FI83137C - Projectile. - Google Patents

Description

1 83137

The present invention relates to an ammunition, and more particularly to an ammunition for use in conventional, grooved or non-grooved handguns.

Conventional ammunition for a grooved barrel usually has a lead core and a copper sheath around it that is nominally the same diameter as the groove diameter and is thus slightly over-caliber 10 or compression-fitting to the barrel hole diameter of the weapon in which it is intended to be used. pressed by then through the barrel of the weapon by means of a helical barrel in the barrel. The grooves rotate the bullet to stabilize its trajectory 15, but a significant portion of the energy generated by the pushing explosive in the bullet-containing sleeve is wasted due to friction between the bullet and the grooved barrel caused by the bullet drawing when heat is generated in the barrel. Especially in weapons that fire automatically, the heat generated by the friction caused by bullets passing through the barrel can be a serious problem and cause rapid barrel wear and, in the worst case, bulge or rupture of the barrel.

25 A conventional shotgun body is a hollow, cylindrical lead cup with a domed curved head, but because the shotgun has no groove, the projectile body does not rotate and is accurate only at a distance of about 100 meters or less, partly due to lack of rotation and partly due to due to its streamlined shape, which slows it down quickly.

The prior art with possible background interest comprises the following patents: US-A-4 239 006, US-A-4,083,306, US-A-4,063,511, 35 US-A-4,056,060, US-A -3,427,648, US-A-3,356,029, 2,833,137 US-A-3,311,061, US-A-3,141,412, US-A-3,005,409, US-A-2,996,992, US-A -2,983,224, US-A-2,811,901, US-A-2,638,051, US-A-2,382,152, US-A-2,306,140, FR-A-1,124,740, FR-A-861 167, FR-A-799 933, FR-A-736 690, 5 GB-A-1 541 291, BG-A-107 088 and DE-C-583 098.

Some of these publications show that it is known that an under-caliber rifle projectile is surrounded by a plastic sleeve (sealing or guide sleeve) which is drawn and rotates by means of a barrel groove and in turn transmits a rotational motion to the projectile by tight frictional grip. The disadvantage is that the sleeve material must have a high coefficient of friction so that it can maintain its grip in the event of a corresponding, high friction loss in the barrel of the projectile. A further consequence of this is that the combined weight of the sleeve and the projectile is less than the weight of a conventional projectile of the same size and therefore has a smaller impulse with the same energy. This has the advantage of a smaller recoil of the rifle, but has the disadvantage that an unmodified self-loading rifle, if designed for a conventional cartridge with 20 larger impulses, will not complete its automatic cycle due to the reduced impulse.

Some of these publications show that the use of a plastic sleeve around the tip is known and that the groove of the barrel is limited to the sleeve which transmits rotational movement to the tip when mechanically gripping the tip fins instead of frictional adhesion, and therefore low friction material can be used for the sleeve. friction loss in the barrel. However, one consequence of using a tip is that the combined weight of the sleeve 30 and the tip is very small when compared to a conventional bullet of the same diameter and length, so that a special automatic rifle operating at reduced thrust must be used. A further consequence and problem of all projectiles fired by the sleeve is that since the sleeve and the projectile come out of the barrel at the same velocity li 3 83137, the energy of each is determined by their relative weight. The heavier the sleeve relative to the weight of the projectile, the higher the percentage of energy loss because the sleeve is not used for a useful purpose as a projectile. The diameter (shaft) of the tip body is small compared to the diameter of the sleeve, resulting in a high weight and energy fraction of the sleeve, so that the tip receives a relatively small amount of total energy and is therefore the least efficient of sleeve-type projectiles.

FR patent publication 861 167 discloses a projectile / grenade with a rear body with a series of longitudinal ribs. The tubular sleeve surrounds and is attached to the rear body by the adhesion of the ribs and the corresponding grooves. The grooves also act as lines of weakness to allow fragmentation during cooling, but the sleeve is otherwise trapped in the projectile.

FR-A-2 365 098 discloses an annular projectile of similar structure with a grooved body surrounding a ribbed body.

It is an object of the present invention to increase the advantages and minimize the disadvantages of a sleeve projectile by moving the spin rotation mechanically (instead of frictional rotation) while simultaneously having the largest possible cross-section 25 and weight in the streamlined projectile and minimum weight in the sleeve.

It is an object of the present invention to provide a streamlined, substantially full-tube bullet or projectile. One embodiment of the invention relates to a rifle-30 projectile and another embodiment to a shotgun projectile.

It will be readily appreciated by those skilled in the art that the problems associated with the design of rifle and pistol projectiles and shotguns are, although they have some features in common, usually with different details due to the different barrel environments and uses to which the preparations are subjected.

