DE19930475A1 - Partial decomposition floor - Google Patents

Abstract

The design of a partial fragmentation projectile, especially of its head, substantially influences the deformation and the fragmentation of the projectile. Especially when used as an ammunition for hunting the partial fragmentation projectile must be adapted to the game hunted for in terms of its structure, shape and size. The inventive projectile (1) consists of a jacketless metal body. In the tapered front part (4) of the projectile body (2) a cavity (19) extends centrally in respect of the longitudinal axis (20) of the projectile (1). Said cavity (19) comprises graduated cross-sections (23, 24, 25, 26). The tip (17) of the projectile is configured as a breaking-up ram (3). Said breaking-up ram (3) consists of a head (15) that closes the opening (27) of the cavity and a shaft (16) that extends within the cavity (19).

Description

The invention relates to a partial dismantling floor according to the preamble of first claim.

Partial dismantling bullets are used for hunting. Used for hunting Bullets should both deform and impact on the game disassemble more or less into fragments. Disassembly floors or are known Partial dismantling storeys consisting of a jacket and one or more cores different material hardness exist. The cores are usually lead cores, because the lead, together with other metals, becomes a material with a predeterminable Alloys hardness. It also exhibits due to its high specific weight good ballistic properties. When hitting the target body is on the Pressure applied to the tip of the projectile body. When entering the target body the projectile core is compressed, the yield strength of the material of the shell is exceeded. This creates longitudinal cracks in the Coat that form metal strips, so-called flags, when it bursts open. At the further passage of the projectile through the target body Metal strips lifted from the core and bent backwards curl up and are torn down. Is after a certain depth of penetration when upsetting the The core of the projectile also exceeds the yield strength of its material he split up into splinters. The mantle and the core of the projectile usually shatter into Parts of different sizes.

The dismantling of the projectile continues until either the energy of the Storey is so far degraded that no further chipping of the jacket and Projectile body more done or the disassembly of the projectile body by a defined chicane, for example a second core or a holding groove or Predetermined breaking point, is ended. The so-called residual body usually has one  indefinable residual mass and leads to its passage through the target body further depth effects and a possible committee.

An ideal disassembly of the projectile body and the jacket is only rare and due to the different resistance conditions in the game body never to be achieved in the same way. The speed of the storey dismantling and the entire process of chipping is fundamentally different, each depending on where the hit is located, whether in soft tissues or in hard muscle areas or Bones, and whether it's a strong, resilient or a small, weak piece. Furthermore, the direction of the shot and the resulting The course of the projectile in the wild body has a significant influence on the process of Missile deformation, but above all the impact speed. One floor the head of which is quickly broken down into fragments, enlarged as it penetrates and further Passage through the game body its cross section quickly. With that the Resistance in the game body is greater, the projectile is slowed down more Breakthrough time becomes longer, a larger percentage of the impact energy remains in the Game bodies, which is a great advantage when such a projectile on weak game is shot down. A shot at strong game, on the other hand, requires greater strength of the projectile head, so that it is not deformed too early, but one stronger fragmentation occurs mainly when the projectile body in the Close to the vital organs inside the game body.

From the article "Geschossportrait" in the magazine "Wild und Hund", 1989, Issue 21, Page 38, a cutting floor is known, especially for predators and big game should be suitable. It is a jacket storey with a lead core and a disassembly level.

The object of the present invention is to present a projectile that at Impact on the target body corresponding to the impact speed Disassembled into fragments and a defined residual body of the floor having. Another goal is the exclusion of toxic loads on the target body through the bullet material.  

The task is solved with the help of the characteristic features of the first Claim. Advantageous embodiments of the invention are in the Claimed claims.

The projectile according to the invention consists of a sleeveless metal body with a front part tapering towards the top of the floor and one rear, essentially cylindrical part. In the front, tapering part of the Storey extends in the direction of its longitudinal axis, a cave Cross section gradually narrows. The top of the floor is opened by a Tappet formed that closes the cave entrance. The break-open ram consists of a head that closes the entrance to the cave extending shaft connects. With the projectile according to the invention targeted disassembly achieved. The ram pestle that closes the cave entrance is pressed into the cave when it hits the target body. Since the cave of narrowing in stages starting from its entrance, the tapering part of the Projectile depending on the speed of impact along the steps broken up. Because the edges of the gradations of the cross section are not rounded due to the stress curve in the material, they act like predetermined breaking points and thus favor the disassembly of the projectile body from the entrance of the cave and with it the formation of fragments. The number of gradations of the diameter as well as the height of the tiers gives the number of tiers and thus the size the splinter before. The higher the impact speed, and the greater the number of Steps, the more the floor is disassembled.

