DE102020133371A1 - Single core full metal jacket bullet and single core ammunition - Google Patents

Abstract

The present invention relates to a full metal jacket projectile, in particular an armor piercing projectile, for ammunition preferably with a caliber of less than 13 mm, comprising a projectile jacket with a front section which is in particular shaped like an ogive and an adjoining, in particular at least partially cylindrical, rear section, a core encased by the projectile jacket, which is dimensioned such that there is a cavity at the front, and an insert arranged in the cavity, which is dimensioned and/or made of a material such that the center of gravity of the metal jacketed bullet is shifted backwards compared to a full metal jacketed bullet without a cavity.

Description

The present invention relates to a full metal jacket bullet, in particular an armor piercing bullet (AP bullet), for ammunition, preferably with a caliber of less than 13 mm, in particular less than 12.7 mm. Furthermore, the present invention relates to ammunition with a full metal jacket projectile.

Full metal jacket bullets are generally characterized in that a jacket encases a core, which is usually made of lead, from the tip of the bullet to the rear of the bullet, with the jacket completely enclosing the core in the area of the tip of the bullet. As a result, the jacket protects the barrel of a firearm from abrasion of the softer core and also prevents deformation or even shattering of the softer core when the bullet hits a target.

So-called armor-piercing projectiles (AP projectiles), which are also called armor-piercing ammunition projectiles, are generally used in the military field to penetrate and destroy armored and/or hardened surfaces of targets. The armor piercing projectiles can have additives, such as explosives, on the inside in order to generate an additional effect after hitting a target, such as detonating the explosives.

U.S. 3,442,216 discloses a generic metal jacketed projectile which has a projectile jacket which is completely closed at the front and which is formed completely around a projectile core and extends to the rear of the projectile. In the area of the rear of the bullet, a jacket base is partially wrapped around the core, so that the core is fixed within the jacket. With known full metal jacket bullets, as is also the case in U.S. 3,442,216 If this is the case, the core, which is usually made of lead, completely occupies the cavity formed by the jacket, even in the front area of the projectile.

However, unsatisfactory precision and ballistics have proven to be disadvantageous in the case of the full metal jacket bullets known in the prior art. In the case of armor-piercing bullets, which can certainly have an unoccupied, free cavity between the core and the bullet jacket in the front, there are also limits in terms of dimensional stability when the bullet hits the target and in terms of penetration performance.

One object of the present invention is to improve the disadvantages of the known prior art, in particular to further develop a full metal jacket bullet in such a way that it has improved precision and/or improved penetration.

The object is solved by the subject matter of the independent claims.

Thereafter, a full metal jacket bullet is provided for ammunition. Generic metal jacketed bullets are single-core bullets, which differ from double-core bullets in that they only have a single core, while double-core bullets have two separate bullet cores. The full metal jacket bullet may be an armor piercing (AP) bullet, for example. Furthermore, generic full metal jacket projectiles can be used, for example, for ammunition with a caliber of up to 13 mm. In general, generic metal jacketed projectiles are characterized in that they are completely closed at the front and can be quite open at the rear. A bullet jacket encases a bullet core from a front bullet tip to the bullet rear, with the bullet tip being completely enclosed by the bullet jacket. AP shells are a special type of jacketed shell and are typically used in the military field to penetrate and destroy armored and/or solid surfaces of targets. They are also called armor-piercing ammunition projectiles. Another special type of AP rounds are armor piercing incendiary rounds (API rounds), to which an additional flammable substance, for example zirconium, is added to create an additional incendiary effect after penetrating the target, especially its armor.

The full metal jacket bullet comprises a bullet jacket which is made of tombac, for example. The projectile casing comprises a front section, in particular shaped like an ogive, and an adjoining, in particular at least partially cylindrical, in particular hollow-cylindrical, rear section. The projectile jacket can have a front section that widens circumferentially, in particular in the manner of an ogive, to form a cavity from a front projectile tip and an adjoining at least partially cylindrical rear section. In other words, the projectile jacket is hollow. The nose of the bullet is formed by a front, edge-side end of the bullet jacket. Starting from the tip of the projectile, the projectile jacket can extend in one piece towards the rear of the projectile, forming the projectile shape cken and can have a constant wall thickness. The cavity is delimited by the projectile jacket. In particular, it is the cylindrical rear section that defines the outer diameter of the jacket, in particular the caliber of the full metal jacket.

Furthermore, the full metal jacket projectile according to the invention comprises a core encased by the projectile jacket, in particular a single core which is made of lead, for example. However, it is also conceivable that the core is made of a lead-free material such as iron, copper or the like. The core is located in the bullet jacket. The core is dimensioned in such a way that there is or remains a cavity at the front. The core can be arranged in the cavity of the projectile jacket and/or be dimensioned in such a way that a front cavity is not occupied by the core. In other words, the core does not fill the cavity completely, in particular on the front side, in particular immediately adjacent to the tip of the projectile up to a certain axial point in front of the tip of the projectile. The core can completely fill the cavity, with the exception of the unoccupied cavity on the front. For example, the projectile jacket is shaped in the tail section in such a way that it jackets the core on the rear side. The rear casing can be understood to mean that the casing is also closed at the rear. However, it is also conceivable that the jacket remains open at the rear or leaves an opening free in which area the core is accessible at the rear.

