DE10013686A1 - Telescopic shell for intermediate caliber weapons has combustible casing made by winding thread impregnated with binder on to propelling charge - Google Patents

Abstract

The telescopic shell has a combustible casing (10) made by winding thread (13) impregnated with a binder on to the propelling charge (9). The casing may be made up of several double layers (11a, 11b, 12a, 12b) wound so that they cross at a fixed angle.

Description

The invention relates to a telescopic cartridge with a combustible or consumable Sleeve according to the preamble of the first claim.

Especially with medium-caliber ammunition, such as those made from Machine guns are fired, the conventional sleeves are made of metal heavy and expensive both in production and as a material because it is rustproof must be and therefore usually consists of brass or clad steel. In addition, such a sleeve must be removed from the weapon after each shot. This is the case with long-range weapons or high-pressure weapons Weapons disadvantageous. These occur in the case of combustible or edible pods Disadvantages not on. The sleeve can also have such a composition have additional energy when they are burned or consumed supplies. For performance reasons, therefore, the concept of the telescopic cartridge picked up, in which the projectile is embedded in a solid propellant body.

From DE 195 44 560 A1 a telescopic cartridge is known, the sleeve of which Winding sleeve is. The cartridge is made by inserting its individual components like that Projectile with a propellant shaped as a projectile holder, the main propellant, and the lighter built into the sleeve. That requires a very precise one Manufacture of the components in terms of their diameter, on the one hand easy assembly is possible and on the other hand an intimate contact between the sleeve and the components, especially the loads, is guaranteed. This contact must be guaranteed and if necessary by Gluing can be ensured so that, on the one hand, high handling of the Cartridge, especially with the automatic feed in the weapon, throughout Guaranteed strength ensures the temperature range of the intended use and secondly, the combustion or consumption of the sleeve without residues is possible.  

It is the object of the present invention to use a telescopic cartridge to improve a combustible or consumable sleeve.

This problem is solved with the aid of the characteristic features of first claim. Advantageous embodiments of the invention are in the dependent claims.

According to the invention, the manufacture and handling of the telescopic cartridge improved in that the sleeve is a winding body that directly on the tubular propellant body is wound, the at least the projectile and the Booster charge surrounds. The propellant charge is the winding tube of the winding body. This creates an intimate, easier lighting of the sleeve and accelerating contact between the sleeve and propellant body, which does not like conventional, must first be produced by gluing. It also adds stability the telescopic cartridge significantly increased, which for the automatic feed in the Weapon is important. The propellant charge body itself consists of a raw one malleable mass of blowing agent and binding agent, and after it has hardened however not enough stability to make the telescopic cartridge manageable. The invention now consists in that after tempering the propellant body at a temperature below the temperature required to stabilize the Binder in the propellant body is required to the propellant body direct winding of the sleeve of the telescopic cartridge is used. After his Tempering has the propellant body enough strength so that it comparable to the manufacture of a spool in the textile industry, in a Winding device can be clamped so that the winding body on it can be wrapped. To stabilize the structure of the winding body, the sleeve, a binder is added during winding.

In an advantageous embodiment of the invention, the winding body can consist of one or several double layers of intersecting threads fixed with binder, which are wound directly on the propellant body. The threads are at least in  a double layer, that is, by a back and forth movement of the thread guide in one so-called cross position. In addition to threads are from the prior art still paper strips or textile cloth webs known as wrapping material.

The winding density of the winding body is decisive for the resistance, Strength and porosity of the winding body. The porosity is determined by the Size of the spaces between the winding material, preferably the threads. The The winding density is determined by how many times the thread in a layer over the Length of the winding body is deposited. The winding density is essentially determined by affects the crossing angle. The crossing angle is at a crossing Filing the threads on the circumference of the winding body the angle between two in each case in the deposition direction threads to run in a so-called Double layer. A double layer consists of a layer of threads running towards one end of the winding body has been deposited and the one above it Location of threads in the opposite direction, towards the other End of the winding body have been deposited. Because the threads on the circumference of the winding body helically in the direction of the longitudinal axis of the Telescopic cartridge are stored, determines the incline of the storage Crossing angle. With a slight slope, the crossing angle is also small, also big on a steep slope. As the slope increases the distance between the threads is greater. This also means that Gaps between the threads are larger. At high loads and less Wall thickness, a small crossing angle will be advantageous because of the number the turns of the deposited thread per unit length on the Propellant body is increased. By an appropriate choice of Crossing angle can thus advantageously the sleeve to the expected load be coordinated. Another influencing factor is the thread tension. A high Thread tension puts the threads under tension, presses the threads together and this makes the winding body hard.  

