DE2137031A1 - Caseless ammunition round - Google Patents

Abstract

Caseless ammunition round for rapid fire guns, consists of a projectile housed in a bore of a propellent charge. The projectile is retained by a combustible ring near the rear end, which is snapped into a groove in the projectile and locates on a shoulder formed in the charge. The shoulder may be formed by a counterbore in the rear end of the charge which is closed, after assembly of the projectile, by a propellent plug carrying a primer and booster charge. Instead, the shoulder may be formed by a combustible sleeve inserted from the forward end and fixed by adhesive. The ring is of pressboard, or Kraft paper contg. up to 20% PETN. The round will withstand loading forces when feeding from a magazine into the gun chamber in a rapid fire sequence.

Description

Arrangement for holding the projectile in place with caseless ammunition The invention relates to an arrangement for holding a projectile at sleeve laser flunition. In particular, the invention relates to an arrangement for holding fast of a projectile in a case-soled cartridge, in which the projectile is at least partially is housed in an axial cavity that extends over the entire length of the @reibladen a sleeveless @atrone extends. The arrangement according to the invention ensures that the bullet fcsb will be kept in its position when the caseless pa @ rone is subjected to great deceleration forces, as happens with snowguns.

There are already cartridge soles for semi-automatic or fully automatic Small arms have been developed in which the projectile is at least partially and in in many cases even completely enclosed in an axial cavity which extends over the entire length of the propellant charge. Caseless cartridges, in which the Gescho @ is completely housed in the propellant charge, z. As described in U.S. Patent 7,482,516.

nS has been shown to be difficult with a caseless cartridge this way to hold the projectile in the propellant charge. The holding means for holding on of the bullet must have sufficient strength to withstand the forces withstand to which such a cartridge is exposed during normal use will. A more important point, however, is that the holding means are designed in this way must be that they hold the projectile reliably in its position when the caseless Cartridge is subjected to a large retarding force, as happens when a such a cartridge when discharging rapid fire from a magazine into the chamber of the Firearm is retracted. When the bullet holding means are loaded by them Delay is usually the greatest load on the support structure must withstand. Furthermore, the holding arrangement must be designed so that it does Projectile under the influence of an ignition charge to ignite the propellant charge or under almost instantly releases the influence of a combined ignition and auxiliary charge. Holding the bullet too strong leads to a reduction in the ballistic Caseless ammunition performance.

The adverse effects of holding the bullet too tight are most evident in caseless cartridges with nested parts noticeable, since if the projectile ages too much, it is possible that Too large an amount of propellant gas is lost in front of the projectile before the projectile placed in the barrel of the weapon by means of which the projectile is to be fired.

The invention now proposes for caseless cartridges, at where the projectile is at least partially housed in an axial cavity, the sicl; extending over the whole amount of the propellant charge, an arrangement for retention of the projectile, which is a projectile with an annular groove formed on its circumference includes, as well as one arranged in this annular groove, consuming snap ring, which determines a first contact surface, r.it, which is through that part of the snap ring is formed, which protrudes from the annular groove and opposite the peripheral surface of the projectile protrudes, as well as a second contact surface inside the propellant charge the caseless cartridge. This second contact surface arranged within the propellant charge limits the forward movement of the bullet provided with the snap ring when ct; the projectile is introduced into the propellant charge along the axial cavity, with the first contact surface of the snap ring in contact with the second contact surface is brought within the propellant charge.

Although there is no theory about the mode of action of the invention Arrangement, but it should be noted that when firing a caseless cartridge with an arrangement according to the invention for holding the projectile Snap ring apparently deformed by the propulsive force caused by the ignition charge for the propellant charge is generated, and that the high one produced by the ignition charge Pressure in connection with the fact that the charge has a connecting effect on the snap ring causes the projectile to be released almost instantaneously.

The object of the invention and advantageous further details the same are detailed below with reference to particularly preferred exemplary embodiments explained, which are shown schematically in the drawing.

Fig. 1 shows in longitudinal section an embodiment of an inventive Arrangement for holding the projectile a caseless cartridge, in which the projectile is enclosed by the propellant charge.

Fig. 2 illustrates in a partial section the interaction of the Contact surface of the spring ring which is also verb @ and that of the propellant charge Fig. 1 designed ixnlageflache.