According to the invention, the full metal jacketed bullet also has an insert which is dimensioned and/or made of a material in such a way that the center of gravity of the full metal jacketed bullet is higher than that of a full metal jacketed bullet without a cavity, ie. H. a full-metal jacketed bullet, in which the core completely fills the hollow jacket and is in full contact with the jacket, is shifted to the rear. The core can have a lower density, in particular a lower specific density, than the bullet core and/or the bullet jacket. The inventors of the present invention have thus surprisingly found a way of transferring the advantages of hollow point bullets to full metal jacket bullets. An essential advantage of the present invention is that the center of gravity of the full metal jacket projectile is shifted backwards, towards the rear of the projectile. This entails significant advantages in terms of the ballistics and/or precision of the full metal jacket bullet.

According to an exemplary further embodiment of the full metal jacket projectile according to the invention, the insert is made from a material that has a lower density, in particular a lower specific density, than the material of the projectile jacket and/or the projectile core. In particular, the insert is made of aluminum, magnesium, brass, steel or plastic. It is clear that the respective material must be selected in such a way that the desired rearward shift in the center of gravity is achieved in order to increase the precision and/or ballistics of the metal jacketed bullet.

According to a further aspect of the present invention, which can be combined with the preceding aspects and exemplary embodiments, a full metal jacket projectile for ammunition is provided. Generic metal jacketed bullets are single-core bullets, which differ from double-core bullets in that they only have a single core, while double-core bullets have two separate bullet cores. The full metal jacket bullet may be an armor piercing (AP) bullet, for example. Furthermore, generic full metal jacket projectiles can be used, for example, for ammunition with a caliber of up to 13 mm. In general, generic metal jacketed projectiles are characterized in that they are completely closed at the front and can be quite open at the rear. A bullet jacket encases a bullet core from a front bullet tip to the bullet rear, with the bullet tip being completely surrounded by the bullet jacket. AP shells are a special type of jacketed shell and are typically used in the military field to penetrate and destroy armored and/or solid surfaces of targets. They are also called armor-piercing ammunition projectiles. Another special type of AP rounds are armor piercing incendiary rounds (API rounds), to which an additional flammable substance, for example zirconium, is added to create an additional incendiary effect after penetrating the target, especially its armor.

The full metal jacket bullet comprises a bullet jacket which is made of tombac, for example. The projectile casing comprises a front section, in particular shaped like an ogive, and an adjoining, in particular at least partially cylindrical, in particular hollow-cylindrical, rear section. The projectile jacket can have a front section that widens circumferentially, in particular in the manner of an ogive, to form a cavity from a front projectile tip and an adjoining at least partially cylindrical rear section. In other words, the projectile jacket is hollow. The nose of the bullet is formed by a front, edge-side end of the bullet jacket. Starting from the tip of the projectile, the projectile jacket can extend in one piece towards the rear of the projectile, forming the projectile shape, and can have a constant wall thickness. The cavity is delimited by the projectile jacket. In particular, it is the cylindrical rear section that defines the outer diameter of the jacket, in particular the caliber of the full metal jacket.

Furthermore, the full metal jacket projectile according to the invention comprises a core encased by the projectile jacket, in particular a single core which is made of lead, for example. However, it is also conceivable that the core is made of a lead-free material such as iron, copper or the like. The core is located in the bullet jacket. The core is dimensioned in such a way that there is or remains a cavity at the front. The core can be arranged in the cavity of the projectile jacket and/or be dimensioned in such a way that a front cavity is not occupied by the core. In other words, the core does not fill the cavity completely, in particular on the front side, in particular immediately adjacent to the tip of the projectile up to a certain axial point in front of the tip of the projectile. The core can completely fill the cavity, with the exception of the unoccupied cavity on the front. For example, the projectile jacket is shaped in the tail section in such a way that it jackets the core on the rear side. The rear casing can be understood to mean that the casing is also closed at the rear. However, it is also conceivable that the jacket remains open at the rear or leaves an opening free in which area the core is accessible at the rear.

According to the further aspect of the present invention, the metal jacketed bullet also has an insert which forms a non-full-surface line or stripe contact with the bullet jacket. It has been found that line or stripe contact is sufficient, for example, to provide jacket support upon impact of the projectile with a target, while allowing the center of gravity of the projectile to be shifted rearwardly, resulting in positive ballistics.

In a further exemplary embodiment, the insert is arranged in the front cavity unoccupied by the core and/or is dimensioned in such a way that a front reservoir of the cavity is unoccupied. This means that the insert leaves a frontal reservoir in the cavity. In other words, the insert does not completely fill the cavity. For example, the front reservoir is set up to receive particles, such as fluid particles and/or solid particles, in particular assembly lubricants, or the like, which are used when the rear projectile core is pressed into the cavity. The front reservoir therefore forms a kind of catchment basin for various residuals, such as lubricants. In this way, process reliability can be increased in the manufacture of full metal jacket bullets.