The disassembly of the projectile body stops when it hits the projectile body acting energy is no longer sufficient to disassemble. Has the remaining one Residual body still has a sufficiently high kinetic energy, it emerges from the target body and leaves a committee, which leads to increased sweat loss in game leads. This is done by a part of the hunters because of the good traceability of the Welding track viewed as desirable.  

For a gradual disassembly of the projectile body by the ram ram into To achieve splinters of the desired size, the cave in the storey body is in two Areas divided into a first area with graduated diameters and in a second area for receiving the stem of the plunger. In this second The area becomes when and after the projectile hits the target body Shaft of the deforming tappet guided so that this in the direction retracts the longitudinal axis of the projectile body. Also, the length of the Shaft and the length of the second area of the cave matched. The free path that the shaft can travel in the second part of the cave determines when the break-open pestle and thus the disassembly of the projectile body into fragments is stopped.

The advantage of a double-conical shape of the head of the break-open ram is in that the part of the head facing away from the shaft, which closes the cave, due to its taper improves the aerodynamics of the projectile body. The one The conical part of the head facing the shaft acts like a wedge that holds the Cave wall, the front, tapered part of the projectile body expands, pushes apart and tears into splinters.

According to the invention, the plunger is made of a softer material than the projectile body. During the projectile body, for example, from hard Synthetic resins and metals such as copper, iron, tungsten, titanium, vanadium and the Alloys of these metals can exist, are the materials of the break-open ram softer, for example tin, zinc, aluminum and plastics, for example made of Polymers or polycarbonate. The advantage is that if it hits the The target body deforms the head of the break-open plunger faster than that the material of the projectile body. A soft material does not shatter, but rather deforms and presses on the brittle due to its plastic deformation Material of the projectile body, which is thereby forced to tear and splinter becomes.  

The length of the cave, the number of decomposition levels, their respective lengths, the Gradations of the diameter, the head shape of the ram and the length of the shaft can depend on the nature of the target body and the achievable Impact speed of the projectile can be matched and thus more advantageous Sufficient to form a defined projectile residual body and splinters Contribute size. Since the impact speed is a determining factor for the Disassembly of a bullet into fragments must be the construction of the bullet be such that the splitting into splinters is in the right place in the animal body takes place, for example earlier with roe deer, later with strong hoofed game. That has with the result that, for example, in the case of projectiles designed for strong hoofed game are provided, the number of decomposition levels is lower and the Diameter steps are larger than, for example, those provided for roe deer Shot. There can be a finer gradation of the diameter as well as a larger one Number of decomposition levels for an earlier decomposition and thus for the desired one Effect of the projectile.

The shape of the head of the break-open ram also influences the disassembly behavior of the projectile body. For example, one drilled into the top of the projectile Hole more or less accelerates the deformation of the projectile head and thus the release of energy into the game body, the so-called projectile effect, what The lower the impact speed of the projectile, the more advantageous it is. If the tip of the head has a recess, be it a conical one Funnel or a trough-shaped depression, the premature expansion of the Head of the break-open plunger, which tears open the tapered Part of the projectile body leads in the longitudinal direction.

If the tip of the head of the break-open ram has a flat end face, leads this hits a strong deformation of the head when hitting the target body and thus to an abrupt widening of the diameter of the ram and as a result to an immediately beginning fragmentation of the tapering part of the floor.  

If the tip of the head of the break-open plunger has no recess and runs on the other hand, if it is pointed or rounded, it will initially be easier in the target body penetrate and only due to the increasing pressure on the head the required Achieve widening in diameter to disassemble the projectile body.

The shape of the tip of the head of the break-open ram should on the one hand be the projectile give good aerodynamic properties, but on the other hand also to one Requirements for the storey sufficient floor dismantling contribute. Out for this reason the cone angle of the tip of the head is approximately between 35 ° and 65 °. A cone angle of approximately 40 ° has proven to be advantageous.

The cone angle of the shaft part of the head also has a significant portion the disassembly behavior of the projectile body. If the cone angle is too acute, it is Wedge effect of the break-open plunger too low and at high impact speed there is a risk that the pestle is pressed into the cave without the to perform expected disassembly work. However, if the cone angle is too large, the resistance to the break-open plunger is lower Impact speed too high and there is also insufficient disassembly of the projectile body. For this reason, the cone angle on the shaft part of the Head on the gradation of the diameter and the number of diameter steps be coordinated. The cone angle of the shaft part of the head is approximately between 90 ° and 130 °. A cone angle of approximately 120 ° has proven to be advantageous.

