CH644831A5 - METHOD FOR PRODUCING A MULTI-BASED POWDER CHARGE POWDER. - Google Patents

Description

The invention relates to a method for producing a polybasic propellant charge powder for tubular weapons with nitrocellulose and explosive oil as an energy source.

In such multi-base propellant powders, the explosive oil has the purpose of increasing the energy content of the propellant charge powder, which is characterized by the heat of explosion, beyond the value that can be achieved with so-called single-base powders essentially consisting only of nitrocellulose and practically the energy content of the nitrocellulose itself (e.g. approx. 4000 J / g). The explosive oil also serves as a gelatinator for the nitrocellulose. Because of the desired increase in energy, occasionally used oils that gelatinize nitrocellulose, but with an energy content below or at most that of the lowest nitrated and still used for powder, are not referred to as explosive oil. The following alcohol nitrates have technical significance as explosive oil in the above sense:

Nitroglycerin (= NGL)

Diethylene glycol dini stepped (= diglycol dinitrate = DEGN) /

ch2-o-no2

I.

ch-o-no2

I.

ch2-o-no2 ch2-o-no2

I.

ch2 ch2

I.

ch2-o-no2

1,2,4-butanetriol trinitrate

Methriol trinitrate ch2-o-no2

I.

ch2

I.

ch-o-no2 ch2-o-no2 ch2-o-no2

I.

ch3-c-ch2-o-no2 ch2-o-no2

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Explosive heat 6322 J / g oxygen value + 3.5%

40

45

Explosive heat 4857 J / g oxygen value -40.8%

Explosive heat 5945 J / g oxygen value -16.6%

50

Explosive heat 5175 J / g oxygen value -34.5%

Common propellant powders contain a single explosive oil. The explosive oil used, its content, the content of nitrocellulose and its degree of nitration determine the properties of the propellant powder and its behavior during manufacture. The level of nitriding, which is typically between 11.8 and 13.4% N2, influences the manufacturing process and the energy content of the propellant powder. This applies to an even greater extent to the explosive oil used in each case. Since the explosive oils e.g. differing in gelling behavior compared to nitrocellulose, the heat of explosion and the oxygen value, propellant powder with different properties can therefore be produced with them.

The most energetic propellant powders are obtained using nitroglycerin. For example, a two-base, propellant powder made with solvent with approx. 40% nitroglycerin can be set to an explosion heat of 5000 J / g. In contrast, a comparable propellant powder with diglycol dinitrate produces an explosion heat of 4200 J / g.

Taking into account the manufacturing process for a propellant powder, its heat of explosion can practically not be increased above a certain value, depending on the explosive oil used. So it is e.g. impossible to produce a propellant powder with diglycol dinitrate as an explosive oil that can be produced without solvents and which has an explosion heat of 4750 J / g. In such cases, it has so far been customary to use a higher calorific oil, in the example above, nitroglycerin, and the simultaneous incorporation of energy-consuming substances such as e.g. Centralite or phthalates. The use of energy-consuming substances is necessary because propellant powder for reasons of manufacture, e.g. B. its homogenization and gelatinization on the hot 55 rolling mills, a certain minimum amount of explosive oils, so in the example nitroglycerin, required, but through which the required heat of explosion would be exceeded without the use of energy-consuming substances. On the other hand, the energy-consuming substance in the propellant powder Bal-60 last for its actual function, which may adversely affect the properties of the propellant powder that may be desired.

The known three-base propellant powder, 65 e.g. the nitroguanidine-containing nitroglycerin powder or the nitroguanidine-containing diglycol dinitrate powder, the so-called gudol powder, each contain only one explosive oil. Therefore, the hiring of one within a

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644 831

A conventional propellant powder A has the following composition:

Nitrocellulose with 13.1% N2 52.00% by weight

Nitroglycerin 40.00% by weight

Plasticizer 5.50% by weight

Stabilizers 2.50% by weight

100.00% by weight The heat of explosion is approx. 4600 J / g.

