl-nitramines (alkyl-NE-NA) having the general structural formula (1), where R _{1 is} an aliphatic radical:

Another particularly suitable class of substances for this purpose are the so-called dinitro-diazaalkanes of the general formula (II) where R ₂ and R _{3 are} aliphatic radicals:

The total amount of these energetic liquid additives is between 0-40 wt .-% compared to the nitrocellulose, preferably between 5-20 wt .-%. The liquid additives are either distributed homogeneously in the grain matrix, wherein the powder production is carried out by the known processes kneading / rolling / pressing. In addition, an enrichment in the outer zones of the powder grain is conceivable, whereby the production of such bulk powder by impregnation of a green grain in aqueous emulsion takes place (see, EP 1 164 116 A 1).

The bulk powders according to the invention have the following geometries: Cylindrical with 0-30 (preferably 1-19) axial longitudinal channels. The outer diameters are between 0.3-15 mm (preferably 0.5-7.5 mm), the lengths are 0.3-15 mm (preferably 0.5-7.5 mm). The ratio of grain length to grain diameter is 0.5-3.0 (preferably 1.0-1.5). The diameters of the longitudinal channels are between 0.05-0.5 mm (preferably 0.1-0.4 mm). In the case of the spherical grain geometry, the diameters are in the range of 0.3-5.0 mm (preferably 0.5-2.0 mm).

The geometric dimensions of the bulk powders included in the present application are primarily determined by the caliber range. So can the powder grains for Small caliber applications (caliber range from about 5.56 to about 20 mm) on the one hand have cylindrical geometries with a diameter of about 0.5-3 mm, wherein the length of a powder grain is typically about 0.5 to 2.0 times the value of the respective grain diameter. In addition, the cylindrical powders may contain longitudinal channels extending in the axial direction for influencing the burning behavior. In practice, 1- and 7-hole geometries have proven particularly useful, wherein the diameter of the hole zones is typically between 0.05 to 0.5 mm. In addition to the cylindrical grain geometry, the spherical grain geometry has also proven successful in the small bore range, with the ball diameters typically ranging from 0.3 to 2.0 mm, depending on the caliber range.

For central caliber applications (caliber range from 20 to approximately 80 mm), experience has shown that the cylindrical grain geometry has proved advantageous, with a plurality of longitudinal channels extending in the axial direction normally being contained in the powder grain for controlling the burnup characteristic. Powder grains with 1, 7 or 19 longitudinal channels, whose diameter is typically 0.05-0.5 mm, have proved to be particularly suitable. Even in the medium caliber range, however, pourable powders with spherical grain geometry can be used for certain applications.

From the following detailed description and the totality of the claims, further advantageous embodiments and feature combinations of the invention result.

Brief description of the drawings

Fig. 1

eine schematische Darstellung der Bismuth-(III)-oxid Konzentration bei einem bevorzugten Pulverkorn;

Fig. 2

eine tabellarische Zusammenstellung der Herstellungsbeispiele 1 bis 10.

The drawings used to explain the embodiment show:

Fig. 1

a schematic representation of bismuth (III) oxide concentration in a preferred powder grain;

Fig. 2

a tabular summary of Preparation Examples 1 to 10.

Ways to carry out the invention

In Fig. 1, the course of the bismuth (III) oxide concentration of a preferred embodiment is shown schematically. The bismuth compound acting as a decoloring additive in this example is one half in the grain matrix (i.e., in the whole grain volume) and the other half in the surface layer. The outer diameter D is e.g. 0.7-1 mm. The surface layer thickness d is e.g. 50 microns. (Figure 1 is not drawn to scale.)

In the following, several embodiments are given. They are summarized in Fig. 2 in tabular form.

Production Example 1 (0.35% by weight of bismuth oxide on the grain surface and 0.35% by weight in the interior of the grain, NGL on the grain surface)

200 kg of a 1-hole green powder with 0.73 mm outside diameter, 0.93 mm length and 0.10 mm hole diameter, composed of the solid portions of 1.5% by weight of acardite II, 1% by weight potassium sulfate, 0.35% by weight bismuth (III) oxide and 97.4 wt .-% nitrocellulose having a nitrogen content of 13.15 wt .-% and prepared in the manner known in the powder art by pressing a solvent-moist kneading dough through a die, are equipped in a 1'000 liter steel reactor equipped with mechanical paddle , Lid inlet valve, bottom outlet valve and vacuum connections, with twice the amount of water added.