Fig. 3 shows in an enlarged perspective partial representation the position of the sicil-consuming snap ring in the ring groove of the bullet Fig. 1.

Fig. 4 shows in longitudinal section a further embodiment of an inventive Arrangement for holding a projectile.

FIG. 5 is a section taken along line 5-5 in FIG. 4.

In Fig. 1, a complete sleeveless can be seen in a longitudinal section Cartridge. In this cartridge, a projectile 10 assumes its starting position in which it is completely absorbed by an axial cavity 12 of the propellant charge 14. Such a caseless cartridge is referred to as "telescopic type cartridge". The axial hollow @ aum 12 of the propellant charge 14 comprises a section with a smaller one Diameter 16 and a portion with a larger diameter 18; the smaller one Diameter 16 determines the size of the axial cavity in the front part 20 cier Propellant charge 14, while the larger diameter 18 is the size of the axial cavity determined in the rear part 22 of the propellant charge. The propellant charge 14 shows where the section of the cavity with the smaller diameter 16 into the section with the larger diameter 18 merges, a shoulder or contact surface 24 on. Of the The area of this shoulder on the propellant is equal to the difference between the areas of two circles, of to which one is the greater and the other has the smaller diameter. @ inside a guide tape 28 that is Projectile 10 provide on its circumference with an annular groove 26, and in this annular groove an elastic snap ring, which is also tightened, grips 30 flour.

According to FIG. 2, the snap ring 30 has an outer diameter 32 which is larger than the outer diameter 34 of the projectile 10. The snap ring 30 is slotted so that it can be easily installed in the annular groove 26. The one from the Annular groove Les Gescho @ ses protruding part of the oprengring 30 determines a contact surface 36.

When assembling the caseless cartridge according to Fig.

1, the projectile 10 is in the axial unfinished space 12 through the rear End 22 of the propellant charge 14 inserted through and advanced into the space, until the contact surface 36 of the spring ring 30 is in contact with the contact surface 24 the propellant charge 14 comes. Then one is made of the material of the propellant charge Plug 38 inserted into cavity 12 in rear end 22 of propellant charge 14, in order to prevent cattle that the projectile moves backwards in relation to the propellant charge. In the plug 38 are an ignition charge 39 and an auxiliary or booster charge 39 'built in.

Fig. 3 shows the built into the annular groove 26 of the projectile 10, using snap ring 30. The one protruding from the ring groove, opposite the peripheral surface of the projectile projecting part of the snap ring determines a first contact surface 6, which holds the projectile in its position after the projectile in the propellant charge of the caseless cartridge has been installed.

Big. 4 shows another embodiment of one according to the invention Arrangement for holding a projectile in a caseless ratrone, in which the propellant charge 40 has an axailen @ ohl @ aum extending over its entire length 41 has. The projectile 42 is on its peripheral surface with a Send ring groove 44 In the ring groove 44 is an elastic, consuming one Snap ring 46 installed, the outer diameter of which is larger than the outer diameter of the projectile. The part of the Snap ring 46 defines a first contact surface 48 of the projectile and the snap ring comprehensive assembly. In the axial cavity 41 of the propellant charge 40 is a consuming cylindrical sleeve 56 is arranged, which consists of a iteibmittel in rorm a flat material is made. The outer surface 52 of the consumable Sleeve 50 is adjacent to the inner surface of treble charge 40 passing through the cavity 41 the propellant charge is formed. The sleeve 50 is in the cavity 41 on any Way, e.g. 2. with the help of an adhesive.

The sleeve 50 has such a wall thickness that it is inside the propellant charge 40 forms a contact surface 54, which the forward movement of the with the snap ring 46 sunk projectile 42 along the axial hohl..au.s 41 of the propellant charge 40 thereby limited that the first contact surface 48 of the snap ring will eventually come into contact with the contact surface 54 of the, sometimes also referred to as the second contact surface Sleeve 50 is coming. The location of the second formed by the inner end of the sleeve 50 Contact surface 54 within the propellant charge 40 and the arrangement of the annular groove 44 and of the snap ring 46 against the projectile 42 determine whether the projectile over the front Front surface 56 of the propellant charge protrudes, The position of the projectile that the projectile occupies in the propellant charge after moving it forwards along the axial cavity the propellant charge has been interrupted by the snap ring, is described below referred to as the "loading position" of the projectile.

