NL7909134A - MULTIPLE COMPONENT POWDER FOR PROPULSIVE CARGO. - Google Patents

Description

49 428 / Bos / AS - 1 - Multi-component powder for a propelling load.

The invention relates to a multi-component powder for a propellant charge for firearms and flying projectiles containing nitrocellulose, explosive oil and optionally further nitro-5 compounds as energy carriers.

In such a multi-component propellant charge powder, the explosive aims to increase the energy content of the powder for a propellant charge, which is characterized by the heat of explosion, to exceed the value which, with a one-component, essentially only nitrocellulose, existing powder is accessible and practically corresponds to the energy content of the nitrocellulose itself (eg approx. 4000 Joules / g). In addition, the explosive oil serves as a gelatinizer for the nitrocellulose. Owing to the envisaged increase in energy, oils sometimes used, which effect a gelatinization of the nitrocellulose, but which have an energy content below or at most that of the lowest nitrated nitrocellulose and which are still used for powder, are not designated as explosives. Technical significance as a jumping oil in the above sense has the following alcohol nitrates:

Nitroglycerin Explosion heat 25 (= NGL) with the formula 1 6322 Joules / g from the formula sheet Oxygen value + 3.5%

Diethylene glycol dinitrate Explosion heat (= diglycol dinitrate = DEGN) 4857 Joules / g 30 of the formula 2 Oxygen value - 40.8% 1,2,4-Butanetriol nitrate Explosion heat of the formula 3 5945 Joules / g

Oxygen value - 16.6% 7909134 / - - 2 - * '* t

Methriol trinitrate Explosion heat of the formula 4 5175 Joules / g

Oxygen value -34.5%

Conventional propellants for a propulsion charge contain a single blasting oil. The explosive oil used in each case, its content, the content of nitrocellulose and the degree of nitration thereof, determine the properties of the powder for a propulsive charge and its behavior during preparation. For example, the degree of nitration typically between 11.8-13.4% nitrogen affects the manufacturing process and the energy content of the powder for a propellant charge. To an even greater extent this applies to the explosive oil used in each case. Since the jumping oils are distinguished, for example, in the gelling behavior with respect to the nitrocellulose, the explosive heat and the oxygen value, it is thus possible to prepare crosses for a propelling charge with various properties.

The most energy-rich crosses for a propelling charge are obtained when nitroglycerin is used. For example, a two component solvent propellant powder with about 40% nitroglycerin can be adjusted to an explosion heat of 5000 Joules / g. On the other hand, a comparable powder for a propellant charge with diglycumin nitrate produces an explosion heat of 4200 Joules / g.

Taking into account the preparation process for a propellant charge powder, its explosive heat cannot practically be increased above a certain value depending on the explosive oil used in each case. For example, it is impossible to prepare a propellant chargeable solvent-free powder 35 with diglycol dinitrate as the explosive oil, which has an explosion heat of 4750 Joules / g. In such cases it has hitherto been common practice to use the required explosion heat by using a higher calorific oil, in the above example nitroglycerine, and simultaneously incorporating energy-digesting substances, such as, for example, centralite or phthalates, into to set. The use of energy-consuming substances is therefore necessary, because powder for a propellant charge, due to its preparation, for example its homogenization and gelatinization on the hot rolling mills, requires a certain small amount of blasting oils, in this example 10 nitroglycerine. , however, so that the required explosion heat would be exceeded without the use of energy-consuming substances. On the other hand, the energy-consuming substance in the propellant charge powder may be ballast to its actual function, which under certain conditions adversely affects desirable powder properties for a propellant charge.

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Also, the known three-component crosses for a propelling charge, for example the nitroguanidine-containing nitroglycerin powder or the nitroguanidine-containing diglycol dinitrate powder, the so-called gudol powder, always contain only one explosive oil. Therefore, it is also not possible here to set an explosion heat 25 given arbitrarily within a noteworthy range without energy-consuming substances. The further energy carrier present in three-component propellants for a propelling charge, for example the nitroguanidine, cannot be used for such an adjustment, since it does not effect gelling, but is a filler, the possibility of incorporation of which in the nitrocellulose explosive oil gel is limited.

