DE102020006200A1 - PROCEDURE FOR IMPROVED ACCELERATION OF THE PROJECTILE OF A BULLET - Google Patents

Abstract

The present invention relates to a method with which the air pressure p in the barrel of a firearm is reduced by means of a projectile (1) with a projectile (2) during the firing process of a propellant charge (10) in the projectile (1). The reduction in air pressure is generated by an evacuated cavity (3) in the projectile (2) of the projectile (1), which is opened when the propellant charge (10) of the projectile (1) is fired. This improves, among other things, the range and accuracy of the projectile with the same amount of propellant (2). In addition, the unavoidable recoil of the firearm in use is reduced.

Description

The present invention relates to a method for improved acceleration of the projectile of a projectile in the barrel of a firearm, in particular a projectile which, when fired, achieves greater range and accuracy with the same propellant charge, while reducing the air pressure within the barrel of the firearm.

In order to achieve higher acceleration and thus a higher muzzle velocity of a projectile, a higher gas pressure is generally required, which can be achieved with a larger propellant charge, among other things.

Shaped charge projectiles with a cavity in which there is a vacuum are from the DE 1 147 143 known in the prior art. The vacuum in this cavity is generated during the flight of the projectile and when it hits the target object it causes a special penetrating effect as a result of the interaction between the vacuum and the so-called plume jet in the cavity. It is to be regarded as a disadvantage of this invention that the vacuum is only generated during the flight of the hollow charge projectile.

Furthermore, from the EP 2 245 419 B1 an explosive projectile for a liquid explosive, and a method for its production have become known, in which a cavity is provided inside the projectile casing, which serves to expand the liquid explosive in the event of temperature fluctuations.

It is considered disadvantageous in the general state of the art that the air resistance in the barrel of a firearm when the projectile is fired is relatively high and thus reduces the acceleration of the projectile, which greatly reduces the muzzle velocity and consequently the range and accuracy of the projectile. To prevent this, it would be desirable, for example, to at least reduce the air pressure in the barrel of the weapon while the projectile is being fired from the case of the projectile.

It is therefore the object of the present invention to improve the known disadvantages of the prior art and to provide a method with which the air pressure in the barrel of a firearm is at least reduced when a projectile is fired.

This object is solved with the characterizing features of the main claims. Further features essential to the invention can be found in the dependent claims and the detailed description.

According to the invention, the method for increasing the muzzle velocity when firing a projectile from a firearm in the period from the firing of the shot to the exit of the projectile from the barrel of the firearm is characterized in that part of a cavity of the projectile is at least partially evacuated, the vacuum inside of the cavity is broken when the propellant charge of the projectile burns, causing a brief drop in air pressure in the barrel of the firearm.

The projectile of a projectile according to the invention is characterized by an evacuated cavity which opens during the firing process of the propellant charge and thus at least partially reduces the air pressure within the barrel of the firearm.

It is advantageous that at least one closure is arranged on the cavity, which seals the cavity airtight in such a way that the cavity remains evacuated over a longer period of time.

A further advantage can be seen in the fact that the closure has at least one sealing element which interacts with a mass element and at least one wall of the cavity.

It is also advantageous for a spring element to be arranged underneath the mass element, which spring element holds the mass element in a sealing position for sealing off the cavity when it is at rest.

Furthermore, it is advantageous that the projectile is arranged in a sleeve over a propellant charge, which is ignited by means of a fuse in the lower area of the projectile.

A further advantage is seen in the fact that the projectile has at least one channel that connects the cavity with the atmosphere in the barrel of the firearm.

It is also advantageous that the at least one channel is shaped in cross section parallel to the longitudinal axis of the projectile, for example cylindrical or funnel-shaped or truncated cone-shaped or curved or curved, depending on which shape provides the most favorable flow conditions.

It is also advantageous that a pin is arranged on the mass element, which in the closed state of the cavity at least partially fills the at least one channel.

It is also advantageous that the tip of a pin arranged on the mass element can be concave or convex.

Furthermore, it is advantageous that the cavity is profiled in cross section parallel to the longitudinal axis of the projectile on the side walls.

It is also considered advantageous that the mass element has at least one sealing element at a suitable point, which seals the cavity, a vacuum-tight connection being produced between the mass element and the cavity.