In a further advantageous embodiment of the invention, the projectile body can be one Show sharp edge. A sharp edge on the floor ensures a clean Shot in, because the blanket of the game was not torn, but when shot is punched out. The bullet hole, which is about the size of a caliber, already provides when shooting for the wound to provide sweat.

In a further advantageous embodiment of the invention, the projectile body has at least one predetermined breaking point arranged on the circumference. This  The predetermined breaking point is a groove with a on the circumference of the floor sharp notch in the groove base. The predetermined breaking point ensures that the Projectile body for the fact that the splitting stops at this point and thus a defined residual body remains. The predetermined breaking point is usually in the area the second part of the cave, in which the shaft of the ram is guided.

The predetermined breaking point must be arranged in front of the coulter edge. Because to generate the Sharp edges the floor is also provided with a groove, the Sharp edge already disadvantageously as the predetermined breaking point of the projectile act. Since when the projectile enters the target body, the disassembly of the If the bullet only begins, the coulter edge has already passed the ceiling of the game have before the dismantling of the projectile has progressed to the predetermined breaking point.

In a development of the invention is on the cylindrical part of the projectile body at least one relief groove to reduce friction in the barrel arranged. The number of relief grooves depends on the size of the intended residual body. In the case of a residual body that is, for example, a third of the The length of the projectile body is the arrangement of two elastic grooves advantageous.

It is particularly advantageous if the projectile body and the ram tappet are made of consist of a lead-free material. Because lead and its alloys are toxic will be considered, especially the tissue interspersed with lead splinters considered edible to a limited extent. In contrast, are materials according to the invention used for the projectile and the tappet, such as plastic, and the metals copper, tin, zinc, iron, tungsten, titanium, silver, aluminum, tantalum, Vanadium and possible alloys of the metals listed are those in the Tissue-penetrating fragments are harmless and do not cause any toxic Contamination of the tissue.

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

Fig. 1 shows an inventive partial fragmentation bullet with break-up plunger whose head tip is rounded,

Fig. 2 shows a break-up plunger with a conical recess in the top of the head,

Fig. 3 shows a break-open plunger, the tip of the head having a trough-shaped recess and

Fig. 4 shows a break-open plunger with a flat end face of the head.

In Fig. 1, a partial dismantling projectile 1 according to the invention is shown in section on a greatly enlarged scale, which is composed of a projectile body 2 and a ram tappet 3 . The projectile body 2 consists of a front, tapering part 4 , an adjoining substantially cylindrical part 5 and a short rear cone extension 6 . The tapering part 4 ends in a sharp edge 7 . It is created by a circumferential puncture in the floor body. The bottom of the groove 8 is rounded. As seen in the direction of flight 9 of the floor 1 , the wall 10 rises at an angle. The wall 11, however, runs perpendicular to the outer contour of the floor 1 . This creates the sharp edge 7 , the sharp edge. When it passes through the deer ceiling, it creates a clean bullet hole with a clearly defined edge.

The predetermined breaking point 12 lies in front of the coulter edge 7 , seen in the direction of flight 9 . It is an annular puncture in the projectile body 2 with a pointed base. The predetermined breaking point 12 is intended to prevent further splintering of the projectile body 2 and form a defined residual body, which essentially consists of the cylindrical part 5 with the short rear cone extension 6 .

The cylindrical part 5 of the projectile body 2 has two relief grooves 14 for reducing the friction in the weapon barrel.

The break-open ram 3 is composed of a head 15 and an adjoining shaft 16 . The shaft 16 is cylindrical in the present exemplary embodiment. The head 15 is divided into two conical halves, the tip 17 pointing in the direction of flight 9 and a conical part 18 facing the shaft 16 . In the present exemplary embodiment, the tip 17 has a rounded shape 36 . The tip 17 of the projectile 1 is thus formed by the head 15 of the break-open plunger 3 . The cone angle 37 of the tip 17 is 40 ° in the present exemplary embodiment.

The head 15 closes a cavity 19 in the front, tapering part 4 of the projectile body 2 . This cavity 19 extends centrally to the longitudinal axis 20 of the projectile 2 . It is divided into two areas 21 and 22 , the first area 21 having stepped diameter areas and the second area 22 being a cylindrical bore for receiving the cylindrically shaped shaft 16 of the break-open ram 3 .

