CZ2010782A3 - Method for controlled deformation of jacket-free projectile and deforming projectile - Google Patents

Abstract

The deformation-free shellless bullet consists of a cylindrical bullet body (1) with relief grooves (11) and a front ogival (2) with a cavity (3) into which the cap (4) is inserted. A cavity (3) of approximately cylindrical shape with longitudinal grooves (5) is pointedly shaped into the front part of the partially circularly shaped cavity (6) in which the longitudinal grooves (7) are formed with a partially circular shape. The cap (4) closes the cavity at the point of contact with the front of the circle-shaped cavity (6), at the same time forming the tip of the bullet, which improves the outer ballistic properties of the bullet and at the same time prevents dirt from entering the cavity. Between the lower part of the cap (10) and the front part of the cavity (6) there is a void space (8) into which the cap (4) is partially pushed when the projectile strikes the target without deforming the front part of the projectile and thereby partially disengaging the front part of the cavity (6) with grooves (7) for applying the tissue pressure of the affected target to the front part of the cavity, thereby causing deformation and regular division of the front part of the bullet into a predefined number of regularly deforming parts, the deformation of which increases with increasing force induced by the pressure of the tissue on the gradually increasing area of the front part of the projectile (6) at the passage through the target. The cap (4) is gradually pushed into the opening cavity (3) without affecting the deformation of the front of the bullet.

Description

Method for controlled deformation of sheathless shells and warping bullets

Technical field

The invention relates to a method of controlled deformation of a sheath-free projectile and to a projectile for introducing the method. The bullet is designed mainly for hunting and for special applications where deformation of the bullet is required.

State of the art

For hunting purposes are used sheathless shells with a cavity in the front part covered with a filler made of plastic, which also forms the tip of the missile. The cavity has a smooth cylindrical shape, which in the front part is shaped into a sealing surface between the projectile body and the filler. The shape of the sealing surface is characterized by a conical shape with the sealing surface angle to the longitudinal axis of the projectile in the range of 10 ° to 80 °. preferably about 45 °, or a combination of conical shape with a cylindrical shape parallel to the longitudinal axis of the projectile or a combination of conical shape with a plane surface perpendicular to the longitudinal axis of the projectile - these solutions are described in EP 1 335 119 A1; missile axis with a cylindrical shape parallel to the longitudinal axis of the missile - this solution is described in DE 103 17 404 A1. Initial deformation of the projectile is ensured by pushing the filling means in the manner of a wedge into the cavity and in this way the initial opening of the front part of the projectile occurs. Subsequently, the pressure of the tissue on the wall of the ajar cavity deforms the projectile into the final shape.

The disadvantage of this method is that during the initial deformation of the projectile caused by the pressing of the filling means into the cavity, there is an uncontrolled and irregular deformation of the front part of the projectile, which consequently adversely affects the course of the entire projectile deformation. in a plane perpendicular to the longitudinal axis of the projectile. Tissue pressure as it strikes a target that acts on the irregular area of the deformed front of the missile can cause the missile to have an irregular effect or change the flight path of the missile.

SUMMARY OF THE INVENTION

These disadvantages of this type of missiles are solved and eliminated by a new construction of shell-free missiles with controlled deformation. The invention relates to a method of controlled, predefined deformation of a projectile and to a projectile for implementing the method.

Attached Figure 1 shows a preferred embodiment of the projectile in which the projectile is formed by a base body consisting of a cylindrical body (1) with relief grooves (11) and a front ogival part (2) with a cavity (3) into which the cap is inserted. (4), which closes the cavity at the point of contact with the front of the cavity (6) in the shape of a circle (9) and at the same time creates a bullet tip which improves the outer ballistic properties of the bullet while preventing impurities from entering the cavity. An unfilled space (8) is formed between the bottom of the cap (10) and the front of the cavity (6). A preferred cavity is formed by an approximately cylindrical portion (3) having a diameter of from 2 mm to 5 mm, which in the front portion (6) is formed into a partially circular shape (R1) formed by a single