Subsequently, the batch is heated to a temperature of 80 ° C. Thereafter, a mixture containing 25 kg of nitroglycerin (12.5 wt .-%) and 0.5 kg (0.25 wt .-%) 2-nitrodiphenylamine, dissolved in ethanol, added dropwise. It is allowed at optimal baking mix adjustment (powder bed completely in suspension) and then drips a suspension containing 6.0 kg (3 wt .-%) of a highly viscous at room temperature polyester compound having an average molecular weight of 1'500 g / mol in water. Then allowed to aftertreat stirring. Subsequently, the pressure in the reactor vessel is slowly reduced and distilled off parts of the solvent from the liquor. Thereafter, the vacuum is broken and cooled the approach. After that, the remaining liquid Parts of the approach drained by opening the bottom valve. Finally, the liquid portions are drained again through the bottom valve and the remaining wet powder matrix is then removed from the reactor. The wet powder is dried and then finished by polishing about 0.3 wt .-% graphite, 0.35 wt .-% finely pulverized bismuth (III) oxide and optionally other special moderators in a known manner in the polishing drum. The resulting bulk powder has a bulk density of 940 g / l with an energy content of 3893 J / g.

Preparation Example 2: (Reference 1 - no bismuth compound)

Analogously to Preparation Example 1, a 1-hole green powder having an outer diameter of 0.64 mm, a length of 1.03 mm and a hole diameter of 0.12 mm is first prepared, but in which no bismuth compound is added. This green powder is then treated analogously to Preparation Example 1 with nitroclycerol and the highly viscous at room temperature polyester compound having an average molecular weight of 1'500 g / mol. The polishing is carried out analogously to Preparation Example 1, but no bismuth compound is used. The finished bulk powder has a bulk density of 943 g / l with an energy content of 3,943 J / g.

Production Example 3: (0.7 wt .-% bismuth in outer layer)

Analogously to Preparation Example 1, a 1-hole green powder having an outer diameter of 0.64 mm, a length of 1.03 mm and a hole diameter of 0.12 mm is first prepared, but in which no bismuth compound is added. This green powder is then treated analogously to Preparation Example 1 with nitroclycerol and the highly viscous at room temperature polyester compound having an average molecular weight of 1'500 g / mol. The polishing is carried out analogously to Preparation Example 1, during which, however, 0.7% by weight of finely powdered bismuth powder is used during the polishing. The finished bulk powder has a bulk density of 940 g / l with an energy content of 3'918 J / g.

Production Example 4: (0.7% by weight bismuth carbonate oxide in outer layer)

A bulk powder is prepared analogously to Preparation Example 2, but 0.7% by weight of finely powdered bismuth carbonate oxide is used during the polishing. The finished bulk powder has a bulk density of 920 g / l with an energy content of 3'919J / g.

Production Example 5 : (0.7 wt .-% bismuth oxide in outer layer)

A bulk powder is prepared analogously to Preparation Example 2, but during the refinement, however, 0.7% by weight of finely powdered bismuth (III) oxide is used. The finished bulk powder has a bulk density of 945 g / l with an energy content of 3,923 J / g.

Production Example 6 : (Reference 2 - 0.7% by weight of tin dioxide in outer layer)

A bulk powder is prepared analogously to Preparation Example 2, but 0.7% by weight of finely powdered tin dioxide is used during the polishing. The finished bulk powder has a bulk density of 925 g / l with an energy content of 3'919 J / g.

Preparation Example 7 : (0.7% by weight of bismuth oxide in grain matrix)

Analogously to Preparation Example 1, a 1-hole green powder with 0.75 mm outside diameter, 0.97 mm length and 0.12 mm hole diameter is first produced, in which, however, 0.7 wt .-% bismuth (III) oxide is added. This green powder is then treated analogously to Preparation Example 1 with nitroclycerol and the polyester at room temperature highly viscous compound having an average molecular weight of 3,000 g / mol. The polishing is carried out analogously to Preparation Example 1, but no bismuth compound is used. The finished bulk powder has a bulk density of 923 g / l with an energy content of 3,921 J / g.