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valued range of any given heat of explosion is not possible without energy-consuming substances. The additional energy source contained in three-phase propellant powders, e.g. the nitroguanidine cannot be used for such an adjustment because it does not cause gelling, but is a filler whose incorporability into the nitrocellulose explosive oil gel is limited.

DE-OS 2 603 927 discloses polybasic propellant powder in which the nitroglycerin can be completely or partially replaced by other, explosive organic nitric acid esters, ie explosive oils, namely the explosive oils mentioned at the outset. DE-OS neither specifies the purpose of the measure to produce a propellant powder from nitrocellulose and an explosive oil mixture, nor the advantage that can be achieved with it. The core of the is DE-OS is different, namely the coating of the individual propellant powder particles with an acrylic resin layer to influence the combustion behavior.

The invention is based on the object of specifying an easy-to-carry out process for producing a multi-base propellant powder in which the heat of explosion of the propellant powder obtained can be adjusted to a specific, desired value in a wide energy range and also the other properties of the propellant powder obtained, especially the shooting behavior and the shelf life, are still improved compared to conventional propellant powders.

This object is achieved according to the invention with the method characterized in claim 1 and with respect to advantageous refinements in claims 2-6. 30th

In the method according to the invention, it is possible in a simple and inexpensive manner to use a specific, predetermined heat of explosion of the propellant powder produced without the use of dietary fiber, which only serves to generate energy, but only by correspondingly varying the proportions of at least two different, i.e.

also to set the exact level of different explosive oils in terms of their energy content, the incorporation of a mixture of two or more explosive oils into the nitrocellulose in such a way that the proportion of the low-calorie explosive oil is made as large as possible and high-calorie explosive oils are only incorporated into the propellant powder with the proportion as it is is necessary to achieve the required heat of explosion, the exact setting of the required heat of explosion allows 45 taking into account the specified limits for the composition or the total explosive oil content, which by the respective method of manufacture - without solvent, with a limited amount of solvent or with Solvents - are drawn, and taking into account the other, 50 of the propellant powder according to the required properties, eg the explosive oil binding behavior in relation to the risk of exudation.

The advantageous comparison of the heat of explosion in a propellant powder according to the invention obtained using the new method without the use of exclusively energy-consuming dietary fibers is shown in the following comparison:

60

65

Another conventional propellant powder B has the following composition:

Nitrocellulose with 12.6% N2 56.00% by weight

Nitroglycerin 38.80% by weight

Stabilizers 5.10% by weight

Magnesium oxide + graphite 0.10% by weight

100.00% by weight The heat of explosion is approx. 4600 J / g. A propellant charge C according to the invention has the following composition:

Nitrocellulose with 13.0% N2 59.50% by weight

Diglycol dinitrate 24.80% by weight

Nitroglycerin 14.90% by weight

Stabilizers 0.70% by weight

Magnesium oxide + graphite 0.10% by weight

100.00% by weight The explosion heat is again approx. 4600 joules / g.

The propellant charge powders A and B contain a significantly higher proportion of stabilizers and plasticizers or stabilizers than is necessary per se. The excess portion is used exclusively for energy consumption, by which the heat of explosion is set to the specified value. In the case of propellant powder C according to the invention, on the other hand, the same explosion heat is achieved without the need for separate energy consumption by installing two explosive oils in appropriate proportions.

To compare the powder properties, the propellant powders B and C were used in a weapon of 105 mm caliber. It was found here that the propellant powder C according to the invention is clearly more favorable than the propellant powder B in the external temperature-pressure behavior. The propellant powder B at -40 ° C already showed a pressure increase to be assessed as critical, which under otherwise identical conditions for the propellant powder C did not occur.

The shooting properties of the propellant powder A and C were compared with a weapon of 120 mm caliber. It was found that bullet speeds were achieved with the propellant powder C according to the invention, which were only achieved with propellant powder A at pressures which were 100 to 200 bar higher.