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or several interconnected circles with a radius of 1 mm to 5 mm. wherein in the wall of the cavity (3) are formed longitudinal grooves (5) with a depth of 0.2 mm to 1.0 mm, parallel to the longitudinal axis of the projectile, extending approximately 2 mm from the bottom of the cavity towards the front of the cavity (6). The grooves (5) adjoin the front of the bullet (6) to the grooves (7). which are formed into a partially circular shape _(R2) formed by one or a number of interconnected circles with a radius from 1 mm to 5 mm with a depth of 0.2 mm to 1.0 mm and continue up to the outer contour of the projectile. The number of grooves in the cavity sc ranges, for practical use, from 3 to 8 grooves, which are regularly distributed around the periphery of the cavity. The required, predefined and regular course of the deformation of the missile is ensured by the designed shape of the front part of the cavity with formed grooves shaped into a partially circular (boiling (R 1. R ₂ )). In the preferred cap (4), the lower portion (10) is formed by a flat perpendicular to the longitudinal axis of the projectile up to the outer contour of the projectile.

The projectile body is made by pressing from an alloy of 85% to 95% copper and 5% to 15% zinc and subsequently heat treated by recrystallization annealing to the desired material structure, characterized by the hardness of material HV 2 in the range of 50 to 150. , characterized by the hardness of the material, are determined according to the use of the projectile for hunting of different kinds of game, or for special use conditions. Deformation properties and missile deformation rate decrease with increasing hardness of the material.

The cap that closes the cavity at the front of the projectile and at the same time forms the tip of the projectile is made of soft metal such as aluminum, copper or the like, or their saliva with better deformation characteristics, characterized by less hardness HV 2 than the base projectile.

Attached Figure 2 illustrates a second preferred missile embodiment that differs from that of Figure 1 in the form of a lower portion of the cap (10). In the embodiment of Figure 1, the bottom of the cap (10) is a flat perpendicular to the longitudinal axis of the missile. In the embodiment of Figure 2, the bottom of the cap (10) is formed by a conical surface with an angle α.

The course of missile deformation can be described as follows:

When the missile strikes the target, the cap (4), which closes the cavity and forms the tip of the projectile, is pushed into the unfilled space (8) and because it is made of a softer material than the projectile body does not cause initial deformation of the projectile body. As the cap is pushed into the unfilled space (8), the front of the cavity (6) gradually exposes. shaped into a partially circular shape (R1), which is affected by the tissue of the target to be affected with increasing pressure. Tissue pressure also acts on the grooves (7). shaped into a partially circular shape (R ₂ ) in the front part of the cavity (6), which in their place weakens the wall of the front of the missile. In these grooves, the deformation begins and periodically divided into a predefined number of deforming parts of the missile. As the tissue pressure increases as the target passes through, the bullet cavity gradually opens and continues to divide and reshape the front of the bullet (2) to a final shape characterized by a regular deformed frontal bullet shape with a predefined number of regularly deformed bullet portions. The rate of deformation of the projectile can be unaffected by the recrystallization annealing of the projectile base body, characterized by the hardness of the material, the depth and shape of the grooves on the anterior cavity and in the projectile cavity, and the radius of the partially circular shape of the anterior cavity.

The essence of the solution is evident from the following figures, the proposed solution of the projectile is suitable for cartridges ranging from 5.6 mm to 12.7 mm.

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BRIEF DESCRIPTION OF THE DRAWINGS

Figure 1 shows a first preferred embodiment of a shellless missile with controlled deformation, Figure 2 shows a second preferred embodiment of a shellless missile with controlled deformation, Figure 3 shows the beginning of deformation and division of the front part of the bullet cavity, Figure 4 shows a characteristic regular shape missiles after the deformation (as an example missile with six grooves).

Execution example

Figure 1 sheathless bullet with controlled deformation 7.62 mm

The casing missile with controlled deformation of 7.62 mm caliber is, according to Figure 1, formed by a base body consisting of a cylindrical body (1) with relief grooves (11) and a front ogival part (2) with a cavity (3) into which it is inserted a cap (4) that closes the cavity at the point of contact with the front portion of the cavity (6) in the shape of a circle (9) and at the same time creates a bullet tip which improves the ballistic properties of the bullet while preventing dirt from entering the cavity. The cavity consists of an approximately cylindrical part with a depth of 12 mm and a diameter of 2.5 mm, which in the front part (6) is formed into a partially circular shape (Rj) formed by one circle with a radius of 3 mm. Six longitudinal grooves (5) are formed in the cavity. 60 ° regularly spaced around the perimeter of the cavity with a groove depth of 0.50 mm. which in the front part of the cavity (6) are shaped into a partially circular shape (7) with a radius of 3 mm. An unfilled space (8) is formed between the bottom of the cap (10) and the front of the cavity (6). The basic body of the projectile is recrystallized annealed.

