FI126940B - Bullet and method for expanding the bullet by fungi - Google Patents

Description

Bullet and method for expanding the bullet by fungi

Background of the Invention

The present invention relates to a bullet according to the preamble of claim 1 and to a method according to the preamble of claim 6 for providing a bullet expansion upon impact. Such a bullet is particularly well suited for large game hunting, where bullet expansion is important, but where excessive bullet fragmentation is desired.

As the pointed bullet advances in the target, for example, in the muscle mass of the game, it predisposes the tissue. This bullet-induced tissue migration time corresponds to the time at which the bullet, at its propagation speed, travels the distance from the bullet tip to the largest bullet outer diameter. The shorter this transition time, the greater the pressure wave bullet generates, and the larger the bullet following the bullet and the resulting trauma. In practice, this means that the higher bullet flight speed increases the trauma caused by the game being hunted, since the time it takes for the tissue to migrate decreases as the flight speed increases. On the other hand, the sharper tip of the bullet reduces trauma because the time it takes for the tissue to migrate increases as the tip is held.

The vacuum bubble created by the bullet also makes its progress unstable because the vacuum bubble prevents the tissue mass it pierces from supporting the bullet at the sides. In addition, the center of gravity of the bullet is in its forward direction at the backside of its center point, whereby the deviation of the bullet from its direction of travel produces two components of force that cancel out the gyratory force caused by the axial rotation of the bullet. The non-directional bullet portion of the bullet will be pressurized by the surrounding tissue mass while the bullet center of gravity torque rises. As a result, the bullet rotates about its longitudinal axis, resulting in an unpredictable direction of travel and very little penetration.

In order to increase the trauma following a hit, it is known per se to use part-shell or solid-state strongly expanding - so-called mushrooming - bullets for hunting. This is even in line with the hunting laws and regulations of many countries. Such a mushrooming bullet is intended to provide a diameter significantly greater than the caliber of the bullet itself, which would cause a larger pressure wave and vacuum bubble than the original pointed bullet and consequently greater trauma. In this way, bullet killing power can be significantly increased. The killing effect of a fungal bullet increases for two reasons in particular. On the other hand, the transition time of the tissue becomes shorter as the bullet head is shaped into a semicircular planar surface. On the other hand, the surface of the bullet facing the tissue is larger, resulting in a larger pressure wave. An embodiment of such a bullet is disclosed in EP1355119. However, the use of these prior art bullets has significant disadvantages. Such highly mushroomed bullets have had varying modifications that depend on the rate of hit and the location of the hit. As a result, the bullet can penetrate the object without opening or over-opening and even break. Such a bullet also produces a very strong pressure wave, resulting in tissue damage to the target surface and very limited permeability as a result of the rate drop. As a rule, the bullet will cause severe damage to parts of the body located in the vicinity of the game. These bullet damage, in turn, results in some of the game being dumped being unfit for consumption, either due to deformation or to bullet accumulation.

Attempts have been made to remedy the above problems by using plane-headed bullets or by hit-and-run bullets. One such bullet is disclosed in US 6,694,888. However, such projectile decomposing bullets require a high firing rate when firing, in order to be certain of their decay. The result is flesh damage similar to the fungal bullets described above, as the bullet momentarily opens to the same shape as these current fungal bullets.

However, some of the bullets made to the level head are good in performance. However, these bullets have very poor outdoor ballistics and are only suitable for folding weapons, that is, they do not carry any projectile weapons at all.

Brief Description of the Invention

It is therefore an object of the invention to provide a method of expanding the bullet and implementing a bullet such that the above problems can be significantly reduced. This object is achieved in that the bullet and the method for expanding the bullet according to the present invention have the characteristics defined in the claims. More specifically, this bullet according to the invention is essentially characterized by what is stated in the characterizing part of claim 1. The method according to the invention, in turn, is essentially characterized by what is stated in the characterizing part of claim 6.

Preferred embodiments of the invention are claimed in the dependent claims.