According to a further exemplary embodiment, the insert is arranged in the front cavity unoccupied by the core and/or is dimensioned in such a way that a rear reservoir of the cavity between the insert and the core is unoccupied. This means that the liner leaves a stern reservoir in the cavity. In other words, the insert does not completely fill the cavity. For example, the stern reservoir is formed as an annular space that is interrupted in the middle by the contact between the core and the insert.

According to an exemplary development of the full metal jacketed projectile according to the invention, it can be used at a distance of at least 0.1 times the external diameter of the projectile, in particular the caliber of the full metal jacketed projectile, and at most 2 times, in particular 1.5 times or 1 times Bullet outer diameter arranged from the bullet nose. In other words, the axial length of the front reservoir is in the range of 0.1 to 2 times the projectile's outer diameter, minus the wall thickness of the projectile jacket in the region of the projectile tip.

According to a further aspect of the present invention, which can be combined with the preceding aspects and exemplary embodiments, a full metal jacket projectile for ammunition is provided. Generic full metal jacket bullets are single-core bullets, which differ from double-core bullets in that they only have a single core, while double-core bullets have two separate bullet cores. The full metal jacket bullet may be an armor piercing (AP) bullet, for example. Furthermore, generic full metal jacket projectiles can be used, for example, for ammunition with a caliber of up to 13 mm. In general, generic metal jacketed projectiles are characterized in that they are completely closed at the front and can be quite open at the rear. A bullet jacket encases a bullet core from a front bullet tip to the bullet rear, with the bullet tip being completely surrounded by the bullet jacket. AP shells are a special type of jacketed shell and are typically used in the military field to penetrate armored and/or solid surfaces of targets to be able to generate and destroy. They are also called armor-piercing ammunition projectiles. Another special type of AP rounds are armor piercing incendiary rounds (API rounds), to which an additional flammable substance, for example zirconium, is added to create an additional incendiary effect after penetrating the target, especially its armor.

The full metal jacket bullet comprises a bullet jacket which is made of tombac, for example. The projectile casing comprises a front section, in particular shaped like an ogive, and an adjoining, in particular at least partially cylindrical, in particular hollow-cylindrical, rear section. The projectile jacket can have a front section that widens circumferentially, in particular in the manner of an ogive, to form a cavity from a front projectile tip and an adjoining at least partially cylindrical rear section. In other words, the projectile jacket is hollow. The nose of the bullet is formed by a front, edge-side end of the bullet jacket. Starting from the tip of the projectile, the projectile jacket can extend in one piece towards the rear of the projectile, forming the projectile shape, and can have a constant wall thickness. The cavity is delimited by the projectile jacket. In particular, it is the cylindrical rear section that defines the outer diameter of the jacket, in particular the caliber of the full metal jacket.

Furthermore, the full metal jacket bullet comprises a core encased by the bullet jacket, in particular a single core which is made of lead, for example. However, it is also conceivable that the core is made of a lead-free material such as iron, copper or the like. The core is located in the bullet jacket. The core is dimensioned in such a way that there is or remains a cavity at the front, which has a length of at most 40%, in particular at most 35%, 30% or at most 25% of the total length of the full metal jacketed projectile, viewed in the longitudinal direction of the projectile. In other words, the bullet core extends from the bullet tail over at least 60%, in particular over at least 65%, 70% or over at least 75% of the total length of the full metal jacket bullet. The core can be arranged in the cavity of the projectile jacket and/or be dimensioned in such a way that a front cavity is not occupied by the core. In other words, the core does not fill the cavity completely, in particular on the front side, in particular immediately adjacent to the tip of the projectile up to a certain axial point in front of the tip of the projectile. The core can completely fill the cavity, with the exception of the unoccupied cavity on the front. For example, the projectile jacket is shaped in the tail section in such a way that it jackets the core on the rear side. The rear casing can be understood to mean that the casing is also closed at the rear. However, it is also conceivable that the jacket remains open at the rear or leaves an opening free in which area the core is accessible at the rear.

According to the further aspect of the present invention, the full jacketed bullet also has a support device, which can be formed, for example, by using one of the aspects or exemplary embodiments described above, which is arranged in the cavity and is assigned to the front section and the front section at the impact of the projectile on a target. Due to the fact that a cavity is left in the front of the full metal jacket projectile, the projectile threatens to collapse at the front in the area of the front section when it hits a particularly hard target. This risk of collapse is counteracted by the support device, which can be set up to counteract a particularly destructive deformation of the front projectile jacket. A related advantage, which has a particularly positive effect on AP projectiles, is the frontal supporting effect of the insert against the projectile jacket in the front section. When the projectile hits the target, the insert absorbs the forces acting on the solid metal jacket projectile from outside, in particular deformation forces, and counteracts deformation of the projectile jacket. As a result, the full metal jacket bullet can essentially remain dimensionally stable. As a result, the penetration performance or penetration performance of the full metal jacket AP bullet can be significantly increased.

In an exemplary embodiment of the full metal jacket projectile, the support device is supported at the rear by the core upon impact of the full metal jacket projectile, in particular in such a way that there is an uninterrupted flow of force from the projectile jacket via the support device into the core. The support can be realized via a circumferential, non-full-area line contact or, in particular, narrow strip contact with the projectile jacket. A force input ring can thus be formed, via which the impact and/or deformation energy is introduced from the projectile jacket into the support device and is finally conducted further into the core.