Production Example 8: (Ball Powder with 0.7% by Weight Bismuth Oxide in Outer Layer)

In a laboratory polishing drum made of glass with 1 liter internal volume and a drum temperature of 60 ° C to 100 g of a finished spherical powder with 0.39 mm diameter, a bulk density of 990 g / l and an energy content of 3'812 J / g, which in addition to nitrocellulose with a nitrogen content of 13.15 wt .-% as further main ingredients nitroglycerin (10 wt .-%), dibutyl phthalate (4.5 wt .-%), a mixture of 0.7g (0.7 wt .-%) bismuth (III) oxide and 0.1 g (0.1 wt.%) of graphite dispersed in 5 ml of ethanol. It is first allowed to turn for 1 hour with the lid closed. Thereafter, continue to rotate with the removal opening open until the bulk powder shows a shiny surface. The bulk powder is then removed from the polishing drum and then dried for 20 hours at a temperature of 60 ° C. The finished bulk powder has a bulk density of 966 g / l and an energy content of 3'782 J / g.

Production Example 9: (7-hole powder with 0.7 wt.% Bismuth oxide in outer layer)

In a laboratory polishing drum made of glass with 1 liter internal volume and a drum temperature of 60 ° C to 100 g of a finished 7-hole powder with an outer diameter of 2.21 mm, a length of 2.32 mm, a hole diameter of 0.16 mm and a middle Wall thickness of 0.47 mm, a bulk density of 1'034 g / l and an energy content of 3'256 J / g, which in addition to nitrocellulose with a nitrogen content of 13.15 wt .-% as further main ingredients camphor (6.5 wt .-%) and diphenylamine (1.5 wt%), a mixture of 0.7 g (0.7 wt%) of bismuth (III) oxide and 0.1 g (0.1 wt%) of graphite dispersed in 5 ml of 94% industrial spirit was added. It is first allowed to turn for 1 hour with the lid closed. Then, with the removal opening open, continue to turn until the bulk powder has a shiny surface. The bulk powder is then removed from the polishing drum and then dried for 20 hours at a temperature of 60 ° C. The finished bulk powder has a bulk density of 1'025 g / l and an energy content of 3'236 J / g.

Production Example 10: (3-base with 0.7 wt.% Bismuth oxide in outer layer)

In a polishing drum made of copper with 50 liters internal volume and a drum temperature of 60 ° C to 5 kg of a finished 19-hole powder with a mean outer diameter of 3.61 mm, a mean grain length of 3.80 mm, a mean hole diameter of 0.12 mm and a average wall thickness of 0.58 mm, a bulk density of 1'060 g / l and an energy content of 3'956 J / g, which in addition to nitrocellulose with a nitrogen content of 13.15 wt .-% as further main ingredients nitroguanidine (5.0 wt .-%) and Diethylene glycol dinitrate (18% by weight), a mixture of 35 g (0.7% by weight) of bismuth (III) oxide and 5 g (0.1% by weight) of graphite dispersed in 300 ml 94% by weight industrial spirit, added. It is first allowed to turn for 1 hour with the lid closed. Thereafter, continue to rotate with the removal opening open until the bulk powder shows a shiny surface. The bulk powder is then removed from the polishing drum and then dried for 20 hours at a temperature of 60 ° C. The finished bulk powder has a bulk density of 1,055 g / l and an energy content of 3,932 J / g.

Production Example 11 : (0.35% by weight of bismuth oxide in grain matrix, NGL on grain surface)

Analogously to Preparation Example 1, a 1-hole green powder with 0.73 mm outside diameter, 0.93 mm in length and 0.10 mm hole diameter is first produced. This green powder is then treated analogously to Preparation Example 1 with nitroglycerin and the polyester at room temperature highly viscous compound having an average molecular weight of 3000 g / mol. The polishing is carried out analogously to Preparation Example 1, but no bismuth compound is used. The finished bulk powder has a bulk density of 891 g / l with an energy content of 3'892 J / g.

Use Example 1 Powder from Production Example 2, Cleaning Efficiency in Lead-Free 5.56 mm Cartridge with Sintox Ignition.

Cartridge casings loaded with Sintox ignition elements were filled with bulk powder from Production Example 1 and sealed with a lead-free bullet. After that, 200 cartridges were fired. The cleaning effort to produce the original tube state was 130 double strokes.