The basic idea of the invention is to provide a cylindrical, closed-ended and, as a result of a hit, a substantially planar bullet, which however has a much lower mushroom fungus compared to previous bullets. Such a substantially flat-headed or slightly concave bullet provides the shortest possible tissue mass transfer time in the target animal due to the formation of a substantially planar surface at the tip of the bullet. A planar or slightly concave bullet creates a strong pressure wave as it progresses through the tissue mass. At the same time, the low tip area of the bullet facing the tissue mass leads to low bullet propagation resistance and high permeability. Such a bullet according to the invention displaces tissue mass very rapidly, whereby it is most strongly affected by a strong pressure wave in fluid-containing tissues such as the lungs. With the vacuum bubble formed by the bullet being smaller in muscle tissue, tissue damage in muscle mass is also smaller than before.

The present bullet achieves better stability because the shape of the bullet face is symmetrical with planes because, unlike before, the center of gravity is substantially at the center of the bullet. In addition, the symmetry of the face surface only reduces the pivoting forces acting on the bullet as the bullet encounter angle changes, so that the gyratory force caused by rotation is not reversed. The end result is a straightforward deep penetration with no change in direction.

Based on the experiments performed, it has been found that the so-called solid bullet can be successfully replaced by the only slightly mushroomed solid bullet according to the invention, without losing its bullet killing effect. By replacing the powerful meat-destroying cavitation effect of the large fungus of known bullets with a controlled pressure wave, it is possible to successfully minimize the otherwise overly common flesh losses of hunting. This has resulted in a bullet such that a single weapon and bullet can shoot such a small deer without breaking it to be inedible that it would be a dangerous game for Africa, provided the caliber used is sufficient for the purpose. At the same time, the bullet is designed to sufficiently comply with Nordic hunting law.

Other advantages of the invention are set forth below when specific embodiments of the invention have been described in more detail.

BRIEF DESCRIPTION OF THE DRAWINGS

In the following, some preferred embodiments of the invention will be described in more detail with reference to the accompanying drawing, in which Fig. 1 is a schematic representation of vacuum bubbles caused by a highly mushroomed and projectile bullet, Fig. 2 illustrates an infiltration of a bullet according to an embodiment of the invention; Figure 4 is a partial and schematic sectional view of the bullet of Figure 3, Figure 5 is another schematic cross-sectional view of the bullet tip of Figure 3, and Figures 6 to 9 show the operation of the bullet of the invention in the following situation.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

In the present figures, the bullet and the method for expanding the bullet are not shown on a scale, but are schematic, illustrating the basic structure and operation of preferred embodiments. In this case, the components designated by the reference numerals in the accompanying figures correspond to the components designated by the reference numerals in this specification.

The design of the present bullet has been based on the creation of a bullet 1 that combines good terminal ballistics, small casualties regardless of hit, good supply reliability in all weapons, including semi-automatic, and sufficient external ballistics and launching speeds to achieve at least 300 m firing.

The above objects have been accomplished with a solid material bullet that does not have a loose plastic tip that could bend, detach or cause false weight. The bullet 1 also has an elongated, smooth tip 2 that is small enough to achieve gun delivery reliability and good outdoor ballistics.

The intended objectives have been achieved by providing an opening um-shaped bullet 1 which, when hit, creates a slightly concave or substantially planar tip structure of up to 1.2 x caliber to cause a shock wave. Experiments carried out have shown that a favorable result is obtained with a bullet which opens to a size of 0.9-1.2 x caliber. A particularly advantageous result is when the bullet opens to a size of 1.1 to 1.15 x caliber.

The behavior of the bullet 1 of Figures 1 and 2 requires a slight, but not excessive, fungus of the bullet tip 2. When the caliber is large enough, the desired amount of sponge is obtained by providing a bulge 4 with a diameter of substantially equal diameter parallel to the central axis 3 of the bullet at the tip of the bullet. Figure 1 shows the operation of a highly mushroomed bullet according to the state of the art with a broken line. The intact line, in turn, illustrates the operation of a bullet with a reduced fungal fungus of the present solution.