Industrial use

In accordance with this technical solution, the sheath-free missile with controlled deformation can be produced by a conventional method, which is used in the production of missiles, mainly by pressing or chip machining and subsequent heat and surface treatment. The actual laboratory of this projectile is performed on common technological equipment for the laboratory of ball, pistol and revolver cartridges.

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Claims (16)

Patent claims 1. Sheath-free missile with a controlled deformation, consisting of a cylindrical body (I) of a bullet with relief grooves (11) and a front ogival part (2) with a cavity (3). into which a cap (4) is inserted, characterized in that the cavity (3). which is formed by an approximately cylindrical shape with longitudinal grooves (5), is formed at the tip into a front part of a cavity (6) with a partially circular shape, in which longitudinal grooves (7) with a partially circular shape are formed, the cap (4) closes in place of contact with the front part of the cavity (6) in the shape of a circle (9) at the same time creating a tip of sulfur which improves the external ballistic properties of the projectile while preventing dirt from entering the cavity an unfilled space (8) is formed into which, when the missile hits the target, the cap (4) is partially pushed without deforming the front of the projectile and thereby partially releasing the front of the cavity (6) with the grooves (7) under pressure tissue of the affected target to this anterior portion of the cavity, causing deformation to begin and a regular division of the anterior portion missiles to a predetermined number of periodically deforming portions, their deformation increases with increasing force exerted by tissue pressure on a gradually increasing area of the anterior portion of the missile (6) as it passes through the target, the cap (4) gradually pushing into the opening cavity ( 3) without affecting the deformation of the front of the missile. Sheath-free bullet according to claim 1, characterized in that. A blank space (8) is formed between the lower part of the cap (10) and the front part of the cavity (6). Sheath-free bullet according to claim 2, characterized in that the front part of the cavity (6) is formed into a partially circular shape R 1 formed by one or more interconnected circles up to the outer contour of the bullet. Sheath-free bullet according to claim 3, characterized in that the radius of the circle of partially circular shape R 1 is from 1 mm to 5 mm. Sheath-free bullet according to claims 2 and 3, characterized in that in the front part of the cavity (6), spaced longitudinal grooves (7) are formed regularly around the periphery of the cavity. which are formed into a partially circular shape K ₂ formed by one or more interconnected circles up to the outer contour of the projectile, which follow the grooves (5) in the cylindrical part of the cavity (3) up to a distance of approximately 2 mm from the bottom of the cavity. Sheath-free bullet according to claim 5, characterized in that the circle radius of the partially circular shape R2 is from 1 mm to 5 mm. Sheath-free bullet according to claim 5, characterized in that the number of grooves (7) and (5) for practical use ranges from 3 grooves to 8 grooves. Sheath-free bullet according to claim 5, characterized in that the depth of the grooves (7) and (5) ranges from 0.2 mm to 1.0 mm. 9. Sheath-free projectile according to claim 2, characterized in that the depth of the cavity (3) is from 30% to 40% of the total length of the base projectile body. Sheath-free bullet according to claim 2, characterized in that the diameter of the cavity (3) is from 2 mm to 5 mm. Sheath-free bullet according to claim 2, characterized in that the lower part of the cap (10) is formed by a plane perpendicular to the longitudinal axis of the bullet and the angle α is 90 °. Sheath-free bullet according to claim 2, characterized in that the lower part of the cap (10) is formed by a conical surface at an angle α to the longitudinal axis of the bullet. 13. The shell according to claim 12, wherein the magnitude of the angle t1 is from 45 [deg.] To 90 [deg.]. Sheath-free bullet according to claim 2, characterized in that the cover (4) is made of a soft metal such as aluminum, copper or their alloys so as not to affect the bullet's decomposition. 15. The shell according to claim 2, wherein the base body is made of an alloy of 85% to 95% copper and 5 to 15% zinc. 16. Shell according to claim 15, characterized in that the base body of the projectile is recrystallized annealed to the soft structure of the material with a hardness HV 2 = 50 to 150.