NO178594B - Projectile or bullet for firearms - Google Patents

Description

The present invention relates to a projectile or a bullet for a firearm, preferably a weapon with a rifle bore, and more particularly a bullet made of steel, the use of steel for the production of such a bullet, and a method for producing the bullet.

The present international patent application is based on the applicant's national Swedish application no. 9201967-8 which is still being processed and from which priority is claimed for corresponding features.

The dominant material used for rifled barrel bullets is lead (Pb), usually surrounded by a jacket made of a copper-zinc alloy or of coated steel. On the one hand, the jacket acts as a protection for the soft lead core against external deformation, and on the other hand it enables firing at the high muzzle velocities that are relevant in modern firearms. At such speeds, an unjacketed bullet will deposit lead in the barrel due to the heat of friction. Furthermore, in connection with hunting, the jacket will increase the effect of the bullet on impact by retaining the shape of the lead core as the bullet penetrates the game and thus enables the desired, deep penetration. The latter characteristic is of course of little importance in connection with practice and competition shooting.

A jacketed lead bullet is produced using several steps. Shell blanks are punched from a shell plate and formed into a sleeve through two or more compression molding operations. The lead core, possibly with the addition of antimony to increase hardness, is draw-formed through conical bores to obtain accurate caliber, and cold-formed to fit into the jacket. In a joining operation, the lead core is adapted to the jacket, whereby a tight fit between the core and the jacket is of great or decisive importance, because the presence of air pockets will cause an imbalance in the bullet which in turn will result in *poor accuracy. During the jointing operation, several tools are used, usually up to six tools, between which the balls and casings are moved during progress, and finally the finished balls are checked with regard to caliber and weight.

Jacketed lead bullets are available in many designs, a common feature of which is that the various designs, especially with regard to The manteI construction has been developed to increase the effect and penetration of the bullet in connection with hunting. However, the majority of firearms ammunition is used for practice shooting and competitions, where properties such as rapid killing are of no importance. In connection with purposes such as sight adjustment and target evaluations in connection with hunting rifles, practice shooting against flash will take place with the ammunition that is later used for the relevant hunting shooting, but such shooting exercises only make up a small part of the total amount of rifle ammunition used in connection with range- shooting and competitive shooting. On the basis that a manufacturer of small caliber ammunition, which only works on the Swedish market, distributes e.g. 5 million cartridges for flash shooting, and when you know that as much as 90-95% of the bullets consist of lead, you will easily understand that significant quantities of this toxic metal are scattered around the environment every year, so that all measures aimed at towards limiting and reducing the deposition of lead is of course of great importance.

For smooth rifle barrels (shotguns), there are alternatives on the market for the use of lead shot, although lead shot is still dominant. For rifles and handguns, however, there is currently no alternative to lead to be able to meet the shooters' demands for performance and price.

It is therefore an aim of the present invention to provide a small-caliber bullet with a minimum lead content which, through a simplified production process, will have a low market price compared to jacketed lead bullets, and where one has nevertheless retained the bullet's shooting properties in connection with target shooting.

Another disadvantage of conventional bullets that is evident in target shooting is that, when perforating the target, the bullet produces a torn hole with grainy edges, which often leads to difficult interpretation and necessitates the use of drill targets to determine which target ring was hit.

A further object of the present invention is therefore to produce a small-caliber projectile with a shape which helps to form a cylindrical piercing with sharp and clear edges when perforating the target.

These purposes are fulfilled by means of a small-caliber projectile with features as specified in the attached requirements.

The invention shall be described in more detail with reference to the attached drawings, where: fig. 1 shows a partial vertical section of a projectile according to the invention,

fig. 2 shows a target disk penetrated by a conventional jacketed lead bullet,

fig. 3 shows a target disc which has been penetrated by a projectile according to the invention, and

fig. 4 shows a second embodiment of the projectile according to the invention.

