NO132559B - - Google Patents

Description

The invention relates to containers for propellant charges, respectively cartridges, ammunition casings or the like of nitrated cellulose, as well as a method for producing such containers.

The task underlying the invention is to produce containers for fuel charges. which containers consist of combustible materials such as nitrated cellulose. As containers for fuel charges and explosive substances, cartridges, pipe sleeves for rockets and housings for mines of different types come into consideration, which in their form can be diverse, while for cartridges it depends on the adaptation to the type of weapon, the diameter of the barrel, etc.

In addition to fuel housings made of metals or cartridges for conventional weapons, in which the projectile is rolled, fuel containers that burn more or less completely with the ignition of the propellant charge are also known. At the same time, an attempt is made to achieve that the mechanical firmness and resistance to water vapor and sea water correspond to the requirements set. The very different shapes and dimensions of the fuel containers that come into consideration necessitate here an undesirably large inventory.

A further requirement for fuel containers of this type is that the damaging effects on the weapon must be kept as low as possible, a goal that is easily achieved with metal cartridges. However, in the case of containers for fuel charges, where the container consists of combustible materials, it is undesirable for combustion residues to prevent a disturbance-free use of the weapon.

It is known to use nitrated cellulose as a combustible material for such ammunition casings which largely correspond to the desired requirements. In addition to powder form bodies made of nitrocellulose, nitrated cardboard has also already been used for the production of ammunition casings. In this way, the production of pure nitrated cellulose is bound to specific, often difficult to maintain conditions due to the dangerous handling. With regard to this, ammunition casings have also been developed which only contain a proportion of nitrated cellulose derivatives. In the case of cellulose derivatives which are first produced as molded pieces and then nitrated, the desired course of combustion due to the explosion flame is difficult to control for the reason that the nitration process is difficult to control. In addition, a large supply of manufacturing forms is a prerequisite for the adaptation of the ammunition casings to the various purposes of use.

The purpose of the invention is to provide a container for propellant charges which is better than the previously known ones, as well as a method for the manufacture of such containers, which method in relation to the known technique simplifies the manufacture of containers for fuel charges from completely combustible materials and which improves the technical application assumptions.

This is achieved by a container and a method which is characterized by what appears in the requirements.

The invention consists in man'nitrating layers of fixed - made fiber fleece in a known way, that the nitrated fleece layers are united by being placed on top of each other and dried, after which cutouts are made from this web in the form of the unfolding form for the containers for the fuel charges respectively the ammunition sleeves and that the cutouts after solution respectively softening with the help of rollers or other shaping is formed into ammunition casings. The nitrated fluorine layers are drawn in a number corresponding to the predetermined strength of the ammunition casing through a bath of dissolved nitrocellulose, superimposed and glued together.

Advantageously, the nitrated fluorine layers have a different nitrogen content. Thus, e.g. the inner layer has a nitrogen content of 11.9% and the layers located in the area of the outer circumference of the cartridge have a nitrogen content of 6%. Thereby the advantage is achieved that the outer layers burn more heavily and thereby that the walls of the gunpowder chamber are not heated too strongly. A complete combustion of the total material without residue

occurs in any case. Por that by cardus or cartridge

the form is ensured that the outer and inner layers are arranged according to regulations, the layers can be designed with a different colour.

To ensure a disturbance-free nitration and

binding of the loose fluorine webs, it is advantageous before nitre-

the ring to equip them with a wire reinforcement or combi-

cover them with an extremely light cotton fabric, whereby fiber

the web and the web may be connected to each other by needling. Both tracks can thus be jointly de-glued and degreased.

tes, which, however, can also be carried out in a separate state before the joining.. The path combined in this way remains on

the mentioned way led through the nitration bath.

In principle, only light cotton can also be used

woven fabric or cotton wood, if this satisfies the requirements for a high porosity. The surface of the threads may be rough.

From the plate-shaped bodies thus formed, there will be

punched section respectively they are shaped in a different way that corresponds to the dimensions of the later ammunition casings. The actual fuel container is then produced by a common processing method, e.g. by round rolling. In this way, overlapping seams are designed without transitions, e.g. in the case of bevelled edges.

A further characteristic of the method according to the invention by. its application for the production of cartridges or cartridges consists in the fact that longitudinal grooves or reinforcement ribs are formed in the cartridge cuts when

sing or pressing.

The finished ammunition cases are equipped for storage

with a barrier layer of swellable, natural or synthetic polymer or its derivatives' in film thickness, and these are coated with a moisture-insensitive hydrophobic protective layer, where-

the containers manufactured according to the invention are water vapor resistant and sea water resistant.

When carrying out the method according to the invention

the nitration of the fluorine layers is carried out in a known manner.

It can also be used for the design of the individual cuts

known methods and devices are used.

An arrangement for carrying out the nitration and joining of the fluorine layers is illustrated in the drawing's fig. 1. On this, the procedure is carried out in the following way: Fluorescent layer of natural or artificial cellulose with a staple length of approx. 30 mm is nitrated if necessary after an enrichment with oxygen. The nitriding and treatment time are adjusted so that a nitrogen content in the fibers usually between 10.5 and 11.5 appears. This fiber pile is then stabilized, e.g. when washing or boiling in order to avoid any self-ignition.

The fleece material treated in this way is on the device according to fig. 1 led through a container 10. Above the container 10, the nitrated fluorine layers are arranged in the form of rolls 11 in such a way that, depending on the number of fluorine layers to be joined, these are led from the roll 11 over guide rollers 12 through a bath of dissolved nitrocellulose as an adhesive. The predetermined number of nitrided webs each time is passed between extrusion rollers 13 and led into a drying device 14. In the drying device 14, the solvent for the used adhesive is driven out so that a fluorine web of continuous nitrided webs of predetermined thickness is produced. structure is now cut to specific dimensions if it is intended for storage. If, for ammunition cases of greater thickness, a greater number of layers are bonded together, these may be subjected to a compressive pressure, whereby, however, the porous structure of the nitrided layer web must be maintained .