Fig. 5 is a longitudinal cross-sectional view of the caseless cartridge of Fig. 4 the line 5-5 in Fig. 4 and leaves the cylindrical shape of the consumable sleeve 50 recognize.

In the following, certain exemplary embodiments are written to further illustrate the inventive arrangement for holding projectiles. The lialtmittel are tested by having completely assembled sleeveless Cartridges from a height of 2.45 m to a thickness of about 12.5 mm Pad made of polyurethane can fall down, which has a Shore A hardness of 60. This dropping of the cartridges from a height of 2.45 n on the surface Polyurethane mimics the retarding force applied to a caseless cartridge is transferred to the chamber of the firearm while releasing rapid fire will. In the examples described below, the propellant charges are made of grains a @ smokeless powder, and all propellant charges are alike with respect to the composition of the weight and the shape.

Examples 1 to 10 are elastic, consumable snap rings made of pressboard (U.S.A. Federal Specification UU-P-701 J) with an inner diameter of about 23.4 mm, an outside diameter of about 27.8 mm and a thickness of about 0.585 mm. These snap rings are slit to make them easier can be built into the grooves of the floors. Ten storeys are made with ring grooves provided, which have a depth of about 0.81 mm, and their width about 0.635 mm or about 1.27 mm or about 1.90 mm or

is about 2.45 mm. These snap rings are in the ring grooves of the Built-in storeys. Every bullet fitted with such a snap ring is in the rear end of the cavity of a propellant charge inserted forward in seal, until the contact surface of the snap ring is in contact with the contact surface of the propellant charge stands, as it was described with reference to FIG. The axial cavity nat with each Propellant charge at the rear end has a larger diameter about 27.8 mm and at the front end a smaller diameter of about 26.3 mm. In the The rear end of the cavity of the propellant charge is made from the propellant Plug installed to prevent the bullet from moving backwards, and simultaneously supports an ignition charge and a booster charge. The so produced Caseless cartridges are tested using the drop test to determine their effectiveness to be able to judge the holding arrangement. Information about the different cartridge designs and the results obtained in the drop test are summarized in Table 1 below.

Table I. Example floor Floor: @ Snap ring (e) Result of the ..

outside through- width @@ e @@ e @@@@@@ @@@@@@@@@@@@@ knives of the groove 2.45 m mm mm mm 1 25 0.635 0.585 1 failure 2 25 0.635 0.585 1 failure 3 25 1.27 0.585 2 failure 4 25 1.27 0.585 2 failure 5 25 1.27 0.585 2 failure 6 25 1.90 0.585 3 storey held 7 25 1.90 0.585 3 storey held 8 25 1.90 0.585 3 Floor held 9 25 2.45 0.585 4 Floor held 10 25 2.45 0.585 4 floor held As can be seen from Table I, the projectile with 3 or 4 snap rings, which are in annular grooves with a depth of about 1.90 mm or about 2.45 mm are installed, perfectly in its loading position in the propellant charge held when the cartridges are dropped from a height of about 2.45 m.

Examples 11 to 5 additional cartridges are made which are provided with three snap rings, the dimensions of the ring groove of the projectiles and the dimensions of the snap rings are as indicated in Table I relating to the example 6 correspond. These cartridges are the drop test at a drop height of about 2.45 m subjected. All projectiles are held in their position in the propellant charge. These cartridges are then fired, revealing that the ballistic Results are flawless. After firing the cartridges are in the chamber of the weapon and no residue on the ground, from which it can be seen that the explosives are essentially completely used up.

The circlips that are used up after the discovery can come off can be produced for any material that is bonded under the conditions that rule in the chamber of a firearm when the caseless ammunition has failed and which is sufficiently elastic to withstand the stresses during installation in the To hold the bullet ring grooves without breaking. The expression "consuming itself means here that there are practically none in the chamber of a firearm after firing Residues of the snap ring can be found. The snap ring according to the invention is preferred Manufactured as a slotted ring so that it fits more easily into the ring groove of the bullet can be installed. You the materials, those used to manufacture the Suitable snap rings include pressboard, lraft paper, ds O to 70% pentaerythritol tetranitrate contains, blowing agents in sheet material form and the like.