The strength and resilience of a winding body and its burning behavior are also influenced by the winding technology. For example, a Thread alone or several, parallel to each other with a smaller distance Threads are wound into a winding body as a sleeve.

A winding body can be produced without additional effort and therefore inexpensively wrap, the winding density is constant over the length of the winding body.

However, the winding density of the winding body can also be chosen accordingly of the crossing angle over the length of the sleeve may be different and thereby advantageous to different loads in the respective areas of the sleeve be coordinated.

The transition area between the booster charge and the floor is due to the different weights of the two parts in terms of stability and strength of the projectile critical. It can therefore be particularly advantageous there if the winding density of the sleeve is greater than in the neighboring areas. But also at the ends of the sleeve can increase the stability to increase the stability Winding density may be advantageous.

Not only on the resilience of the sleeve but also on its erosion or Consumption behavior can be influenced by the choice of the angle of incidence become. So can be in a winding body consisting of several double layers exists, the crossing angle and thus the sizes of the spaces distinguish between the threads in the respective double layers. The Spaces can be used to support the burn with air or to increase the propellant be filled with explosive. To burn or consume to accelerate the sleeve and thus support it, it is advantageous to the Binder with which the threads are soaked or covered, an explosive to mix. Also the gaps between the threads and the thread layers can be at least partially filled with an explosive.  

In order to particularly support the effect of the propellant charges during combustion, it can be advantageous if the construction of the wall of the sleeve takes place in the radial direction, that by specifying small crossing angles, the outermost layers of a can withstand higher pressure loads than the inner layers. This will the radial deformation of the sleeve when the propellant charges burn up a higher Opposing resistance, so that the effect of the propellant charge in axial Direction to the floor is supported.

A particularly intimate contact between the propellant charge body and the sleeve advantageously achieved in that in the manufacture of the winding body directly on the Propellant body is added a binder that the binder that the Explosive of the propellant charge is admixed, chemically related. The Binders should belong to related polymer systems. The binder of the Propellant charge can be a polyaddition polymer, for example, while the Binder of the winding body is polystyrene.

The sleeve is wrapped on the propellant body before the binder is in it has hardened. Only after winding the sleeve is the common The binders of the propellant charge body and the sleeve are hardened by tempering at the temperature level required for curing. This is for example for the named binders at about 110 ° C. By annealing together Because of the chemically related polymer systems, there is advantageously one intimate connection between the propellant body and the sleeve by a subsequent gluing of the two components would not be achieved. This is in particular the mechanical stability as a whole, for use provided temperature range guaranteed.

The winding of the sleeve according to the invention directly onto the propellant charge also has the advantage that only a single machining of the sleeve to the caliber dimension must be made. Would the sleeve, as from the prior art known, wound separately, the propellant charge body would first have to  its outer contour are machined so that it fits into the sleeve. In addition would have to then the sleeve is turned on its outer circumference to the caliber dimension. Thus, at least two separate processing steps for producing the Ammunition of the required caliber is required.

The invention is explained in more detail using an exemplary embodiment.

In the present exemplary embodiment, a telescopic cartridge according to the invention is designated by 1. The representation is schematic and is intended to explain the invention. For the sake of clarity, therefore, details have not been drawn to scale. The cartridge is shown half in section and the top double layer of the crossing threads is omitted from the winding body to demonstrate the cross position underneath in the direction of the axis of symmetry 16 .

The telescopic cartridge 1 consists of the floor 2 , the booster charge 3 , the inductive igniter 4 , the ignition transmitter 5 of which is embedded in the initial igniter 6 and is connected to an induction coil 8 via a connecting line 7 . Storey 2 , booster charge 3 and inductive igniter 4 are surrounded concentrically by the tubular propellant charge body 9 as the main propellant charge. The propellant charge body 9 consists of a mixture of known propellants, for example RDX and nitroguanidine, and a binder which burns without residue, for example polybutadiene. The sleeve 10 is wound on the propellant charge body 9 .

In order to give the propellant charge body 9 the strength required for winding the sleeve 10 , it is first annealed at about 90 ° C. The sleeve 10 can then be wound in at least one double layer of crossing threads in a winding device. For this purpose, threads and binders can be used, as are known from DE 38 25 581 C1.

As can be seen from the figure of the exemplary embodiment, the sleeve 10 in the present exemplary embodiment consists of a winding body of two double layers or cross layers 11 or 12 of threads 13 . The first double sheet 11 which has been wound directly onto the propellant charge body 9 has a uniform structure as the constant crossing angle α close to 90 ° between the wound to the right position 11a of the threads 13 and the wound to the left position 11b of the threads proves.