According to a further exemplary embodiment, the support device is implemented as an insert which is arranged in the cavity and which is keyed to the front section of the projectile jacket via the core. The bet can be made according to any of the Aspects or exemplary embodiments described above may be formed. The wedging can ensure optimal power transmission or power flow deflection of the impact and/or deformation energy.

Furthermore, the insert can be arranged in the cavity in such a way that an axial relative movement between the core and the projectile jacket is essentially prevented. For example, the insert can be jammed within the projectile jacket, in particular between the core and the projectile jacket. As a result, both the insert and the core are axially fixed or fixed with respect to the longitudinal direction of the projectile within the projectile jacket. Another advantage, which has a particularly positive effect on AP projectiles, is the frontal supporting effect of the insert against the projectile jacket in the front section. When the projectile hits the target, the insert absorbs the forces acting on the solid metal jacket projectile from outside, in particular deformation forces, and counteracts deformation of the projectile jacket. As a result, the full metal jacket bullet can essentially remain dimensionally stable. As a result, the penetration performance or penetration performance of the full metal jacket AP bullet can be significantly increased.

In contrast to other full metal jacket projectiles, AP projectiles can have a sleeve-like projectile shoe which is inserted into the projectile jacket, in particular into the rear section, and surrounds the projectile core. As a result, sections of the projectile jacket may arise which are not internally supported or occupied by the projectile core, so that when the projectile impacts the target these areas are more susceptible to deformation. The projectile jacket can be supported from the inside by means of the insert according to the invention, so that there is less deformation, as a result of which the penetration performance can be improved.

In an exemplary embodiment of the full metal jacket projectile according to the invention, the insert is arranged in the cavity in such a way that relative rotation of the insert with respect to the projectile jacket and/or axial relative movement between the insert and the projectile jacket is/is prevented. Due to the positionally fixed arrangement of the insert with respect to the projectile jacket, its supporting effect is increased, so that the projectile jacket is more dimensionally stable.

According to an exemplary development, the insert is adapted to an inner contour of the front section casing in axial sections, in particular along the entire outer contour. In this way, in particular, the supporting effect of the insert can be increased. For example, the supporting effect is related to the mutual bearing/supporting surface between the insert and the projectile jacket.

According to a further exemplary development, the insert has an ovoid, spherical, conical or cone-shaped outer contour. For example, the insert has a rotationally symmetrical shape. The specified forms of use have proven to be advantageous, especially with regard to the supporting effect. In particular, it can be reliably ensured that the insert is adequately adapted to the inner contour of the front section jacket, which is in particular shaped like an ogive, in order to be able to counteract the deformation forces acting from outside when the projectile hits the target over the largest possible area.

According to a further exemplary embodiment of the present invention, the insert has a rotationally symmetrical shape and a maximum diameter of at least 30% and at most 70% of the projectile diameter, in particular the caliber of the full metal jacket projectile. For example, in the case of a spherical shape of the insert, the relevant dimensions have proven to be particularly advantageous. By dimensioning the insert with its rotationally symmetrical shape in relation to the bullet jacket, the volume area occupied by the insert can be defined so that the center of gravity of the full metal jacket bullet can be shifted backwards and adjusted as desired.

According to a further exemplary embodiment of the full metal jacket projectile according to the invention, the insert has an essentially rotationally symmetrical basic shape, with a particularly circumferential contact surface, in particular line or preferably narrow strip contact surface, between the insert and the inner jacket contour of the projectile jacket, which acts as a support surface when the projectile hits the target. be or become deformed during assembly in such a way that the insert deviates from its essentially rotationally symmetrical shape in the region of the contact surface. This can be ensured by using a soft or ductile material for the insert. For example, the insert is pressed against the front section jacket of the projectile jacket by pressing the core in at the rear and is at least partially deformed there, in particular adapted to an inner contour of the projectile jacket at least in axial sections.

In a further exemplary embodiment of the present invention, the insert is introduced into the projectile casing, in particular pushed in, preferably pressed in, in such a way that the insert deforms during assembly. For example, the insert adapts to an inner contour of the projectile jacket at least in axial sections during assembly. In particular, this ensures that a relative rotational movement and/or a relative axial movement between the insert and the jacket is/are prevented. For example, the insert deforms as a result of the bullet core being introduced from the rear into the bullet jacket already occupied by the insert. For example, the insert is slightly squeezed together at the front, in particular by means of the rear projectile core pressed against an inner contour of the front section of the projectile jacket, so that it is slightly deformed on its outer circumference, in particular pressed in, in particular adapts at least in sections to the inner contour of the front section. It has proven to be advantageous to use a ductile, soft material for the insert, in particular a softer and/or more ductile material than that of the projectile core and/or the projectile jacket. For example, magnesium has proven to be advantageous and particularly well suited.