When the bullet 1 hits its target, the pressure F exerted thereon is adapted to influence the sponge 2 fungus, whereby the tip preferably reaches a size which is at most 1.2 x the diameter of the bullet body. As the initial velocities increase and the caliber decreases, a situation is encountered in which the tip 2 of the bullet 1 is subjected to very high stress, and the sponge 5 eventually formed tends to fragment. Such an event is illustrated in the accompanying Figures 6-8. In such a case, the diameter of the remaining bullet end is too small and too forward to keep the bullet stable. 8 and 9, such a fungus is provided such that the cavity 4 in the bullet body is preferably formed by two cavity portions 6 and 7. In a preferred embodiment, these cavities are provided, for example, by successive borings. An example of such a bullet is shown in Figure 4.

The cavity at the tip of the bullet is clearly smaller in total depth Li than the caliber of the bullet, being up to 70% of the caliber for small caliber and about 40% of the caliber for large caliber. It has also been found that when the cavity 4 is formed from a plurality of cavity portions 6 and 7, it is preferable to arrange the last cavity to be significantly shorter than the previous cavity. Thus, by making the diameter of each cavity portion 6 and 7 smaller by the distance from the outermost tip, it is possible to control the fragmentation of the resulting sponge 5. Thus, for example, the bullet 1 of Figure 4 behaves as shown in Figures 6-9. In this case the first mushrooming occurs as soon as it hits its target. The sponging is effected by a tissue mass which is exerted by force F on the bulb cavity 4. As the bullet sinks into the tissue cavity, it naturally fungi at the point where the material thicknesses of the tip 2 are lowest, i.e. in the step 8 where two successive portions 6 In the sponging, both the deflection of the material surrounding the cavity portion 6 and the elongation of the material carrier 9 at the step-like position 8 are compared, Figure 7 is also assisted by sufficient difference in diameter d between these sections when using successive cavity portions. When the difference is too small, successive mushrooming does not occur, and the mushrooming immediately extends to the entire depth L2 of the cavity. Thus, in order to reliably achieve sequential fungi, d2 «di.

As the velocity of the bullet slightly decreases as the bullet tip expands and the pressure exerts on it, the first sponge ruptures from the tip, compare Figure 8. The effect of tissue mass F is immediately exerted on the next tip cavity portion 7, spreading to a desired tip diameter up to 1.2x , compare Figures 8 and 9.

Thus, at very high output velocities and / or low calibers, these can be arranged from the cavity 5 to the tip 2 of the bullet 1 several times in succession. In this way, the fungus is fragmented at the tip of the bullet at a time, with the velocity of the bullet steadily decreasing as in Figure 2. At the same time, a uniform pressure wave can be maintained, which, as shown in Figure 1, has a more controlled distribution over the surrounding tissue mass.

Fragmentation of the sponge 5 provided at the tip 2 of the bullet 1 may also be facilitated by providing the bullet tip with the shoulder 10 of Figure 5 or any other discontinuity of the bullet surface arc at substantially the border of each successive portion of the cavity. Such a shoulder reduces the material strength of the site and naturally contributes to the fragmentation of the sponge. Such a shoulder formed on the outer surface of the tip according to Fig. 5 may also be replaced by a groove-like material cap 9 formed at the bottom of the cavity provided at the tip and / or at the junction of successive cavities.

In the manufacture of the bullet 1 from the solid material, it is advantageous to provide at least two parallel grooves 13 in the shell 12 of the body 11 of the bullet to prevent excessive pressure in the barrel of the launching weapon.

One preferred embodiment of the so-called solid material and thus for the manufacture of the bullet body is brass.

It is to be understood that the foregoing description and the accompanying figures are merely intended to illustrate the present solution. Thus, the solution is not limited to the embodiment set forth above or as defined in the claims, but many variations and modifications thereof will be apparent to those skilled in the art, within the spirit of the appended claims.