In the present exemplary embodiment, the first region 21 of the cavity 19 has four stepped diameter regions 23 , 24 , 25 and 26 . The gradations are the same length and decrease in diameter by the same amount. The gradations can also be of different lengths and the decrease in diameter can also take place in steps of different sizes. The entrance 27 to the cavity 19 opens conically and comprises approximately half the length of the first stepped diameter region 23 . The cave entrance 27 is closed by the conical part 18 of the head 15 of the ram tappet 3 . The cone angle 28 of the conical part 18 of the head 15 closing the cave entrance 27 is an obtuse angle, here 120 ° in contrast to the acute cone angle 29 of the cave entrance 27 , which is 50 ° in the present example.

If the projectile 1 strikes a target body, the tip 17 of the break-open plunger 3 first penetrates the target body. The more acute the cone angle 37 of the tip 17 , the deeper it penetrates the target body before its deformation begins. The conical part 18 of the head 15 of the break-open plunger 3 acts like a wedge. The pressure that builds up on the break-open plunger 3 pushes the break-open plunger 3 into the cavity 19 . The cave wall, which is still thin in the area of the cave entrance 27 , is expanded. If the material's yield strength is exceeded, the material will tear open lengthways due to physical laws.

As soon as the conical part 18 penetrates an edge 3 of a stepped diameter range 23 to 26 , the pressure on the material is suddenly increased. The sharp-edged paragraphs 31 act like predetermined breaking points. The strips of the bursting projectile body 2 are bent and at the latest when the last graduated diameter range 26 is reached, the tapering part 4 of the projectile body 2 is broken down into fragments due to the predetermined breaking point 12 . This leaves a residual body of defined mass, which is composed of the predetermined breaking point 12 downwards from the cylindrical part 5 and the short rear cone extension 6 . The remaining body of the projectile should penetrate even deeper into the target body and penetrate it, possibly with an exit on the other side of the game, so that a rejection arises, even if it already penetrates parts of the skeleton on the way through the animal body Has.

The extent of disassembly of the projectile body can be controlled by the length of the shaft 16 . The shaft 16 not only serves to guide the break-open plunger 3 by being guided in the second region 22 of the cavity 19 , but also determines the point in time when it hits the bottom 32 of the bore 22 . From this point on, the ram tappet 3 can no longer be moved, but only plastically deformed. It only flakes off splinters until the end of its deformation.

The FIGS. 2 to 4 show further possible embodiments of a break-up plunger.

The shape of the tip 17 of the head 15 of a break-open plunger 3 , which closes the cavity of the projectile body, determines the influence on the intended disassembly of the projectile body. The cone angle 37 of the tips 17 is the same size in the three further exemplary embodiments and is also 40 °. In the shape of the tip 17 shown in FIG. 1, the projectile will first penetrate into the target body and only then will the disassembly be initiated due to the deformation of the projectile tip 17 which occurs.

The tip 17 of the break-open ram 3 in FIG. 2 has a conical recess which is arranged centrally to the longitudinal axis 20 . Here, when the head 15 strikes a target body, the material is torn open. The disassembly of the projectile is thus initiated much earlier than is the case, for example, according to the exemplary embodiment in FIG. 1.

In one trough-shaped recess 34, as provided in the embodiment of Fig. 3 in the tip 17 of the break-up the plunger 3, the decomposition will run smoothly than with a plunger according to the embodiment of FIG. 2.

The tip 17 of the break-open ram 3 according to the exemplary embodiment in FIG. 4 is shaped substantially differently . There, the tip 17 of the head 15 is a flat end face 35 . When this flat end face 35 hits the target body, a very strong compression of the head 15 is initiated. In this embodiment, the disassembly of the projectile body is essentially caused by the material mass of the ram tappet 3 that compresses.

In the exemplary embodiments of a ram tappet shown in FIGS. 2 to 4, the projectile will be disassembled much earlier than in the embodiment according to FIG. 1. This can be advantageous, for example, in game, in which a low penetration depth is desired and a penetration should be avoided, for example with roe deer. The disassembly of the projectile body occurs shortly after the projectile enters the target body.