Fig. 1 shows a projectile or bullet according to the invention, generally referred to by the reference numeral 1. The bullet 1 comprises a torpedo section 2 and a guide section 3. At its periphery, the guide section 3 comprises circumferential grooves and projecting surfaces 4 which act to provide a tight seal between the bullet and the rifle barrel so that combustion gases are prevented from passing past the bullet. The grooves are arranged so that the material in the surfaces 4 can "escape" when it is compressed by the surfaces in the rifle barrel. In the embodiment shown in fig. 1, the transition section between the torpedo section 2 and the steering section 3 includes a shoulder with a sloping front surface 5 with an angle a relative to the vertical axis 1 which is within the range 25-35°, preferably 30°. The control section 3 further comprises a chamfered rear edge 6. In the embodiment shown in fig. 1, the torpedo section is pointed, but the bullet can alternatively be designed with a hollow point or ogival point, or with a flat or round nose.

The projectile according to the invention is of course not limited to the design shown in fig. 1, but can be given any desired design to meet the special requirements for penetration and stopping power.

The ball 1 is compact and is made of steel with a low carbon content (C) (up to 0.40%) and preferably contains lead (Pb) which gives the steel an improved cutting ability (related cutting ability) compared to standard machine steel cutting ability index 100 (DIN 9SMn23 or SS 1912) to an index 150 for lead-containing steel alloy (DIN 9SMnPb28 or BX 1914). In the present invention, the high machinability of the lead-containing steel alloy is utilized for the production, preferably by rotation in a lathe, of a small caliber bullet with a competitive market price.

Tellurium (Te) can preferably be added to the steel. Tellurium-containing free-cutting steel has a limited industrial application, but is used e.g. in tire spikes and is marketed by Boxholm, Sweden, under the product designation 1914-04+Te, and can be supplied with a tellurium addition of 0.02 to 0.04%. This steel alloy contains lead in an amount of 0.15 to 0.35%

By adding lead and tellurium, the machinability of the steel can thus be increased, and in the present invention the lubricating effect of the tellurium mineral is utilized together with the content of lead to produce a bullet with minimal lead content, which bullet will not damage the rifle barrel when the bullet passes through. Furthermore, it is generally assumed that the high-temperature gases developed during the discharge process pose a more serious threat due to erosion in the barrel, particularly in the conical part of the barrel exposed to the gases during the bullet's free-running passage, i.e. before the bullet has fully settled in the bore of the barrel, than the erosion caused by frictional wear in the bore of the rifle when using copper- or steel-jacketed bullets.

In manufacture, the bullet 1 is preferably machined in a lathe, and cut from a rod which may have a slightly smaller diameter than the rifle caliber to enable the application of a coating with an anti-oxidizing compound, such as copper, zinc, nickel, or a composition which includes one or more of these metals. The coating is preferably applied electrochemically, but can also be provided with the help of a normal jacket blank. The ball can be produced using three or four steps in an automatic lathe, equipped with a bar magazine feed and a tool adapter for multiple cuttings. After machining (and/or after coating), the ball is calibrated, smoothed or polished by shaking in a liquid, possibly with the addition of an abrasive and a cleaning agent, after which the coating is applied. An alternative coating can consist of an application of a layer of polytetrafluoroethylene (PTFE) which will further reduce frictional wear during the ball's passage through the barrel.

Alternatively, the steel may be subjected to normalization to reduce the hardness, e.g. in the case where the ball is produced from cold-drawn material. However, this is not considered necessary in order to reduce frictional wear in the rifle barrel when a tellurium-containing steel alloy that also contains lead is used, but can be advantageous when other steel alloys are used to achieve pre-selected properties in the bullet.

In an alternative manufacturing process, a ball according to the invention is formed in a roll forming machine, e.g. of the type manufactured and marketed by Kinefac Corporation, Worcester, Massachusetts, US. These roll forming machines have high performance and can produce balls according to the invention at a very low price.

Mild steel projectiles or bullets according to the invention have been tested in a number of firing tests to determine their performance under different conditions.

In a first series of firing tests, the bullets were machined from steel containing 0.25% lead and 0.04% tellurium. The ball was coated with a surrounding copper layer of approx. 10 microns. In this embodiment, the ball 1 will hold a weight of approx. 4 g in caliber 6.5 mm, while a jacketed lead bullet of a similar caliber will generally hold a weight of 5-10 g, depending on the design and purpose of the bullet.

As expected, the firing tests confirm that a bullet according to the invention with a relatively low weight achieves a relatively high muzzle velocity. The test results also show that with the bullet 1 with the specified muzzle velocity, good impact point groups are achieved.