Application example 2 : Powder from production example 6, cleaning effort in lead-free 5.56 mm cartridge with Sintox ignition.

Cartridge casings loaded with Sintox ignition elements were filled with bulk powder from Production Example 1 and sealed with a lead-free bullet. After that, 200 cartridges were fired. The cleaning effort to produce the original tube state was 110 double strokes.

Example of Use 3 Powder from Production Example 3, Cleaning Efficiency in Lead-Free 5.56 mm Cartridge with Sintox Ignition.

Cartridge casings filled with sintered ignition elements were filled with bulk powder from Production Example 3 and sealed with a lead-free bullet. After that, 200 cartridges were fired. The cleaning effort to produce the original tube state was 20 double strokes.

Use Example 4: Powder from Preparation Example 4, cleaning effort in lead-free 5.56 mm cartridge with Sintox ignition.

Cartridge casings loaded with Sintox ignition elements were filled with bulk powder from Production Example 4 and sealed with a lead-free bullet. After that, 200 cartridges were fired. The cleaning effort to produce the original tube state was 30 double strokes.

Use Example 5 Powder from Production Example 3, Cleaning Efficiency in Lead-Free 5.56 mm Cartridge with Sintox Ignition.

Cartridge casings loaded with Sintox ignition elements were filled with bulk powder from Production Example 5 and sealed with a lead-free bullet. After that, 200 cartridges were fired. The cleaning effort to produce the original tube state was 10 double strokes.

Use Example 6: Powder from Preparation Example 1, cleaning effort in lead-free 5.56 mm cartridge with lead-free ignition.

Cartridge casings loaded with Sintox ignition elements were filled with bulk powder from Production Example 1 and sealed with a lead-free bullet. This was 1,500 cartridges fired, the cleaning effort was determined after every 100 shots. The cleaning effort required to produce the original tube condition was between 10 and 20 double strokes for the shot loads examined (100 rounds, 200 rounds, 300 rounds, etc.). When using a non-bismuth-containing reference powder when using the same cartridge and ignition element is the weapon barrel after the same shot load no longer clean and is therefore unusable.

Use Example 7 Powder from Production Example 1, Caliber Enlargement at the Orifice (Pipe Outwash) in a Lead-Free 5.56 mm Cartridge with Lead-Free Ignition.

Cartridge casings loaded with Sintox ignition elements were filled with bulk powder from Production Example 1 and sealed with a lead-free bullet. This was 1,500 cartridges fired, the caliber at the mouth of the muzzle was determined after every 100 shots. After 800 shots occurred in the use of a non-bismuth-containing reference powder, a caliber extension of 5.54 mm to 5.55 mm, in the powder of Preparation Example 1, however, the caliber at the mouth after 1'500 shots compared to the initial state unchanged at 5.54 mm.

Example of Use 8 : Powder from Production Example 1, Free Flight with Lead-Free 5.56 mm Cartridge with Lead-Free Ignition.

Cartridge casings loaded with Sintox ignition elements were filled with bulk powder from Production Example 1 and sealed with a lead-free bullet. Hereupon 1,400 cartridges were fired, whereby the free flight (distance between sleeve mouth and introduction into running trains) after every 100 shots was determined. After 300 shots, when using a non-bismuth-containing reference powder, the free flight increased from 3.0 to 3.1 mm, after 800 shots from 3.1 to 3.2 mm and after 1 400 shots from 3.2 to 3.3 mm. In the case of the powder from Production Example 1, the first enlargement of the free flight by 0.1 mm only occurred after 700 shots, until 1,400 shots no longer changed.

The admixture of the investigated bismuth compounds to the inventive bulk powders causes no compatibility resp. Stability problems. All fabricated samples are below the maximum allowable heat development of 114 μW in heat flow calorimetry measurements performed according to STANAG 4582, regardless of the spatial distribution of the bismuth compound in the TLP grain.

In summary, a new technical approach has been found to prevent pipe coppering when using lead-free ammunition. This is based on the use of novel bulk powders in which a bismuth compound or elemental bismuth (without other metal) is incorporated and which are able to effectively prevent the Rohraufkupferung occurring when using lead-free projectiles and ignitions. The bulk powders can be used in principle for small, medium and large caliber applications.