The outer double layer 12 of the threads 13 , however, has a different structure. It is wound more tightly, as can already be seen from the smaller crossing angles, and is therefore more stable. It also has five areas 14 a to 14 e, which are alternately wound with different densities. In the end areas 14 a and 14 e of the sleeve 10 and in the area 14 c, where the projectile 2 and the booster charge 3 meet, the winding density is greatest because the mechanical load of the sleeve wall to be expected is also highest there. In these regions 14 a, 14 c and 14 e, the crossing angle β of 30 ° between the threads 13 of the layer 12 a wound to the right and the layer 12 b wound to the left is smallest.

In the areas 14 b and 14 d, the crossing angle γ at 60 ° is twice as large as the crossing angle β, but is approximately one third smaller than the crossing angle α in the double layer 11 .

The distribution of the threads 13 in the individual layers is clearly visible in the sectional view. The higher the number of threads 13, the higher the stability of the sleeve 10 .

As is known from DE 38 25 581 C1, the threads, as not shown here, are soaked or surrounded with binding agents. Explosive material can be added to the binder to support the burning of the threads. In addition, spaces 15 are formed between the individual threads and thread layers, which act like pores. They can also be filled with bound explosives.

After the top thread layer 12 b has been deposited, the winding body, the sleeve 10 , is finally dried at approximately 110 ° C. The connection of the chemically related binders results in an intimate connection between the sleeve 10 and the propellant charge body 9 . Even at high loads in the temperature range between approximately -45 ° C. and + 65 ° C., the sleeve 10 does not detach from the propellant charge body 9 . After the final thermal treatment, the telescopic cartridge 1 is so stable that the surface of the sleeve 10 can withstand mechanical treatment, for example by twisting it off, so that the cartridge receives the required caliber.

Claims (12)

1. Telescopic cartridge with a combustible or consumable sleeve which concentrically surrounds a tubular propellant charge body, which in turn encloses at least the projectile and the booster charge, characterized in that the sleeve ( 10 ) is a winding body which is wound directly onto the tubular propellant charge body ( 9 ) is. 2. Telescopic cartridge according to claim 1, characterized in that the structure of the sleeve ( 10 ) is fixed by a binder added during winding. 3. Telescopic cartridge according to claim 2, characterized in that the binder with which the structure of the sleeve ( 10 ) is fixed is chemically related to the binder of the propellant charge body ( 9 ). 4. Telescopic cartridge according to one of claims 2 or 3, characterized in that the binder of the propellant charge body ( 9 ) is not yet cured when the sleeve ( 10 ) is wound on the propellant charge body ( 9 ). 5. Telescopic cartridge according to one of claims 2 to 4, characterized in that the sleeve ( 10 ) after the final curing of the binder of the propellant charge body ( 9 ) and the sleeve ( 10 ) is machinable to produce the required caliber. 6. Telescopic cartridge according to one of claims 1 to 5, characterized in that the sleeve ( 10 ) consists of one or more double layers ( 11 , 12 ) crossing, with binder fixed threads ( 13 ) and that the threads ( 13 ) for manufacture the sleeve ( 10 ) are wound directly onto the propellant charge body ( 9 ). 7. Telescopic cartridge according to claim 6, characterized in that the winding density of the sleeve ( 10 ) by the size of the crossing angle (α, β, γ) of the threads ( 13 ) in the respective double layers ( 11 , 12 ) is determined. 8. Telescopic cartridge according to claim 7, characterized in that the winding density of the sleeve ( 10 ) due to the constant crossing angle (α) of the threads ( 13 ) over the length of the sleeve ( 10 ) is constant. 9. Telescopic cartridge according to claim 7, characterized in that the winding density of the sleeve ( 10 ) in coordination with the load in the respective winding areas ( 14 a to 14 e) of the sleeve ( 10 ) over the length of the sleeve ( 10 ) is different. 10. Telescopic cartridge according to claim 9, characterized in that the winding density of the sleeve ( 10 ), in particular in the area where the projectile ( 2 ) and the booster charge ( 3 ) abut, is greater than in its other areas ( 14 b, 14 d) . 11. Telescopic cartridge according to claim 9 or 10, characterized in that the winding density of the sleeve ( 10 ) is greater, in particular in its end regions ( 14 a, 14 e) than in its other regions ( 14 b, 14 d). 12. Telescopic cartridge according to one of claims 6 to 11, characterized in that the sleeve consists of several double layers ( 11 , 12 ) of threads ( 13 ) and that their crossing angle (α; β, γ) in the respective double layers ( 11 , 12 ) differ from each other.