The plate-like structure removed from the drying device 14 can be removed in a known manner, e.g. by punching out form-to-cuts, be further processed into ammunition trays, rocket sleeves or the like.

An embodiment of a cartridge or cartridge is shown in fig. 2. This consists of the nitrided fluorine layer 20 which is laminated according to fig. 1, and on the outer circumference of which ribs 21 are formed. The shaped body designed as an annular sleeve is glued together by a chamfered connecting seam 22, so that a pressure-resistant body is provided. The overlap location at 22 can be secured by means of a nitrocellulose adhesive which dries to a hard state.

When carrying out the method according to the invention, containers for fuel charges can be produced with

arbitrary shape and thickness. Of those from the drying facility 14

removed sheets of predetermined thickness are produced

unfolding forms for the individual ammunition casings, respectively these are shaped as punched bodies from the plates. The hard plate-like structures are softened and this is done expediently in a container through which softening agent mixtures or solvent mixtures adjusted to the fixing agent are passed. These solvents enable a softening in a short time, after which the cuts that are in a soft plastic state can be brought to the final shape for the ammunition container or the mine cup by means of form rollers, embossing or pressing.

When manufacturing ammunition containers according to fig. 2, the rib 21 is thereby formed, which can also be formed on the inner surface.

The method according to the invention offers the advantage that complete combustibility is ensured by the fluorine layers being nitrated. In this way, the mechanical strength of the final product can be determined by means of the staple length of the fibers that are processed into flour. The nitriding of the individual fiber piles makes it possible to produce a material equipped with pores, which promotes the burning rate, while the firmness is not affected. Stocking can be done in a very space-saving way with the plate form and the production of individual or pre-assembled plates in adaptation to the forms and the application regulations for the ammunition casings are simplified.

Due to the reinforcement ribs on the outer surface of the ammunition casings, due to the fact that the explosion flame can also reach the back of the ammunition casing at the same time, it is achieved that

the combustion process is accelerated. At the same time, these ribs, which can also be designed on the inside, form a reinforcement of the ammunition housing. As fiber felt which can be processed in any number of layers, those which, due to their chemical or natural composition, burn without residue are particularly suitable, preferably also those which, in the design of the felt, can be produced without additional bonding agents.

Claims (1)

1. Containers for propellant charges, respectively cartridges, ammunition casings or the like made of nitrated cellulose, t characterized by the fact that the walls consist of superimposed layers of different strongly nitrated cellulose flor materials f, whereby the outer layers are more weakly nitrated than the inner layers, and whereby the layers are united to each other while maintaining porosity by means of a nitrocellulose matrix and possibly equipped with a surface barrier layer, respectively a cover layer. 2. Container according to claim 1, characterized in that projections are formed on the outer circumferential wall of the container. 3" - Container according to claim 2, characterized in that the projections consist of less compressed material than the other wall parts. 4. Container according to claim 2, characterized in that the projections are embossments in the container wall. 5- Container according to claim 4, characterized in that in the case of a multi-layered container wall, the projections are embossments in individual layers. 6. Container according to claim 2, characterized in that the material in the protrusions is treated so that it burns more difficult than the container wall. 7- Method for the production of containers for propellants and charges, respectively ammunition casings of nitrated cellulose, according to one or more of the preceding requirements, whereby layers of nitrated fibrous material are laid over each other and glued to each other, characterized in that different strongly nitrated iberstof f layers are drawn through a bath of dissolved nitrocellulose in such an arrangement that the weaker nitrated layers will come to lie at the outer circumference of the container for the fuel charge, respectively the ammunition sleeve, as the fiber fabric layers are laid over each other and glued together in a therein predetermined firmness for the container, respectively the corresponding number of ammunition casings, and that the container, respectively the ammunition casing, before, during or after drying the thus treated fiber material layers is formed by rolling, winding or other shaping. 8. Method according to claim 7, character, characterized in that a flor material is used as fiber material. 9. Method according to claim 75, characterized in that cut-outs are produced in the shape of the unfolding form for containers, from the overlapping, glued webs, and, possibly after drying and a new softening, that these are shaped into containers by rolling or other forming processes and then is dried. 10. Method according to claim 9S, characterized in that the containers are produced from optionally re-softened cuttings by round rolling while simultaneously closing an obliquely cut overlapping seam. 11. Method according to claim 9, characterized in that protrusions, longitudinal grooves or reinforcement ribs are formed on the circumference of the softened cardstock cutting by rolling or pressing. 12. Method according to claim 7, characterized in that the surfaces of the ammunition casings formed of nitrated fluorine are equipped with a residue-free combustible barrier layer or cover layer as a protective layer against moisture, water vapor or the like. 13. Method according to claim 7, characterized by the fact that a lightweight fabric, a work or the like, with the properties of a flor material is used. 14. Method according to claim 13, characterized in that the fabric is roughened on one or both sides to provide a fiber-like surface. 15. Method according to/claim 7, characterized in that a fiber pile and a weave are connected to each other before nitriding by means of needling.v 16. Method according to claim 7, characterized in that, before the nitriding, loose fibers are loop-connected with a woven base. 17. Method according to claim 7S, characterized in that the fabric is equipped with a fiber layer on both sides before the nitriding. 18. Method according to claim 13, characterized in that the fabric and/or the fabric, work or the like consists of cotton which, possibly before the nitriding, is degreased and/or finished.