• 1 eine schematische Darstellung eines Geschosses (1) mit einem Projektil (2), das einen Hohlraum (3) aufweist, der evakuiert ist, wobei das Projektil (2) in einer Hülse (9) steckt, die mit einer Treibladung (10) gefüllt ist;
• 2 eine schematische Querschnittsdarstellung des Projektils 2, bei dem das Masseelement (7) den Verschluss (4) zum Hohlraum (3) geöffnet hat;
• 3 einen schematischen Querschnitt parallel zur Längsachse des Geschosses (1') eines weiteren Ausführungsbeispiels eines Projektils (2') mit einem geschlossenen Hohlraum (3), durch den ein Masseelement (7') ragt;
• 4 einen schematischen Querschnitt des Projektils (2') aus 3, bei dem das Masseelement (7') in einer Stellung ist, bei der der Hohlraum (3) geöffnet ist;
• 5 den schematischen Querschnitt eines weiteren Ausführungsbeispiels des Projektils (2) in geschlossenem Zustand des Hohlraumes (3);
• 6 den schematischen Querschnitt des Projektils (2) aus 5, bei dem das Masseelement (7') in einer Stellung steht, bei der der Hohlraum (3') geöffnet ist;
• 7 eine Blockdarstellung der einzelnen Verfahrensschritte.

In the following, the invention is explained in more detail with reference to drawings. It shows

• 1 a schematic representation of a projectile (1) with a projectile (2) which has a cavity (3) which is evacuated, the projectile (2) being in a sleeve (9) which is filled with a propellant charge (10). ;
• 2 a schematic cross-sectional view of the projectile 2, in which the mass element (7) has opened the closure (4) to the cavity (3);
• 3 a schematic cross section parallel to the longitudinal axis of the projectile (1') of a further embodiment of a projectile (2') with a closed cavity (3) through which a mass element (7') protrudes;
• 4 a schematic cross-section of the projectile (2'). 3 , in which the mass element (7 ') is in a position in which the cavity (3) is open;
• 5 the schematic cross section of a further embodiment of the projectile (2) in the closed state of the cavity (3);
• 6 the schematic cross-section of the projectile (2). 5 , in which the mass element (7 ') is in a position in which the cavity (3') is open;
• 7 a block diagram of the individual process steps.

the 1 shows a schematic cross-sectional view of a projectile 1 according to the invention with a projectile 2, which is partially arranged in the case 9 of the projectile 1 above the propellant charge 10. In this illustration, an ignition element 11 projects into the propellant charge 10 in the lower area of the sleeve 9, which is fired when the ignition element 11 is ignited. The projectile 2 is arranged above the propellant charge 10 and has a shaped cavity 3, the walls 6, 6' of which are straight cylindrical in one embodiment and curved or curved in another embodiment, which is symbolized by the dashed lines 6' . The cavity 3 is connected at one end to a duct 12 which establishes communication between the cavity 3 and the atmosphere in the barrel of the firearm. The channel 12 does not necessarily have to be cylindrical in shape, but can also have other shapes such as, for example, a funnel shape or a truncated cone shape, depending on which flow conditions best affect the entry of the air masses from the barrel of the firearm. A spring element 8 is arranged in the cavity 3 below a mass element 7, which exerts mechanical pressure on the mass element 7 in the direction of the channel 12 in order to seal the closure 4 between the channel 12 and the cavity 3, ie the mass element 7 in the closed position keep. The closure 4 consists essentially of a sealing seat 16 and a sealing element 15, the sealing seat 16 being arranged at a suitable point on the wall of the channel 12 pointing upwards, the sealing element 15 sealing the mass element 7 vacuum tightly.

the 2 shows a schematic cross-sectional representation of the projectile 2, in which the mass element 7 has released the closure 4, consisting of a sealing seat 16 and a sealing element 15, for the cavity 3. The mass element 7 has a predetermined weight which, due to its inertia and due to the air pressure p in the barrel of the gun when the propellant charge 10 is fired, briefly opens the breech 4 in order to suck in the amount of air in the barrel of the gun through the channel 12, as a result of which in a certain area in front of the projectile 2, the air pressure is at least reduced, thereby increasing the acceleration of the projectile 2 in the course of the firearm. As a result of the short-term drop in air pressure in the barrel of the gun, the muzzle velocity of the projectile 2 at the end of the gun's barrel also increases. In addition, as a result of the burning of the propellant charge, the bang spreads at a different speed and thus with a reduced intensity.