Claims (21)

A granular propellant powder with nitrocellulose-based grains containing bismuth as a decoloring additive, characterized in that the bismuth is contained in the grains as bismuth compound or as metallic bismuth in an amount of 0.1-2% by weight. Propellant powder according to claim 1, characterized in that the bismuth compound is bismuth (III) oxide or bismuth carbonate oxide. Propellant powder according to one of claims 1 to 2, characterized in that the bismuth compound or the metallic bismuth is uniformly distributed in a grain matrix forming the grains. Propellant powder according to one of claims 1 to 3, characterized in that the bismuth compound or the metallic bismuth is accommodated in a surface layer of the grains, so that the bismuth compound or the metallic bismuth in the surface layer has a higher concentration than in the grain matrix. Propellant powder according to both claims 3 and 4, characterized in that the bismuth compound is distributed about halfway in the grain matrix and about half in the surface layer of the grains. Propellant powder according to one of Claims 1 to 5, characterized in that the bismuth compound or the metallic bismuth are present as powders having a particle size of less than 100 micrometers, in particular of 20 micrometers or less. Propellant powder according to one of claims 1 to 4, characterized in that the bismuth (III) oxide is present in an amount between 0.5 wt .-% and 1.2 wt .-%. Propellant powder according to one of Claims 1 to 6, characterized in that it contains between 3-20% by weight of nitroglycerin, in particular 4-8% by weight of nitroglycerin for medium caliber and 10-17% by weight of nitroglycerin for small caliber, in one near-surface layer contains. Propellant powder according to one of claims 1 to 7, characterized in that the grains have a cylindrical, spherical or sheet-like geometry. Propellant powder according to one of claims 1 to 8, characterized in that the grains have a geometric extension of 20 mm or less. Propellant powder according to claim 8 or 9, characterized in that the geometry of the grains is cylindrical, wherein a ratio of length (L) to diameter (D), L / D, is 0.25-5, and wherein a length of the grain between 0.3- 10 mm and a diameter of the grain is between 0.3-10 mm. Propellant powder according to claim 8 or 9, characterized in that the geometry of the grains is spherical, wherein a diameter of the grains is between 0.2-20 mm. Propellant powder according to one of claims 8 or 9, characterized in that the geometry of the grains is sheet-shaped with a thickness between 0.3-5 mm and a diagonal between 1-15 mm. Propellant charge powder according to one of claims 1 to 12, characterized in that the grains in addition to nitrocellulose as further main components crystalline energy carriers and / or energetic plasticizers or blasting oils. Propellant powder according to claim 13, characterized in that the crystalline energy carrier comprises one or more of the following substances: nitroguanidine, hexogen or octogen and the energetic plasticizers nitroglycerin, diethylene glycol dinitrate, Me-NENA, Et-NENA, Bu-NENA. Propellant powder according to any one of claims 13 to 14, characterized in that the weight percentages of the crystalline energy carriers between 0-45 wt .-% of the powder mass, the weight percentages of energy plasticizers between 0-45 wt .-% of the powder mass and not together more than 75 wt .-% of the powder mass. Propellant powder according to one of claims 13 to 15, characterized in that bismuth (III) oxide in a concentration between 0.1-2 wt .-%, the energetic plasticizer in a concentration between 0-25 wt .-% and the crystalline energy carrier is present in a concentration between 0-30 wt .-% and together amount to not more than 50 wt .-% of the powder mass. Process for producing a propellant charge powder according to one of Claims 1 to 16, characterized in that the bismuth or bismuth compound is added to a polishing process together with graphite in an amount of at least 0.1% by weight and not more than 2% by weight, so that the bismuth or the bismuth compound is introduced into a near-surface layer of the grain. A process for producing a propellant charge powder according to claims 1 and 3, wherein green particles are prepared by extrusion from a kneading material and these green grains are surface-treated for producing powder grains, characterized in that the kneading material prior to extrusion elemental bismuth or a bismuth compound, in particular bismuth - (III) oxide, in an amount of at least 0.1 wt .-% and at most 2 wt .-% is added as Entkupferungsadditiv to bring the bismuth or bismuth compound in a matrix of the powder grain. A method according to claim 17 or 18, characterized in that by a surface treatment nitroglycerin in an amount of 3-20 wt .-% is introduced into the grain. Ammunition for small, medium and large caliber with a lead-free projectile and with a lead-free ignition containing a pourable propellant charge powder according to one of claims 1 to 16.

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