The test shooting was carried out outdoors in the middle of the day and with a relative humidity of 40%. The weather conditions can be described as partly cloudy, light wind, but with crosswinds of 2-8 m/s. The distance to the target was 100 m and the muzzle velocities were measured with a model M1 chronograph. The test results were compared with a concurrent Smith Veston laboratory test.

The mild steel cartridges were loaded with a gunpowder charge of approx. 1.95 g, and with this charge an average muzzle velocity of 952.4 m/s was achieved in test series of 10 rounds. The factory charged jacketed lead bullet used for comparison had a weight of approx. 6 g, and achieved an average muzzle velocity of 926.3 m/s with a charge of approx. 2.1 g of gunpowder, and likewise in test series of 10 rounds.

Muzzle Velocity M/S

For comparison between the fired groups, respectively types of bullets, were fired in five series with three rounds in each. The impact points or impact collections of the steel bullet ranged from 17 to 22 mm, while the groups of jacketed lead bullets ranged from

in collections from 17 to 25 mm.

HIT POINT COLLECTIONS

The spread is partly explained as a result of the varying crosswinds that occurred during the test firing, but the accuracy of the results from the comparative tests nevertheless confirms the competitive impact point results of the bullet according to the present invention.

By using a chamfered shoulder 5 in the transition zone between the torpedo section 2 and the steering section 3, it can be achieved that when the bullet penetrates the target it punches a cylindrical hole with clean edges, as shown in fig. 3. By comparison, a target shot through using a conventional jacketed lead bullet will look like fig. 2. In the execution as used during the precision tests stated above, the collar of the ball 1 was given an inclined angle a in relation to the vertical axis of 30°, which in relation to air resistance and penetration efficiency is considered to constitute an advantageous slope.

The chamfered rear edge 6 of the guide section 3, which is preferably rounded or has a bevel angle of 45°, is considered to have a beneficial effect on the escape path of the bullet by contributing to a smooth passage of the combustion gases when the bullet leaves the barrel at the rifle muzzle.

In another series of firing tests, a mild steel bullet of the above-mentioned tellurium-containing steel alloy of the design shown in fig. 4 used in the caliber .308 W. In this embodiment, the bullet 1' has surfaces 4' with rounded edges and an extended, conical guide section 3' with a rounded rear edge 6'. This second test was carried out to determine the performance of the bullet when using automatic rifles and machine guns, and the tests were carried out under varying temperature conditions in the range from -54 to +52°C. The test shows that a ball according to the invention with respect to automatic weapon functions are not inferior to a reference bullet of conventional type. No depositional materials were found in the bore during the course after the launch.

AUTOMATIC WEAPON TEST

Ammunition components

Cartridge: Ordinary 7.62 cartridge with primer

Gunpowder: NC 1055 p 86030

Charge: 45 grains (approx. 2.92 g). Press approx. 340 MPa

Ball: According to the design shown in fig. 4, which gives a total

cartridge length of 70.7 mm. Weight = 124 grains (8.05 g).

Automatic carbine AK4

Machine gun ksp 58

When produced from a steel alloy as described above, a bullet according to the invention will achieve improved properties during the firing process. At the moment of firing, a rifle bullet will not only be exposed to high temperature, but also to gas pressure as high as 3000 kp/cm<2> or more, which can cause damage to a conventional lead bullet, especially during the flight of the bullet. With a bullet according to the invention, this disadvantage, as well as the disadvantage in connection with slipping in the rifle barrel, will be avoided.

The ball 1 according to the present invention must not be considered limited to the embodiments shown in Figures 1 and 4. For a person skilled in the field, it will be clear that modifications regarding the shape of the bullet, such as an extended guide section or torpedo section to increase the weight of the bullet or a manipulation of the center of gravity, can be done to impart other ballistic properties to the bullet. Furthermore, especially in connection with hunting, the torpedo section can be modified to reduce the speed of the bullet when hitting live targets, e.g. by shaping the ball with a hollow tip or bevel tip or a flat nose. The coating in the shown embodiments made of copper can also, as mentioned above, be composed of zinc, nickel, a composition which

contains e.g. lead and one or more of these metals

and/or polytetrafluoroethylene (PTFE). In this connection, the polytetrafluoroethylene coating can be applied in the form of a completely surrounding protective layer, or in the form of circumferential rings around the control section 3 with a close fit inside the rifle barrel.