This results in a clear ballistic superiority of the propellant charge powder according to the invention with several explosive oils over the conventional propellant charge powder.

The propellant charge powder according to the invention has a further advantageous property:

In modern weapon systems, instead of conventional metal cartridges, more and more combustible cartridge cases are used. These exist e.g. B. from a high proportion of nitrocellulose and additional neutral fibers, a resin binder and a chemical stabilizer for the nitrocellulose. Due to their material composition, they can absorb plasticizers and explosive oils in contact with propellant powders. In order to ensure that ammunition with combustible cases can be stored for a long time, it is important that the propellant powder releases as little explosive oil as possible into the case material.

When the propellant powder according to the invention was examined in this regard, it was surprisingly found that it releases significantly less explosive oil into combustible sleeve material than known propellant powder.

In detail, a check was carried out with the propellant powders A and C listed above in such a way that propellant powder is pressed between two pieces of combustible sleeve material and sealed in well-sealable

644 831

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bottles was stored at 65 "C and 80 ° C. The increase in weight of the combustible sleeve material was monitored over time.

The following weight increases were determined at a storage temperature of 80 ° C:

Powder A

Powder C

Difference after 1 week after 3 weeks after 6 weeks

9.0% 16.7% 21.4%

7.3% 12.0% 14.5%

1.7% 4.7% 6.9%

At a storage temperature of 65 ° C, the following weight gain was determined after 18 days:

Powder A

Powder C

8.0%

6.9%

1.1%

The results shown clearly show the superiority of the propellant charge powder according to the invention over a known propellant charge powder with regard to the blasting oil transition into the sleeve material.

Finally, due to the precise adjustability of the heat of explosion, a propellant charge powder according to the invention can still be expected to have the advantage of a comparatively lower weapon barrel erosion.

Four exemplary embodiments of the propellant charge powder according to the invention are explained in more detail below.

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example 1

For a solvent-free diglycol dinitrate / nitroglycerine propellant powder: 35

The following are mixed together in a 400-1-putty common in powder production:

148.8 kg dry weight of a powder raw material containing 30% water of the following composition, based on dry weight: 40

60% nitrocellulose with a nitration level of 13.0% nitrogen 25% diglycol dinitrate 15% nitroglycerin;

1.080 kg Arkarditll 45

0.075 kg magnesium oxide 0.075 kg graphite

After optimal mixing in the kneader, the mass is processed on a roller kneader at 85 ° C in the usual way to a well gelatinized skin, 50 then rolled into a press wrap and pressed in a hydraulic press at 70 ° C to a 7-hole strand, whose diameter and web width are set according to the ammunition requirements. After the strands have been cut to the required length, the powder is mixed after the maturation storage 55.

The finished powder has the following composition within the tolerance limits:

Nitrocellulose with 13.0% nitrogen 59.5% by weight diglycol dinitrate 24.8% by weight 60

Nitroglycerin 14.9% by weight

Akardit II 0.7% by weight

Graphite 0.05% by weight

Magnesium oxide 0.05% by weight

100.00% by weight 65 Its heat of explosion is approx. 4600 J / g.

The favorable ballistic behavior described above was determined on the propellant charge powder.

Example 2

for a solvent-free butane triol trinitrate / nitroglycerine friction powder:

The kneading approach is as follows:

148.8 kg dry weight of a powder raw material containing 30% water of the following composition, based on dry weight:

64% nitrocellulose with a degree of nitration of 13.0% nitrogen, 22% 1,2,4-butanetriol trinitrate,

14% nitroglycerin,

0.375 kg CentralitI 0.675 kg Akardit II 0.075 kg magnesium oxide 0.075 kg graphite

The production corresponds to example 1. The finished powder has the following composition within the tolerance limits:

Nitrocellulose with 13.0% nitrogen 63.50% by weight 1,2,4-butanetriol trinitrate 21.70% by weight

Nitroglycerin 14.00% by weight

Centralite I 0.25% by weight

Akardit II 0.45% by weight

Graphite 0.05% by weight

Magnesium oxide 0.05% by weight

100.00% by weight Its heat of explosion is approx. 4950 J / g.