4 83137 A projectile according to the present invention comprising a projectile containing a pushing explosive, a bullet having a substantially full diameter of the tube and a plurality of full length grooves on its outer surface, helically or substantially parallel to the longitudinal axis of the bullet and a plastic sleeve the sleeve is characterized in that the sleeve comprises a body part with a diameter larger than the diameter of the bullet and a plurality of spaced projections 10 which engage the corresponding grooves in the bullet and cause the bullet to rotate as the sleeve rotates as the body engages the grooves in the tube, through which the projectile the projectile is fired.

The radial strength of the protrusions is substantially the same as the radial depth of the grooves and that the protrusions extend the entire length of the bullet, thereby stabilizing and preventing the bullet from tilting off the axis as it passes through the tube through which it is fired.

The projectile or bullet may be formed of lead or steel or other suitable material, depending on the type of projectile in which it is incorporated and its use.

It is preferred that the grooves have a substantially V- or U-shaped cross-section and that the sleeve comprises a body part which is short compared to the length of the projections.

The sleeve preferably comprises a flexible plastic molding. The protrusions of the sleeve can be made hollow to lighten the sleeve.

The invention further comprises a sleeve having a cylindrical body portion and a plurality of fingers substantially parallel to the axis of the body portion or formed helically about the axis.

It is preferred that the projections of the sleeve have a reduced part at their free end.

The outer surface of the projections of the sleeve is radially part-35 cylindrical, the projections filling the corresponding grooves in the bullet, the parts between the grooves of the bullet forming a substantially circular broken cross-section.

The body portion of the sleeve comprises a cylindrical body portion having a raised diameter raised portion having a diameter 5 larger than the diameter of the bullet.

In addition, the protrusions of the sleeve extend forward from the cylindrical body of the bullet to its conical portion, thereby forming a supporting truncated circle having the diameter of the tube around the reduced diameter of the conical portion of the bullet.

A projectile incorporating a sleeve according to the first aspect of the invention generates significantly less friction in the barrel of a weapon than a normal bullet because the Rih-laurels of the barrel bite more easily into the sleeve, and thus generate less friction as it travels along the barrel. As a result, more of the initial energy becomes created as kinetic energy (velocity) and less initial energy is converted to heat in the barrel.

The sleeve preferably has a body that is short relative to the length of the protrusions, the protrusions being ejected radially outward from the longitudinal axis of the bullet as the bullet exits the barrel due to rotation of the bullet and sleeve, releasing the protrusions from the contact it has. into the grooves of the bullet and, allowing air pressure, completely remove the sleeve from the bullet as soon as it comes out of the barrel.

The sleeve may have an axial hole which allows the pressure of the pushing explosive to force the sleeve against the walls of the barrel and onto the groove. Alternatively, the rear end of the bullet may have a conical engagement with the sleeve body to provide the same effect.

By forming full-length grooves in the surface of the bullet, the bullet can rotate and / or laterally stabilize as it travels in air, and when the bullet has helical grooves, the rotational speed corresponds to 35 bullets advancing in air, so as the advancing speed decreases. The bullet is made of steel or similar hard metal for military use.

When the grooves are extended to the tip or front end of the bullet, the cross-sectional or frontal area of the 5 bullets is reduced, thus increasing the permeability and range of the armor.

Two embodiments of a projectile constructed in accordance with the present invention will now be described with reference to the accompanying drawings, in which Figure 1 is a side view of a bullet, Figure 2 is a section along line II-II of Figure 1, Figure 3 is a side view of a sleeve, Figure 4 is an end view of Figure 3 arrow In the IV direction, Fig. 5 shows a sleeve attached to the end of a bullet 15 and an entire unit attached to the end of a sleeve, and Figs. 6a, b and c show a side view and two cross-sections of a pistol bullet, respectively.

As shown in Figure 1, the bullet 1 has a conventional appearance comprising a side 2 parallel to it and a tapered tip 3. The bullet is essentially full caliber in diameter for the barrel in which it is intended to be used, but only slightly smaller in diameter so that it does not engrave when fired. , as will be explained later. However, unlike a conventional bullet, the surface of the bullet is not a smooth, cylindrical / conical surface, but rather numerous V-shaped grooves 4 are made parallel to the longitudinal axis 1 'of the bullet, the structure to be treated comprising four such grooves and the handles of each groove. -30 at its base mainly at an internal angle of 90 °. In this case, four elongate flanges 5 are formed in the shape of a cross, as shown in Fig. 2. The grooves 4 extend towards the tip 3 of the bullet, and thus the bullet has a much smaller front surface area than a conventional bullet, the bullet also having a corresponding increase in its ability to penetrate the armor plate or the like.

li 7 83137

Attached to the end of the bullet remote from the tip, hereinafter referred to as the rear end, is a sealing and guide sleeve formed of a flexible plastic material, e.g. nylon. The sleeve 6 shown in Figures 3 and 4 5 comprises a substantially cylindrical body part 7 with an enlarged diameter, a raised part 8 of sufficient diameter so that the Rih-engraving of the weapon can be engraved therein and is therefore slightly larger than the bullet. 1 nominal diameter. This is best seen in Fig. 5. Several protrusions 9 protrude from the body part 7, there are four in the construction under consideration, each of which is substantially parallel to the central axis 7 'of the cylindrical body part 7, and each of which comprises, shown in cross section in Fig. 4, mainly a 90 ° segment with a tight fit in the corresponding groove of the bullet 4.