The object of the invention is to provide a new multi-component propellant powder. In particular, this must be adjustable to a desired explosion heat in a wide energy range, be easy to prepare and, moreover, also in its other properties, in particular in 7909134 --4- '* the shooting behavior and the suitability for storage / relative to conventional crosses for propelling charge have been improved.

This problem is solved according to the invention with a multi-component propellant charge powder which, instead of the conventionally used single blasting oil, contains two or more different blasting oils.

By the powder for a propelling charge 10.. according to the invention it is possible in a surprisingly simple manner to accurately adjust a given given explosion heat without the use of energy-consuming substances only by correspondingly varying the proportions of at least two different, i.e. also different in their energy content, spring oils. The freedom to measure achieved by the incorporation of two or more blasting oils allows the precise adjustment of a required explosion heat, also while respecting the limits for the composition, which have been drawn through the preparation path, and while respecting other properties that of a powder for a propelling charge may be required.

Jumping oils which are preferably used for the propellant charge powder according to the invention are mentioned in claims 2 and 3. Within the limits for the total content of the jumping oil, the lower limit of which generally relates to the production process and the upper limit. towards the spice properties and take into account, for example, the spring-oil bonding behavior with regard to the risk of exudation, the propellant charge powder according to the invention will advantageously be used within the meaning of claim 13 as a proportion of the low-calorie jumping oil as large as and higher-calorie jumping oils only with such a share in. the powder for a propelling charge, if this is necessary to achieve the required explosion heat.

Suitable powder compositions for a 7909134 4-5 propulsion charge according to the invention for a solvent-free preparation (solventless procedure). for example on rollers and / or extruders, preparation with limited addition of solvent 5 (semi-solvent procedure) and for preparation according to a classic solvent method (solvent procedure) are apparent from claims 4 to 12.

The advantageous adjustability of the explosion heat at a powder for a propelling charge according to the invention is apparent from the following comparative tests:

A conventional propellant charge A powder has the following composition:% by weight.

Nitrocellulose with 13.1% Nj 52.00

Ni troglycerin 40.00

Plasticizer 5.50

Stabilizers 2.50 100.00 20 The explosion heat is approx. 4600 Joules / g.

Another common propellant charge B powder has the following composition: wt%

Nitrocellulose with 12.6% ^ 56.00 Nitroglycerin 38.80

Stabilizers 5.10

Magnesium oxide + graphite 0.10 100.00

The explosion heat is approx. 4600 Joules / g.

30 A powder for a propelling charge C

according to the invention has the following composition: wt%

Nitrocellulose with 13.0% ^ 59.50

Diglycol dinitrate 24.80 35 Nitroglycerin 14.90

Stabilizers 0.70

Magnesium oxide + graphite 0.10 7? Q 3 1 3 4 100.00 - 6 - y

The explosion heat is again approximately 4600 Joules / g.

The cross compositions A and B contain a significantly higher proportion of stabilizers and plasticizers and stabilizers, respectively, than this is necessary per se. The remaining portion is only for energy digestion, so that the explosion heat is set to the specified value. In the cross composition C according to the invention, on the other hand, the same explosion heat is achieved without separate energy digestion by incorporating two jumping oils in suitable proportions.

To compare the spice properties, the spice compositions B and C were placed in a 105 mm caliber weapon. In addition, it was found that the cross composition C according to the invention is clearly more favorable in the outside temperature pressure behavior than the cross composition B. The cross composition B already showed an increase in pressure at -40 ° C, which can be assessed as critical, which under otherwise equal conditions at 20 the cross compound C did not occur.

The firing properties of the cross compositions A and C were compared with a 120 mm caliber weapon. It was found that with the powder composition C according to the invention, firing speeds were achieved, which were first achieved at 100-200 bar higher pressures with the propellant charge powder A.

Thus, there appears to be a pronounced ballistic superiority of the propellant charge powder according to the invention with multiple blasting oils 30 over the conventional propellant charge powder.

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

In modern weapon systems, instead of the 35 conventional metal cartridge cases, increasingly combustible cartridge cases are used. These include, for example, a high proportion of nitrocellulose, as well as neutral fibers, a resin binder and a 7909134-7 chemical stabilizer for the nitrocellulose. Due to the material composition, they can contact plasticizers and explosives in contact with powder for a propelling charge. However, in order to ensure a long suitability for storage of ammunition with combustible shells, it is important that the propellant powder releases as little explosive as possible to the shell material for a propelling charge.