Example 3

For a solvent-free diglycol dinitrate / nitroglycerin / nitroguanidine propellant powder:

The kneading approach is as follows:

103.8 kg dry weight of a powder raw material containing 30% water analogously to Example 2 with diglycol dinitrate instead of 1,2,4-butanetriol trinitrate 45.0 kg nitroguanidine 0.300 kg centralite I 0.750 kg Akardit II 0.075 kg magnesium oxide 0.075 kg graphite

The production corresponds to example 1. The finished powder has the following composition within the tolerance limits:

Nitrocellulose with 13.0% nitrogen 44.30% by weight diglycol dinitrate 15.00% by weight

Nitroglycerin 9.90% by weight

Nitroguanidine 30.00% by weight

Centralite I 0.20% by weight

Akardit II 0.50% by weight

Magnesium oxide 0.05% by weight

Graphite 0.05% by weight

100.00% by weight Its heat of explosion is approx. 4100 J / g.

Example 4

For a solvent-containing butane triol trinitrate / methriol trinitrate / diglycol dinitrate / nitroguanidine propellant powder:

The following are poured into a 400 liter modeling clay:

172 kg of a 30% alcohol-containing nitrol cellulose with 12.8% N2 (= 110 kg nitrocellulose, converted to non-alcoholic substance)

40 kg nitroguanidine 2 kg Akardit II

A mixture of the following explosive oils, which have been desensitized with solvents, is introduced into this premixed mixture:

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644 831

16 kg 1,2,4-butanetriol trinitrate

Methriol trinitrate 16 kg diglycol dinitrate 40 kg alcohol-ether mixture

After mixing in the kneader, the batch is left to ripen at about 25 C for 10 days, then kneaded again and then pressed into single-hole strands in a hydraulic press. After cutting, the powder is dried in a warm air stream, possibly under vacuum.

The finished powder has the following composition within the tolerance limits:

Nitrocellulose with 12.8% nitrogen 55.00% by weight 1,2,4-butajitriol trinitrate 8.00% by weight methriol trinitrate 8.00% by weight diglycol dinitrate 8.00% by weight

Nitroguanidine 20.00% by weight Akardit II 1.00% by weight

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100.00% by weight The heat of explosion is approx. 3960 J / g.

s

Claims (6)

644 831 PATENT CLAIMS 1. A process for producing a multi-base propellant charge powder for tubular weapons, in which a mixture of at least two of the explosive oils nitroglycerin, diglycol dinitrate, methriol trinitrate and 1,2,4-butanetriol trinitrate is incorporated into the nitrocellulose in a certain total explosive oil content, thereby characterized in that no more energy-consuming fiber is incorporated than is necessary exclusively for stabilization, and that the proportion of the high-calorific explosive oil (s) in the total explosive oil content is measured so that the propellant charge powder has a certain, predetermined explosion heat . 2. The method according to claim 1, characterized in that the total explosive oil content, based on the nitrocellulose content, is set to at most 100% by weight in the case of solvent-free production. 10th 15 3. The method according to claim 2, characterized in that the total explosive oil content is set to a value between 54 wt .-% and 82 wt .-%. 4. The method according to claim 3, characterized in that in the nitrocellulose, based in each case on the nitrocellulose content, 33-52% by weight, preferably 41-43% by weight, diglycol dinitrate and 21-30% by weight, preferably 24-26% by weight, nitroglycerin can be incorporated. 5. The method according to claim 1, characterized in that the total explosive oil content is adjusted to a maximum of 30 wt .-% when producing with a limited amount of solvent as a gelatinization aid. 6. The method according to claim 1, characterized in that the total explosive oil content, based on the nitrocellulose content, is adjusted to a maximum of 150% by weight when produced with solvents.