Claims (18)

1. partial dismantling projectile with a tapering to the top of the projectile front part and a rear, essentially cylindrical part, characterized in that the projectile ( 1 ) consists of a shell-less metal body that in the tapered, front part ( 4 ) of the projectile body ( 2 ) a cave ( 19 ) centrally to the longitudinal axis ( 20 ) of the projectile ( 1 ) extends that the cave ( 19 ) narrows in stepped diameter ranges ( 23 , 24 , 25 , 26 ) starting from its entrance ( 27 ) that a break-open plunger ( 3 ) forms the projectile tip ( 17 ) and that the break-open plunger ( 3 ) consists of a head ( 15 ) closing the cave entrance ( 27 ) and a shaft ( 16 ) extending into the cave ( 19 ). 2. Partial dismantling floor according to claim 1, characterized in that the cave ( 19 ) is divided into two areas ( 21 , 22 ), in a first area ( 21 ) with stepped diameters ( 23 , 24 , 25 , 26 ) and a second area ( 22 ) for receiving the shaft ( 16 ) of the break-open plunger ( 3 ). 3. Partial decomposition projectile according to one of claims 1 or 2, characterized in that the edges ( 30 ) and shoulders ( 31 ) of the stepped diameter regions ( 23 , 24 , 25 , 26 ) of the cave ( 19 ) are designed as predetermined breaking points. 4. Partial decomposition projectile according to one of claims 1 to 3, characterized in that the head ( 15 ) of the break-open plunger ( 3 ) has a double conical shape ( 17 , 18 ). 5. Partial decomposition projectile according to one of claims 1 to 4, characterized in that the break-open plunger ( 3 ) consists of a softer material than the projectile body ( 2 ). 6. Partial decomposition projectile according to one of claims 1 to 5, characterized in that the length of the cavity ( 19 ), the number of graded diameter ranges ( 23 , 24 , 25 , 26 ) as the decomposition levels, the gradation to form a defined projectile residual body and sufficient fragment size the diameter within the disassembly stages ( 23 , 24 , 25 , 26 ), the shape of the head ( 15 ) of the break-open plunger ( 3 ) and the length of the shaft ( 16 ) on the nature of the target body and the achievable impact velocity of the projectile ( 1 ) are tunable. 7. Partial disassembly projectile according to one of claims 1 to 6, characterized in that the head ( 15 ) of the break-open plunger ( 3 ) has a shape which influences the disassembling behavior of the projectile body ( 2 ). 8. Partial dismantling projectile according to claim 7, characterized in that the tip ( 17 ) of the head ( 15 ) of the break-open plunger ( 3 ) has a conical ( 33 ) or trough-like ( 34 ) recess. 9. Partial dismantling projectile according to claim 7, characterized in that the tip ( 17 ) of the head ( 15 ) of the break-open ram ( 3 ) has a flat end face ( 35 ). 10. Partial dismantling projectile according to claim 7, characterized in that the tip ( 17 ) of the head ( 15 ) of the break-open ram ( 3 ) has a rounded shape ( 36 ). 11. Partial dismantling projectile according to one of claims 1 to 10, characterized in that the cone angle ( 37 ) of the tip ( 17 ) of the head ( 15 ) of the break-open ram ( 3 ) between about 35 ° and 60 °, preferably at about 40 ° lies. 12. Partial dismantling projectile according to one of claims 1 to 11, characterized in that the cone angle ( 28 ) of the shaft ( 16 ) facing part ( 18 ) of the head ( 15 ) of the break-open ram ( 3 ) between about 90 ° and 130 ° , is preferably about 120 °. 13. Partial decomposition projectile according to one of claims 1 to 12, characterized in that the projectile body ( 2 ) has a coulter edge ( 7 ). 14. Partial decomposition projectile according to one of claims 1 to 13, characterized in that the projectile body ( 2 ) has at least one predetermined breaking point ( 12 ) arranged on the circumference. 15. Partial decomposition projectile according to claim 14, characterized in that the predetermined breaking point ( 12 ) in the direction of movement ( 9 ) of the projectile ( 1 ) is arranged in front of the coulter edge ( 7 ). 16. Partial projectile according to one of claims 1 to 15, characterized in that at least one relief groove ( 14 ) for reducing the friction in the gun barrel is arranged on the cylindrical part ( 5 ) of the projectile body ( 2 ). 17. Partial dismantling projectile according to one of claims 1 to 16, characterized in that the projectile ( 1 ), consisting of the projectile body ( 2 ) and the break-open plunger ( 3 ), consists of lead-free materials. 18. Partial decomposition projectile according to claim 17, characterized in that the projectile ( 1 ) consists in particular of the following materials: plastics, in particular biodegradable, synthetic resins, and as metallic materials copper, tin, zinc, iron, tungsten, titanium, silver, aluminum, Tantalum and vanadium as well as possible alloys of these metals.