the 3 shows a schematic cross-section parallel to the longitudinal axis of the projectile 1' of a further exemplary embodiment of a projectile 2' with a sealed, closed cavity 3 through which a mass element 7', which is designed as an elongate bolt, protrudes. The material from which the bolt is made is in principle optional and may, for example, consist of a suitable steel or a suitable ceramic or plastics material. The elongated bolt 7 'is on in the present embodiment upper end of at least one slot 18 passes through. Instead of a long hole, other solutions can of course also be used, for example a notch in the surface of the bolt 7'. The bolt 7' protrudes through the entire cavity 3 and ends at the lower end 19 of the projectile 2. Furthermore, the bolt 7' is guided through a second cavity 3' in which a spring element 8 is arranged around the bolt. The upper end of the spring element 8 frictionally contacts the upper wall of the cavity 3' and its lower end frictionally engages a shoulder 20 on the elongated bolt 7'. In the lower part of the projectile 2, the bolt is guided through a shank 21 communicating with the cavity 3'. In order to be able to evacuate the cavity 3, a sealing element 15 is arranged in the area of the lower end of the cavity 3 and in the area of the upper end of the cavity 3, which seals the cavity 3 in a vacuum-tight manner. Other sealing elements for sealing the cavity 3 which tear or break after use of the projectile are also suitable. It is important that the cavity 3 is evacuated until the projectile 1 is fired. The specific weight of the elongated bolt 7' together with the spring element 8 should be selected in such a way that it approximately compensates for the weight loss of the project target 2 as a result of the cavities 3, 3', 12 and 21 incorporated. The outer shape of the projectile 2 can of course remain unchanged compared to a normal projectile. Because of the strong mechanical stresses on the elongated mass element 7' when the propellant charge 10 is fired as a result of the spin of the projectile, a support element 23 is arranged in the present exemplary embodiment in the central region of the cavity 3, which absorbs bending forces, for example.

the 4 shows a schematic cross-section of the project target 2 ' 3 , in which the mass element 7 'is in a position in which the cavity 3 is open. In this embodiment, the projectile 2' 3 the cavity 3 is briefly opened as a result of the firing of the projectile 2'. The cavity 3 is opened by longitudinal displacement of the bolt 7' towards the tip of the projectile 2', which creates a connection between the space in the barrel of the firearm and the cavity 3 due to the oblong hole 18 as a result of the displacement of the bolt 7'. The displacement of the bolt 7' in the longitudinal direction is caused by the fact that when the propellant charge 10 is fired in the sleeve 9 of the projectile 1, an enormous gas pressure is built up, which acts on the stamping surface 22 of the bolt 7' and pushes the bolt against the spring force of the spring element 8 shifts longitudinally upwards in this illustration. When the cavity 3 is opened, the vacuum sucks part of the air quantities out of the barrel of the gun, so that the air pressure inside the barrel of the gun is reduced. This gives the projectile 2' a higher acceleration and, at the end of the barrel, a higher muzzle velocity.

the 5 shows the schematic cross section of a further embodiment of the projectile 2 in the closed state of the cavity 3', through which the mass element 7' passes and projects into a guide shaft 3". A compression spring element 8 is arranged in the lower part of the guide shaft 3", which exerts a force exerts the mass element 7' and thus also seals the closure 4 on the channel 12 in an airtight manner. In order to improve the sealing of the cavity 3', at least one sealing element 17, which can be designed as an O-ring, is arranged on the mass element 7' just below the closure 4, which against the wall of the shaft 3" above and below the cavity 3 Arranged at the upper end of the mass element 7' is a pin 14 which almost completely fills the volume of the channel 12 in the closed state of the cavity 3'.

the 6 Figure 12 shows the schematic cross-section of the same projectile 2 5 , in which the mass element 7' is in a position in which the cavity 3' is open. The mass element 7' leads through the profiled cavity 3' and ends in a guide shaft 3". This illustration shows a snapshot of the projectile 2 after the propellant gas of the propellant charge 10 has pushed the projectile 2 out of the case 9 of the projectile 1 and accelerated it enormously. As a result of the inertia of the mass element 7' and the air pressure p in the barrel of the firearm, a counterforce is exerted on the spring element 8, which compresses the spring element 8 and thus opens the closure 4 in the area of the channel 12, so that the vacuum in the cavity 3' is broken and air masses from the barrel of the firearm can penetrate into the cavity 3. In this exemplary embodiment, the air pressure is at least reduced during the firing of the projectile 2, so that the projectile 2 is accelerated.