Surprisingly, a propellant charge according to the invention in this regard showed that it releases significantly less explosive oil to combustible shell material than known propellant charge.

Typically, an examination with the aforementioned powder compositions A and C was conducted in such a way that the propellant powder was pressed between two pieces of combustible sleeve material and stored in tightly sealed bottles at 75 ° C and 80 ° C. In addition, the weight increase of the combustible sleeve material was observed over time.

At a storage temperature of 80 ° C, the following weight increases were determined;

Powder A Powder C Difference 25 after 1 week 9.0% 7.3% 1.7% after 3 weeks 16.7% 12.0% 4.7% after 6 weeks 21.4% 14.5% 6.9 %

At a storage temperature of 65 ° C, the following weight gain was observed after 18-30 days:

Powder A Powder C Difference 8.0% 6.9% 1.1%

The said results clearly demonstrate the superiority of the propellant charge powder according to the invention over a known propellant charge powder in view of the explosive oil transition in the sleeve material.

7909134 * - 8 -

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

The invention is further illustrated by the following four examples.

Example I.

Solvent-free diglycol dinitrate / nitroglycerin-10 powder for a propelling charge.

In a 400 l kneader customary in powder manufacture, were mixed together: 148.8 kg dry weight of a 30% aqueous raw powder mass with the following composition, based on dry weight: 60% nitrocellulose with a nitration degree of 13.0% nitrogen, 25 % diglycol dinitrate, 15% nitroglycerin,

20 1.080 kg Akardite II

0.075 kg magnesium oxide 0.075 kg graphite.

After optimal mixing in the kneader, the mass was processed on a roller kneader at 85 ° C into a well-gelled sheet by the usual method, then rolled up into a press wrapper and pressed into a 7-hole strand in a hydraulic press at 70 ° C. , whose cross-section and body width were set to the ammunition requirements. After cutting the strand to the required length 30, the powder was mixed after a ripening storage.

The finished powder had within the tolerance limits the following composition: 7909134-9% by weight

Nitrocellulose with 13.0%. nitrogen 59.5

Diglycol dinitrate 24.8

Nitroglycerin 14.9 5 Akardite II 0.7

Graphite 0.05

Magnesium Oxide 0.05 100.00

Its heat of explosion was about 4600 Joules / g.

The propellant charge described above was found to be suitable for this propellant charge powder.

Example II.

Solvent-free butanetriol trinitrate / nitrogly-15 cerine powder for a propelling charge.

The charge in the kneader was as follows: 148.8 kg dry weight of a 30% aqueous raw powder mass with the following dry weight composition: 64% nitrocellulose with a nitration rate of 13.0% nitrogen, 22% 1.2, 4-butanetriol trinitrate, 14% nitroglycerin,

0.375 kg Centrallite I 25 0.675 kg Akardite II

0.075 kg magnesium oxide 0.075 kg graphite.

The preparation was similar to that described in Example 1. The finished powder had the following composition within the tolerance limits:%

Nitrocellulose with 13.0% nitrogen 63.50 1,2,4-Butanetriol trinitrate 21.70

Nitroglycerin 14.00 35 Centrallite I 0.25

Akardite II 0.45

Graphite 0.05

Magnesium Oxide 0.05 100.00 7909134 J * -10 -

Its heat of explosion was about 4950 Joules / g.

Example -III.

Solvent-free diglycol dinitrate / nitroglycerin / nitroguanidine powder for a propelling charge. The kneader charge was as follows: 103.8 kg dry weight of a 30% aqueous raw powder mass analogous to Example II with diglycol dinitrate instead of 1,2,4-butanetriol trinitrate

45.0 kg Nitroguanidine 10 0.300 kg Centrallite I.

0.750 kg Akardite II 0.075 kg Magnesium dioxide 0.075 kg Graphite

The preparation corresponded to that described in Example 1. The finished powder had within the tolerance limits the following composition:% by weight

Nitrocellulose with 13.0% nitrogen 44.30

Diglycol dinitrate 15.00 20 Nitroglycerin o 9.90

Nitroguanidine 30.00

Centrallite I 0.20

Akardite II 0.50

Magnesium Oxide 0.05 25 Graphite 0.05 '100.00

Its heat of explosion was approximately 4100 Joules / g.