In the embodiments described above, include consuming holding means, which form the second contact surface, the one Prevents forward movement of the projectile, a formed inside the propellant charge Ring shoulder. Such a contact surface can be with a propellant charge Axial cavity extending over its entire length can easily be created by that the rear part of the axial cavity is machined so that this Part is given the desired length and inner diameter. As mentioned, can the consuming holding means, which form the second contact surface, also be formed by a consuming sleeve that is firmly in the axial The cavity of the propellant charge is installed. This sleeve can be used as a cylinder Propellants may be in sheet form, or a set of Provide strips of a propellant in flat material form such that these strips form the second contact surface; the sleeve or the strips must have a sufficient Have firmness so that they hold the projectile; hold on reliably when the sleeveless Cartridge is exposed to the retardation forces that cause rapid fire caused by the feeding device. You could also use other materials use which are consumed in the chamber of a firearm and are suitable, that projectile to hold against acceleration and deceleration forces in its position.

With the contact surface of the snap ring, the width of the snap ring, the depth of the ring groove on the circumference of the bullet and the contact surface inside the propellant charge it concerns sizes that are carefully assessed and must be coordinated when an inventive arrangement for holding Shot should be provided. The dimensions of the projectile and the acceleration and deceleration forces to which the projectile. exposed at the weapon in question will determine the requirements to be met in constructing all parts of the invention Holding arrangement must be considered. Any professional can do this Requirements to be taken into account in such a way that one has a snap ring holding arrangement for the Projectiles from caseless cartridges of the type described receive without the ballistic Properties of the ammunition are impaired; for this purpose can simple Experiments and evaluations are carried out as mentioned in connection with those Examples have been described.

For example, the location of the snap ring and the annular groove of the Change the bullet to pick up the explosive along the axis of the bullet in such a way that as it is necessary to optimize the projectile according to its construction Way to accommodate.

Expectations:

Claims (1)

A N S P R Ü C H E 1. Arrangement for holding a projectile in its position in a caseless cartridge when the cartridge has retarding forces is exposed, with the cartridge carrying a propellant charge over its ban e length extending axial cavity, and the projectile at least partially is housed in the cavity, in that the Projectile (10) has an annular groove (26) on its peripheral surface that into the annular groove of the projectile a verb, -auchender snap ring (50) is installed, the outer diameter of which (32) is larger than the outer diameter (34) of the projectile that of the circumferential surface the projectile protruding part of the snap ring has a first contact surface (36), that in the cavity (12) of the propellant charge (14) consuming holding means are present are which determine a second contact surface (24), and that this second contact surface the forward movement of the bullet with the snap ring along the cavity The propellant is interrupted as soon as the first contact surface is in contact with the second contact surface comes. H. Arrangement according to Claim 1, characterized in that it is e k e n n -z e i c h n e t that the cavity (12) of the propellant charge (14) at its front end (20) a smaller diameter (16) and at its rear end (22) a larger diameter (18) and that the verb @ also end in the cavity of the propellant charge Holding means are formed by the surface (24) of the propellant charge that is present there is where the section of the cavity with the larger one. Diameter merges into the section with the smaller diameter. 3. Arrangement according to claim 2, characterized in that g e k e n n -z e i c h net, that the consumable holding means through an in deii cavity (41) of the propellant charge (40) attached cylindrical sleeve, (50) made of a propellant in flat material form are formed that this sleeve has an outer surface (52), an inner surface and a Contact surface (54) has that the outer surface of the sleeve of the inner surface of the cavity the propellant charge is immediately adjacent, and that the contact surface of the sleeve mentioned wide contact surface forms, so that this contact surface is the consuming Forms holding means. 4. Arrangement according to claim 2 or 3, characterized in that g e -k e n n z e i c h n e t ç that the projectile (10) completely into the cavity (12) of the propellant charge (14) is included. 5. Arrangement according to one of claims 2 to 4, by g e k e n n z e i c h net that the snap ring (3Q; 46) made of pressboard material (pressboard) is. 6. Arrangement according to one of claims 2 to 4, characterized g e k e n n shows that the snap ring (30; 46) is elastic and made of kraft paper is produced which contains up to about 70% pentaerythritol tetranitrate.