According to a further exemplary embodiment of the full metal jacket projectile according to the invention, the insert is accommodated and/or dimensioned in the projectile jacket in such a way that the insert prevents the core, in particular core material, from penetrating into the front reservoir. Alternatively or additionally, the front reservoir can be sealed off from the cavity at the rear, as seen with respect to the insert. The insert can thus act as a kind of flow barrier during assembly against the rear core, which is made of lead, for example, and/or has a high specific gravity and can tend to flow towards the nose of the bullet. According to an exemplary development, an at least partially circumferential, in particular completely circumferential, in particular completely circumferential sealing contact line or sealing contact surface is formed between the insert and the projectile jacket.

In a further exemplary embodiment of the full metal jacket projectile according to the invention, the insert is made from hardened steel. In the case of AP bullets in particular, a particularly hard and dimensionally stable insert has proven to be advantageous in order to maximize the supporting effect against deformation of the bullet jacket. The penetration performance of the full metal jacket bullet can be increased by using an insert made of hardened steel. The more dimensionally stable the full metal jacket bullet remains, the higher its penetration performance can be.

According to an exemplary development of the full metal jacket projectile according to the invention, the insert is roughened at least in regions on a surface facing the projectile jacket. For example, the insert has at least partially a surface roughness, given by way of example via the average peak-to-valley height Rz, in the range from Rz 15 to Rz 200, in particular in the range from Rz 25 to Rz 150. It has been found that the advantages of the invention increase with a certain surface roughness .

Furthermore, it can be provided that the insert has a readable data carrier. In this respect, it is possible to assign certain information to the mission, which can be queried again at any time.

According to an exemplary development, a floor-specific identifier is stored on the readable data carrier. Thus, an unambiguous assignment of the full metal jacket projectile, for example with regard to the manufacturer and/or user of the firearm, is possible. Alternatively or additionally, the readable data carrier can have a position transmitter, in particular an RFID transponder, a telemetry transmitter or a GPS transmitter, or a forensic marker. In this respect it is possible to understand the geographic location of the full metal jacket bullet. For example, it is also possible to track the metal jacketed projectile literally after it has been fired, for example if this is to be used to mark an armored vehicle in order to then be able to track its GPS position. Furthermore, the use of forensic markers in forensics has proven to be advantageous in terms of evaluation.

According to an exemplary development of the full metal jacketed projectile according to the invention, the insert can be provided with a substance which causes a chemical reaction when the full metal jacketed projectile hits a target. For example, the full metal jacket bullet can thus implement a terminal ballistic effect, such as a flash of light, similar to the titanium tips in API bullets. For example, this chemical substance can be designed and/or housed in the insert in such a way that the chemical substance is activated by a negative acceleration force when the full metal jacketed bullet hits a target and/or by a deformation of the insert, which is caused by the of the projectile can be triggered on the target by externally acting deformation forces.

According to a further aspect of the present invention, which can be combined with the previous aspects and exemplary embodiments, an intermediate, also known as an intermediate product, is required for producing a full metal jacket bullet, in particular an armor-piercing bullet, for example for ammunition with a caliber of less than 13 mm, provided. For example, the intermediate can be used to produce a full metal jacket projectile according to the invention.

The intermediate according to the invention comprises a hollow sleeve which forms the projectile jacket and has a closed front and an open rear. For example, the closed front forms the tip of the finished metal jacketed bullet.

Furthermore, the intermediate according to the invention comprises an insert inserted into the sleeve from the open rear, which is arranged in the sleeve such that a front reservoir adjoining the front is not occupied by the insert and is sealed off from the rear sleeve cavity. Such an intermediate is characterized, among other things, by a flow barrier that prevents the bullet core, which is made of lead, for example, and has a high specific density, from flowing in the direction of the front of the case or the bullet tip when the rear bullet core is pressed in to form the full metal jacket bullet.

According to an exemplary embodiment of the intermediate according to the invention, an at least partially encircling, in particular completely encircling, sealing contact line or non-full-area, in particular narrow, strip sealing contact surface is formed between the insert and the sleeve. The sealing contact line or the sealing contact surface prevents the penetration of the core material into the front reservoir, for example.

According to an exemplary development of the intermediate according to the invention, the insert is in sealing contact with the sleeve such that the material of a core to be inserted, in particular pressed, into the sleeve at the rear, which is made of lead, for example, cannot get into the front reservoir. Thus, the inventive effect of shifting the center of gravity to the rear can be ensured on the one hand due to the introduction of a front-side insert which, for example, has a lower specific density than the rear-side core, and on the other hand by the unoccupied, hollow front reservoir.

In a further exemplary embodiment of the intermediate according to the invention, the case front has an end that forms the bullet tip, from which the insert is at a distance of at least 0.1 times the case outer diameter, in particular the caliber of the full metal jacket bullet, and at most 2 times, in particular 1.5 times or 1 times the sleeve outer diameter is arranged. The front reservoir dimensioned in this way has proven to be particularly advantageous in terms of shifting the center of gravity and the associated increase in precision through improved ballistics.

According to a further aspect of the present invention, which can be combined with the preceding aspects and exemplary embodiments, a method for producing an intermediate, in particular an intermediate product, for producing a full metal jacket projectile or a method for producing a full metal jacket projectile is provided. For example, an intermediate according to the invention and/or a full metal jacket projectile according to the invention can be produced by means of the method.