• S1: Zünden der Treibladung 10 mit Zünder 11;
• S2: Druckentwicklung in der Hülse 9 des Geschosses 1;
• S3: Beschleunigen des Projektils 2 im Lauf der Schusswaffe;
• S4: Öffnen des Verschlusses 4 der evakuierten Hohlkammer 3 infolge der Trägheit der Masse des Masseelements 7 und des Luftdrucks p im Lauf der Schußwaffe;
• S5: Ansaugen eines Teils der Luftmassen im Lauf der Schußwaffe;
• S6: Minderung des Luftdrucks im Lauf der Schußwaffe;
• S7: Verlängern der Reichweite des Projektils 2.

the 7 shows a block diagram of the process sequence from the ignition of the propellant charge 10 of a projectile 1 until the muzzle velocity of the projectile 2 is reached in the end region of the barrel of the firearm. The individual process steps are as follows:

• S1: ignition of the propellant charge 10 with igniter 11;
• S2: pressure development in the sleeve 9 of the projectile 1;
• S3: Accelerating the projectile 2 in the barrel of the gun;
• S4: opening of the closure 4 of the evacuated hollow chamber 3 due to the inertia of the mass of the mass element 7 and the air pressure p in the barrel of the firearm;
• S5: sucking in part of the air masses in the barrel of the firearm;
• S6: reduction in air pressure in the barrel of the firearm;
• S7: Extending the range of the projectile 2.

In summary, it can be stated that the present invention discloses a method with a projectile 1 with a projectile 2 in various exemplary embodiments, with which the air pressure p in the barrel of a firearm is reduced during the firing process of a propellant charge 10 of the projectile 1 . The air pressure reduction is generated by a vacuum cavity 3 in the projectile 2 of the projectile 1, which is opened when the propellant charge 10 of the projectile 1 is fired. As a result of the method according to the invention for increasing the acceleration of the projectile 2 of the projectile 1, there are a number of advantages for the user of the method and the projectile 1 connected thereto associated projectile aiming accuracy 2. Also, firearm recoil is reduced. In addition, neither the firearm nor the projectile 1 needs to be changed in its external shape.

QUOTES INCLUDED IN DESCRIPTION

This list of the 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

• DE 1147143 [0003]
• EP 2245419 B1 [0004]

Claims (14)

Projectile (1) with a projectile (2), characterized in that the projectile (2) has a cavity (3) which is evacuated. floor after claim 1 , characterized in that the cavity (3) at least one closure (4) is arranged, which closes the cavity (3) airtight. floor after claim 1 and 2 , characterized in that the closure (4) has at least one sealing element (5) which is arranged between a mass element (7) and the cavity (3). Projectile according to one of the preceding claims, characterized in that a spring element (8) is arranged below the mass element (7). Projectile according to one of the preceding claims, characterized in that the projectile (2) is arranged in a sleeve (9) above a propellant charge (10). Projectile according to one of the preceding claims, characterized in that an ignition element (11) is arranged in the propellant charge (10) in the lower region of the case (9). Projectile according to one of the preceding claims, characterized in that the projectile (2) has at least one channel (12) which connects the cavity (3) with the atmosphere. floor after claim 7 , characterized in that the at least one channel (12) is shaped in cross section parallel to the longitudinal axis of the projectile (1), for example cylindrical or funnel-shaped or truncated cone-shaped or curved or curved. Projectile according to one of the preceding claims, characterized in that a spigot (14) is arranged on the mass element (7) which at least partially fills the at least one channel (12) in the closed state of the cavity (3). Projectile according to one of the preceding claims, characterized in that the cavity (3) is profiled on the side walls in cross-section parallel to the longitudinal axis of the projectile (1). Projectile according to one of the preceding claims, characterized in that the mass element (7) creates a connection between the mass element (7) and a wall of the cavity (3) at a suitable point with at least one sealing element (15). Projectile according to one of the preceding claims, characterized in that the mass element (7) is supported by at least one support element (23) on the wall of the cavity (3). Method for increasing the muzzle velocity of a projectile (2) of a projectile (1) when the projectile (2) is fired from a firearm in the period from the firing of the shot to the exit of the projectile (2) from the barrel of the firearm, characterized in that the Cavity (3) in the projectile (2) of the projectile (1) is evacuated and hermetically sealed before the projectile (2) is fired. procedure after Claim 13 , characterized in that the cavity (3) in the projectile (2) of the projectile (1) is opened after the burning of a propellant charge (10).

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