The purpose of the invention as stated at the outset is fully achieved by a bullet according to the invention: to provide a bullet, preferably for practice and competition shooting, which remarkably reduces the deposition of lead in nature. Addition of lead to ball 1 only changes to approx. 1/400 compared to an equivalent conventional bullet. When manufacturing the ball using a tellurium-containing steel alloy, a lubrication effect will be achieved which will protect the bore and the flat parts of the barrel.

By designing the ball according to the embodiment shown in fig. 1, the second purpose of the invention is also fulfilled: to provide a bullet preferably for use in connection with flash shooting, which bullet, as a result of the construction, results in an indisputably improved hitting pattern.

At the present time, it has not been possible to clarify how suitable the bullet is in connection with hunting. Because of. however, due to its hardness and relatively low weight, the bullet's performance when hitting game can theoretically be predicted, even if the bullet is primarily intended for use in connection with flash shooting.

During the development of the invention, which has always been guided by the basic purpose of arriving at a replacement for lead-containing bullets, many alternatives to the tellurium-containing steel alloy have been considered and tested. It is thus assumed that other metal compositions can also be used for the production of a projectile or bullet for small-caliber weapons, such as steel containing alloying components, which are used in qualities that are usually referred to as free-cutting steel, e.g. silicon (Si), sulfur (S), phosphorus (P) and manganese (Mn), in some cases with the addition of e.g. bismuth (Bi), selenium (Se), or tungsten (W), preferably in combination with lead. All these additives can be used to give the bullet specified properties, e.g. an increased amount of phosphorus will make the bullet brittle with a tendency to crack on impact, leaving little or no ricochets, or an addition of tungsten to increase the bullet's penetrability. A bullet made of tellurium-alloyed steel will, however, exhibit, together with the proportion of lead, a beneficial lubricating effect when passing through the barrel and in connection with the machining, a fact which gives this metal composition particularly suitable properties for the present purpose.

In the present description, the bullet according to the invention has been presented as a projectile or bullet which is primarily intended for use in rifle barrels. This circumstance will not, however, preclude the use of the tellurium-containing steel alloy for projectiles intended for use in smooth barrels in connection with the production of round shot.

Claims (12)

1. Projectile or bullet for small caliber weapons with a compact body of steel alloy and an anti-corrosive coating, characterized in that the steel alloy includes the addition of tellurium (Te). 2. Projectile as specified in claim 1, characterized in that tellurium (Te) is added in an amount of 0.02-0.04%. 3. Projectile as stated in claim 1, characterized in that lead (Pb) is added in an amount of 0.15-0.35%. 4. Projectile as stated in claim 1, characterized in that the anti-corrosive coating contains at least one from the following group of metals including copper (Cu), zinc (Zn) and nickel (Ni). 5. Projectile as stated in claim 1, characterized in that the anti-corrosive coating at least partially contains polytetrafluoroethylene (PTFE)' 6. Projectile as stated in claims 1, 2 and 3, characterized by a torpedo section (2.2') and a steering section (3.3'), which steering section has circumferentially arranged grooves and surfaces (4.4'). 7. Projectile as specified in claims 1, 2 and 3, characterized by a spherical design. 8. Use of alloy steel including the addition of tellurium (Te) for the design of a small caliber projectile. 9. Use of alloy steel as specified in claim 8, including the addition of tellurium (Te) in an amount of 0.02-0.04% for the design of a small caliber projectile. 10. Use of alloy steel as stated in claim 8, including the addition of lead (Pb) in an amount of 0.15-0.35% for the design of a small caliber projectile. 11. Method for producing a small-caliber projectile with a compact body of alloy steel comprising tellurium (Te) and with an anti-corrosive coating as stated in claim 1, characterized by the following steps: - forming a projectile body from a rod element, - calibration of the body , - polishing the body by drumming in a fluid, - coating the body by applying a layer that includes at least one from the following group of metals including copper (Cu), zinc (Zn) and nickel (Ni). 12. Method as stated in claim 11, characterized in that the step comprising coating the body includes application at least partially of a layer of polytetrafluoroethylene (PTFE).