In the process, a hollow sleeve forming the projectile jacket is closed at the front. Furthermore, an insert is inserted into the sleeve, in particular in its cavity, in such a way that a front reservoir of the sleeve remains unoccupied and is sealed off from the rear sleeve cavity.

According to an exemplary development, a core can be introduced into the rear sleeve cavity and the sleeve can be bent over, in particular flanged, on the rear side for the axial fixation of the core in the sleeve cavity. In particular, it is ensured in this way that an axial relative movement between the core and the sleeve jacket is essentially prevented.

In general, it has been found that a predetermined minimum insert hardness has a positive effect on the penetration performance of the full metal jacketed bullet. A hardness in the range from 55 to 65 HRC (Rockwell hardness) has proven particularly advantageous.

Preferred embodiments are specified in the dependent claims.

• 1 eine Schnittansicht einer beispielhaften Ausführung eines erfindungsgemäßen Vollmantelgeschosses; und
• 2 eine Schnittansicht einer weiteren beispielhaften Ausführung eines erfindungsgemäßen Vollmantelgeschosses, das als AP-Geschoss gestaltet ist.

In the following, further properties, features and advantages of the invention are made clear by means of a description of preferred embodiments of the invention using the accompanying exemplary drawings, in which:

• 1 a sectional view of an exemplary embodiment of a full metal jacket projectile according to the invention; and
• 2 a sectional view of a further exemplary embodiment of a full metal jacket projectile according to the invention, which is designed as an AP projectile.

In the description of exemplary embodiments of the present invention, a full-metal jacketed bullet according to the invention is generally given the reference number 1 . Full metal jacket projectiles 1 according to the invention, which can also be referred to as single-core full metal jacket projectiles, comprise in particular the following main components: a hollow projectile jacket 3; a bullet core 5 arranged in the jacket; and an insert 7 also housed in the bullet jacket. For the description of the present exemplary embodiments of full metal jacket bullets 1 according to the invention, it can be assumed that the bullet jacket 3 is made of tombac, for example, the bullet core 5 is made of lead and the insert 7 is made of one material is, which has a lower density than the projectile jacket 3 or than the projectile core 5.

In 1 an exemplary embodiment of a full metal jacket projectile according to the invention, namely a so-called BALL projectile, is shown. The full metal jacket projectile 1 has a projectile jacket 3 made of tombac that defines the projectile caliber and has a projectile tip 9 at the front, an adjoining front section 11 which is in particular shaped like an ogive and a rear section 13 which is cylindrical in sections and adjoins the front section 11 .

According to the generic type, the metal jacketed projectile 1 is closed in the area of the projectile tip 9 and open towards the rear. As in 1 is shown, it is a rotationally symmetrical projectile 1 with respect to the axis of rotation R indicated by a dashed line.

According to one aspect, the projectile core 5, around which the projectile jacket 3 is bent at the rear to form a circumferential ring 15 forming the base of the projectile and having an opening 17, and which is encased by the projectile jacket 3, does not completely occupy the hollow projectile jacket 3, but leaves a cavity 19 free or unoccupied at the front. As a result, the overall center of gravity of the metal jacketed projectile 1 can be shifted in the direction of the rear of the projectile, as a result of which the precision and the ballistics of the full metal jacketed projectile 1 are improved. An insert 7 made of magnesium, aluminum, plastic or the like, for example, is inserted into the cavity 19 on the front side. On the one hand, the center of gravity of the metal jacketed bullet 1 is shifted backwards because of the lower density of the insert 7 compared to the material of the core 5 and on the other hand due to the fact that the insert 7 does not completely occupy or fill the cavity 19 .

In 1 it is a spherical insert 7, which releases a front reservoir 21 at the front, which is hollow. In 1 it can be seen that there is a circumferential sealing contact line 23 between the insert 7 and the projectile jacket 3 . The sealing contact can also be a particularly narrow strip sealing contact, for example because the insert 7 is deformed at least in sections when it is inserted into the projectile jacket 3, in particular when it is pressed in, in order to adapt it to the inner contour of the projectile jacket 3, for example.

In the area of the sealing contact, a type of flow barrier is formed in relation to the lead core 5 on the rear side. It is also in 1 It can be seen that when the projectile core 5 is pressed into the projectile jacket 3, the projectile core is deformed on a front end face 25, in particular adapting to an outer contour of the insert. The face 25 is in 1 partially concave. On the one hand, the insert 7 can achieve the desired shift in the center of gravity backwards to increase precision and improve ballistics, and on the other hand it can be ensured that the stability and/or true-to-form of the full metal jacketed bullet 1 is not too severely impaired when it hits a target, since the Insert 7 supports the projectile jacket 3 on the inside in the area of the front section 11 against the action of external forces.

Furthermore, the insert 7 can be dimensioned in such a way that a rear reservoir 41 is unoccupied or remains free between the insert 7 and the core 5, which is formed in the form of an annular space.

In the sectional view of the exemplary embodiment of a full metal jacket projectile according to the invention 2 an AP bullet is shown. Identical or similar components are provided with the same or similar reference numbers.