The free end of each protrusion has a reduced strength portion 10 which allows the sleeve 11, to which the sleeve and bullet unit 20 are attached together, to be pressed into its interconnected bullet 1 and sleeve 6 (as shown in 12) from its smaller diameter end portion 13 , to which the unit formed by the bullet and the sleeve is attached. The plastic material of the sleeve closes the sleeve during contraction and makes the seal waterproof during storage. The projections of the sleeve fill the grooves of the bullet behind the contraction and prevent gas leakage through the grooves at the moment of ignition.

As an example, a standard 5.56 soldier or .223 Remington barrel has a nominal barrel diameter of 5.58 mm 30 (.219 inches) and a nominal diameter at the bottom of the grooves of 5.7 mm (.224 inches) with a groove width of 1 .78 mm (0.07 inches). The diameter of a suitable bullet (as shown in the drawings) is a maximum diameter of 5.55 mm (.21875 inches) and the width of the flanges 5 is 1.52 mm (0.060 inches). The total length of Bullet 1 is 28.8 mm (1.127 inches). The nominal diameter of the sleeve body 7 is 5.49 8 83137 nun (.216 inches) and the enlarged diameter portion 8 is 5.7 mm (0.224 inches) in diameter, said portion 8 is 1.58 mm (0.062 inches) in length and the entire body 7 is 3 in length. 18 mm (.125 inches).

As can be seen from Figure 6, the projections 9 of the sleeve 6 can extend in front of the straight cylindrical part of the bullet and further into the conical part of the bullet and thus continue the effect of the straight cylinder. This is particularly advantageous for a pistol bullet, which, like a shotgun projectile, is necessarily short of its diameter and must therefore be conical for most of its length in order to be streamlined. The support of the protruding projections 9 prevents the bullet from tilting off the shaft as it passes through the barrel.

Since both the rifle and the pistol have a grooved barrel 15 for bullet rotation, both the rifle and the pistol bullet benefit from the resulting geometry associated with the projection of the protrusions into the cone portion in that the leading edge of the soft sleeve extends beyond the cone diameter out of the cartridge case and into the grooves of the barrel. The protrusions formed by the leading edge of the protrusions thus soften the entry of the bullet into the groove and prevent damage to the barrel.

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Claims (9)

Anununition shot comprising a sleeve (11) containing a driving charge, a ball (1) having a diameter substantially equal to the diameter of the barrel, said ball having a plurality of latches (4) in its outer surface along its entire surface. length extending helically about or substantially parallel to the longitudinal axis of the ball (1), and a plastic hollow (6) into which the ball (1) is inserted and sealing the ball in the sleeve (11), characterized therein , that the hollow (6) comprises a body part (8) with a diameter greater than the diameter of the ball (1) and a plurality of mutually spaced fingers (9) which engage the corresponding latch (4) in the ball (1) and cause the ball to rotate when the hollow (6) rotates by engaging the body portion (8) with grooves in a barrel through which the shot is fired. Shot according to claim 1, characterized in that the fingers (9) have a radial thickness substantially equal to the radial depth of the latch and that the fingers (9) extend substantially along the entire length of the ball, the ball being stabilized and prevented from being tilted. out of the shaft as it moves through the race through which it is fired. 3. Shot according to any of the preceding claims, characterized in that the latch (4) has a substantially V-shaped or U-shaped cross-section. Shot according to any of the preceding claims, characterized in that the ball (1) is of steel. Shot according to any of the preceding claims, characterized in that the hollow (6) comprises a body part (7) which is short in comparison with the length of the fingers (9). 6. Shot according to any one of the preceding claims, characterized in that the finger (9) of the hollow (6) has a tapered portion (10) adjacent its free end. 7. Shot according to any of the preceding claims, characterized in that the fingers (9) of the hollow (6) have a partial cylindrical radially outer surface (9 '), the fingers filling the respective spacers (4) in the ball. (1) and the portions (5) of the ball fastener forming a substantially circular interrupted section. 8. Shot according to any one of the preceding claims, characterized in that the body part comprises a cylindrical body part (7) having an increased diameter having an elevated portion (8), the diameter of which is larger than the diameter of the ball (1). Shot according to any of the preceding claims, characterized in that the fingers (9) of the hollow (6) extend forwardly past the cylindrical body of the ball up to its conical portion, forming a supporting, interrupted race diameter circle. around the reduced diameter of the conical section.