Example IV.

Solvent-containing butanetriol trinitrate / methriol trinitrate / diglycol dinitrate / nitroguanidine powder for propellant charge.

The following was placed in a 400 l kneader: 172 kg of a 30% alcohol containing nitrocellulose 35 with 12.8% N2 (= 110 kg nitrocellulose, converted to alcohol-free substance)

40 kg nitroguanidine 2 kg Akardite II

7909134 -11 -

Into this premixed mixture, a mixture of the following solvent-phlegmatized spring oils was introduced: 16 kg of 1,2,4-butanetriol trinitrate 5 methriol trinitrate 16 kg of diglycol dinitrate 40 kg of alcohol-ether mixture

After mixing in the kneader, the batch was subjected to a 10-day maturation at about 25 ° C, then kneaded again and then pressed into 1-hole strands in a hydraulic press. After cutting, the powder was dried in a spreading warm air, optionally under vacuum. The finished powder had the following composition within the tolerance limits: 15% by weight

Nitrocellulose with 12.8% nitrogen 55.00 1,2,4-Butanetriol trinitrate 8.00

Methriol trinitrate 8.00

Diglycol dinitrate 8.00 20 Nitroguanidine 20.00

Akardite II 1.00 100.00

Its explosion heat was approximately 3960 Joules / g.

7 # ö 3 1 3 4 Conclusions.

Claims (13)

1. Multi-component propellant powder for firearms and flying projectiles containing nitrocellulose, explosive oil and possibly further nitro compounds as energy carriers 5, characterized in that the powder contains at least two different explosives. 2. A propellant charge powder according to claim 1, characterized in that it contains a mixture of at least two of the explosive oils nitroglycerine, diglycol dinitrate, methyl trinitrate and 1,2,4-butanetriol trinitrate. Propellant charge powder according to claim 2, characterized in that it contains nitroglycerin and diglycol dinitrate. Propellant charge powder according to claim 1, 2 or 3, which is prepared according to a solvent-less procedure (solvent-less procedure), characterized in that the total content of explosives for optimum homogenization and gelatinization in the preparation process is recorded. Propellant charge powder according to claim 4, characterized in that the total explosive oil content, based on the nitrocellulose content, is not more than 100% by weight. Propellant charge powder according to claim 5, characterized in that the total explosive oil content is 54-82% by weight. Propellant charge powder according to claims 3 and 6, characterized in that, based on the nitrocellulose content, it contains about 33-52% by weight of diglycol dinitrate and about 21-30% by weight of nitroglycerin. 7909134 - 13 - 8. Powder for one. propellant charge according to claim 7, characterized in that it contains 41-43 wt.% diglycol dinitrate and 24-26 wt.% nitroglycerin. Propellant charge powder according to claim 1, 2 or 3, which is prepared as two- or three-component powder with a limited amount of solvent as a gelation aid (semi-solvent procedure), characterized in that the total content of explosives is at most 30% by weight. 10. Propellant charge powder according to claim 1, 2 or 3, which is prepared according to a solvent-applying process (solvent procedure), characterized in that the total content of explosive oil in view of the cases to set explosion heat and / or the nitroguanidine or nitramine content to be incorporated has been established. 20 11. Propellant charge powder according to claim 10, characterized in that the total explosive oil content is fixed such that up to 55% by weight of nitroguanidine or nitramine can be incorporated into the nitrocellulose explosive oil gel as hexogen or octogen. Propellant charge powder according to claim 11, characterized in that the total explosive oil content, based on the nitrocellulose content, is at most 150% by weight. Propellant charge powder according to any one of claims 1-12, characterized in that the proportion of the higher caloric explosive oil (s) in the total content of the explosive oil is so dimensioned that a predetermined explosion heat is achieved without energy, digesting bulking agents such as phthalates or centrallite. 7908134. € CH ~ - O - NO, CH - 0 - NO, 1! CH2 - 0 - NO2 CH, - 0 - NO, I 2 2 CH, 0 2 2 X CH, CH2 - 0 - NO2 CH, - 0 - NO, r CH, I 2 '3 CH - 0 - NO, - CH2 - 0 - N02 ch2 - 0 - N02 CH3 - C - CH2 - 0 - N02 4 CH2 - 0 - N02 7909134 WNC Nitrochemie GmbH Aschau