A difference of the AP shell 1 the 2 compared to the BALL bullet 1 consists, among other things, that a so-called bullet shoe 27 is introduced into the bullet casing 3 at the rear, which is a hollow, sleeve-like structure with a case base 29 facing the ring tail 15 and a peripheral sleeve wall 31, which is adapted to an inner contour of the bullet casing 3.

It can also be seen that the shape of the bullet core 5 from 2 from the bullet core 5 1 differs. On the one hand, the bullet core 5 is formed essentially as a solid cylinder, with the bullet core 5 being pointed at the front, on an end face facing the insert 7 , and defining a tip 33 and a conical or pyramidal end face. In the area of the front section 11, the projectile core 5 contacts the inner contour of the projectile jacket 3 over a certain axial section. In this axial section, which is generally provided with the reference numeral 37 and is designed as a circumferential contact or bearing surface with respect to the axis of rotation R, the projectile core 5 supports the projectile jacket 3 when the projectile hits the target. At the back with respect to the contact or bearing surface 37 is a free space area 39 which is unoccupied and surrounds the projectile core 5 in the manner of a ring.

Especially with the AP bullet 1 according to 2 the insert 7 designed as a spherical support device, in particular a support ball, causes an increase in stability and shape stabilization of the ogive-like front section 11 of the projectile jacket 3, as a result of which its precision and penetration capacity can be increased. The support ball forms a type of anti-collapse protection that prevents the front section 11 of the projectile jacket 3 from failing or collapsing when it hits a target. It has also been found that when using an insert 7 in general, especially when using a support ball 7 with a hardness in the range of 55 to 65 HRC (Rockwell hardness), the penetration performance can be further enhanced.

The features disclosed in the above description, the figures and the claims can be important both individually and in any combination for the implementation of the invention in the various configurations.

Reference List

1

full metal jacket bullet

3

jacket

5

bullet core

7

mission

9

bullet tip

11

front section

13

tail section

15

ring tail

17

opening

19

cavity

21

front reservoir

23

sealing contact line

25

face

27

bullet shoe

29

case base

31

sleeve wall

33

sleeve tip

35

sleeve front

37

contact surface

39

clearance area

41

stern reservoir

R

axis of rotation

QUOTES INCLUDED IN DESCRIPTION

This list of documents cited by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent Literature Cited

• US3442216 [0004]

Claims (27)