Claims (9)

A bullet (1) comprising a solid metal body (11) having a cavity (4) opened at the bullet tip (2) and on the center axis (3) of the bullet, comprising at least two successive portions of the cavity (6, 7). ), the diameter (d1, d2) of each bulb portion (6, 7) is smaller than the preceding bulb, so that the diameter (d1, d2) of the bullet (1) is adapted to the fungus upon contact with the target; the cavity portions (6, 7) are formed such that at a distance from the tip (2), the diameter (d2) of the next cavity portion (7) is clearly smaller than the diameter (d1) of the preceding cavity (6), forming a staggered discontinuity (8) that the successive portions of the cavity (6, 7) have a length where the length (Li) of the cavity portion (6) at the tip (2) is less than 70% of the caliber for small calibers and approximately 40% of the caliber for large calibers substantially larger than the length (L2-Li) of the next cavity portion (7), with the last cavity being substantially shorter than the previous cavity, Li »L2-Li When fungi are used, the tip (2) of the bullet (1) is adapted to achieve a size of , 2 x the diameter of the bullet body (11), and the shape of the tip (2) provided by it which is slightly concave or substantially planar. A bullet (1) according to claim 1, characterized in that the diameter (1) of the bullet (1) upon contact with the target is adapted to reach a size which is at most 1.1 - 1.15 x bullet caliber. The bullet (1) according to claim 1 or 2, characterized in that the tip (2) of the bullet (1) is adapted to sponge at least twice upon impact. Bullet (1) according to Claim 2 or 3, characterized in that the fungus (1) of the bullet (1) has a sponge size of 1.1 to 1.15 x the caliber of the bullet, arranged to take place at the border of each successive cavity portion (6, 7). such that, as the fungus continues to move away from the tip (2), the previous insertion site is arranged to detach from the body (11) of the bullet (1) by fragmentation therefrom. Bullet (1) according to Claim 4, characterized in that a grooved material carrier (9) is provided at the bottom (2) of the bullet (1) and / or at the junction of successive portions (6, 7) of the bullet (4). A method of causing the bullet (1) to expand by contacting a target with a mushroom, the body (11) of the bullet (1) being made of a solid material and opening a cavity (4) on the bullet tip (2) and center bullet axis (3). formed by at least two portions (6, 7) of the cavity, the pressure (F) applied to the tip (2) of the bullet (1) upon contact with the target is directed to the tip cavity (4) where the pressure modifies the diameter of the tip the diameter (d1, d2) of the cavity portion (6, 7) is formed such that it is smaller than the preceding one so that successive portions of the cavity (6, 7) are formed such that the diameter (d2) of the next cavity portion smaller than the diameter (di) of the preceding cavity portion to form a stepped discontinuity (8), characterized in that the successive cavity portions (6, 7) are formed such that at a distance from the tip (2) the length (l2-Li) of the next cavity portion (7) is clearly smaller, Li »l-2-Li, than the length (Li) of the previous lumen portion (6) which is less than 70% of the caliber for small calibers and about 40% for large calibers wherein, upon impact, the tip has a sponge diameter which is up to 1.2x the diameter of the bullet body (11) and gives the tip (2) a shape which is slightly concave or substantially planar. Method according to Claim 6, characterized in that at least two successive mushrooms are allowed to form at the tip (2) of the bullet (1) when it hits the target, such that a first mushroom (5a) is formed at the tip of the bullet. , which due to the high velocity of the bullet is fragmented, wherein the second bulb portion (7) is mushroomed to form a second bulb (5b) up to 1.2x body diameter in order to avoid excessive shortening of the tissue mass transfer time caused by the bullet. A method according to claim 6 or 7, characterized in that a fungus of 1.1 to 1.15 x caliber is obtained at the tip (2) of the bullet (1). Method according to one of Claims 6 to 8, characterized in that the fungus is obtained at the borderline of each successive portion of the cavity (6, 7) so that as the fungus continues to move away from the tip (2), the previous fungal spot is detached from the bullet body. claim