Full metal jacket bullet (1), in particular armor-piercing bullet, for ammunition, in particular with a caliber of less than 13 mm, comprising: - a projectile casing (3) with a front section (11) shaped in particular in the manner of an ogive and an adjoining, in particular at least partially cylindrical, rear section (13); - A core (5) which is encased by the projectile jacket (3) and is dimensioned in such a way that there is a cavity (19) at the front; and - An insert (7) arranged in the cavity (19), which is dimensioned and/or made of a material such that the center of gravity of the metal jacketed projectile (1) is shifted backwards compared to a full metal jacketed projectile without a cavity. Full metal jacket bullet (1) after claim 1 , wherein the insert (7) is made of a material that has a lower density than the material of the projectile jacket (3) and/or the core (5), in particular made of aluminum, magnesium, brass, steel or plastic. Full metal jacket bullet (1), in particular according to one of the preceding claims, in particular armor piercing bullet, for ammunition in particular with a caliber of less than 13 mm, comprising: - a projectile casing (3) with a front section (11) shaped in particular in the manner of an ogive and an adjoining, in particular at least partially cylindrical, rear section (13); - A core (5) which is encased by the projectile jacket (3) and is dimensioned in such a way that there is a cavity (19) at the front; and - An insert (7) arranged in the cavity (19) and forming a non-full-area line or stripe contact with the projectile jacket (3). Full metal jacket bullet (1) according to one of the preceding claims, wherein the insert (7) is arranged in the cavity (19) and/or is dimensioned in such a way that a front reservoir (21) of the cavity (19) is unoccupied, wherein in particular the front reservoir ( 21) is set up to receive particles such as fluid particles and/or solid particles, in particular assembly lubricants or the like. Full metal jacket bullet (1) according to one of the preceding claims, wherein the insert (7) is arranged in the cavity (19) and/or is dimensioned in such a way that a rear reservoir (41) of the cavity (19) between the insert (7) and the core ( 5) is unoccupied, with the rear reservoir (41) in particular being formed as an annular space. Full metal jacketed bullet (1) according to one of the preceding claims, wherein the insert (7) is arranged at a distance from the bullet nose (9) of at least 0.1 times a bullet jacket outside diameter, in particular the caliber of the full metal jacketed bullet, and at most twice the bullet jacket outside diameter is. Full metal jacket bullet (1), in particular according to one of the preceding claims, in particular armor piercing bullet, for ammunition in particular with a caliber of less than 13 mm, comprising: - a projectile casing (3) with a front section (11) shaped in particular in the manner of an ogive and an adjoining, in particular at least partially cylindrical, rear section (13); - a core (5) encased by the projectile jacket (3), which is dimensioned in such a way that there is a cavity (19) at the front which has a length of at most 40%, in particular at most 35%, 30% or at most 25% of the total length of the full metal jacket bullet (1); and - A support device which is arranged in the cavity (19) and is associated with the front section (11) and which supports the front section (11) when the metal jacketed projectile (1) hits a target. Full metal jacket bullet (1) after claim 7 , wherein the support device is supported on the rear side by the core (5) upon impact of the full metal jacket projectile (1), in particular in such a way that there is an uninterrupted flow of force from the projectile jacket (3) via the support device into the core (5). Full metal jacket bullet (1) after claim 7 or 8th wherein the support device is realized as an insert (7) arranged in the cavity and which is keyed to the front portion (11) of the projectile jacket (3) via the core (5). Full metal jacket bullet (1) according to one of the preceding claims, wherein the insert (7) is arranged in the cavity (19) in such a way that an axial relative movement between the core (5) and the bullet jacket (3) is essentially prevented. Full metal jacket projectile (1) according to one of the preceding claims, wherein the insert (7) is arranged in the cavity (19) in such a way that a relative rotation of the insert with respect to the projectile jacket and/or a relative axial movement between the insert (7) and the projectile jacket ( 3) is/are prevented. Full metal jacket bullet (1) according to any one of the preceding claims, wherein the insert (7) is full in axial sections, in particular along it permanent outer contour, is adapted to an inner contour of the front section coat. Full metal jacket bullet (1) according to one of the preceding claims, wherein the insert (7) has an ovoid, spherical, conical or cone-shaped outer contour. Full metal jacket bullet (1) according to one of the preceding claims, wherein the insert (7) has a rotationally symmetrical shape and has a maximum diameter in the range of 30% to 70% of the bullet diameter. Full metal jacket bullet (1) according to one of the preceding claims, wherein the insert (7) has an essentially rotationally symmetrical basic shape, with a contact surface, in particular a circumferential contact surface, in particular a line or stripe contact surface, between the insert (7) and the inner jacket contour being deformed during assembly in such a way that the insert (7) deviates from its essentially rotationally symmetrical shape in the area of the contact surface. Full metal jacket bullet (1) according to one of the preceding claims, wherein the insert (7) is introduced, in particular pushed, in particular pressed into the bullet jacket (3) in such a way that the insert (7) deforms during assembly, in particular to an inner contour of the Projectile casing adapts at least in axial sections, in particular in order to prevent a relative rotational movement and/or a relative axial movement between the insert (7) and the projectile casing (3). Full metal jacket bullet (1) according to one of Claims 4 until 16 , wherein the insert (7) is housed in the projectile jacket (3) and/or is dimensioned such that the insert (7) prevents the core from penetrating into the front reservoir and/or that the front reservoir is opposite the cavity ( 19) is sealed, with in particular an at least partially circumferential, in particular completely circumferential, sealing contact line or surface being formed between the insert (7) and the projectile jacket (3). Full metal jacket bullet (1) according to one of the preceding claims, wherein the insert (7) is made of hardened steel. Full metal jacket bullet (1) according to one of the preceding claims, wherein the insert (7) is roughened at least in regions on a surface facing the bullet jacket (3), in particular having a roughness in the range of Rz 25 to Rz 150. Full metal jacket bullet (1) according to one of the preceding claims, wherein the insert (7) has a readable data carrier. Full metal jacket bullet (1) after claim 20 , wherein a projectile-specific identifier is stored on the readable data carrier and/or the readable data carrier has a position transmitter, in particular an RFID transponder, a telemetry transmitter or a GPS transmitter, or a forensic marker. Full metal jacketed bullet (1) according to one of the preceding claims, wherein the insert (7) is provided with a substance which causes a chemical reaction when the full metal jacketed bullet hits a target. Intermediate for producing a full jacket projectile (1) designed in particular according to one of the preceding claims, comprising - a projectile jacket (3) forming, hollow sleeve having a closed front and an open rear; and - An insert (7) inserted into the sleeve from the open rear, which is arranged in the sleeve in such a way that a front reservoir (21) adjoining the front is unoccupied and sealed off from the rear sleeve cavity. intermediate after Claim 23 , wherein an at least partially circumferential, in particular completely circumferential, sealing contact line or non-full-surface strip sealing contact surface is formed between the insert (7) and the sleeve. intermediate after Claim 23 or 24 , wherein the insert (7) and the sleeve are in sealing contact such that the material of a core (5) to be inserted, in particular pressed, into the sleeve at the rear, for example made of lead, cannot get into the front reservoir. Intermediate after one of the Claims 23 until 25 , wherein the case front has an end forming the bullet tip (9), from which the insert (7) is arranged at a distance of at least 0.1 times the case outer diameter, in particular the caliber of the full metal jacket bullet, and at most 2 times the case outer diameter . A method for producing a particular according to one of Claims 23 until 26 trained intermediates or for producing a particular according to one of Claims 1 until 22 trained full metal jacket projectile (1), in which - a the projectile jacket (3) forming, hollow sleeve is closed at the front; and - an insert (7) is inserted into the sleeve in such a way that a frontal reservoir (21) in the sleeve remains unoccupied and is sealed against a rearward sleeve cavity; In particular, a core (5) is introduced into the rear sleeve cavity and the sleeve is bent over on the rear side to fix the core (5) axially in the sleeve cavity.

Images