EP4283245A1 - Outil et procédé de fabrication d'un projectile et projectile - Google Patents

Outil et procédé de fabrication d'un projectile et projectile Download PDF

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Publication number
EP4283245A1
EP4283245A1 EP23173741.2A EP23173741A EP4283245A1 EP 4283245 A1 EP4283245 A1 EP 4283245A1 EP 23173741 A EP23173741 A EP 23173741A EP 4283245 A1 EP4283245 A1 EP 4283245A1
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EP
European Patent Office
Prior art keywords
projectile
bullet
tool
cavity
section
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Pending
Application number
EP23173741.2A
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German (de)
English (en)
Inventor
Stephan GELFERT
Donald Meyer
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RWS GmbH
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RWS GmbH
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Filing date
Publication date
Application filed by RWS GmbH filed Critical RWS GmbH
Publication of EP4283245A1 publication Critical patent/EP4283245A1/fr
Pending legal-status Critical Current

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Classifications

    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F42AMMUNITION; BLASTING
    • F42BEXPLOSIVE CHARGES, e.g. FOR BLASTING, FIREWORKS, AMMUNITION
    • F42B12/00Projectiles, missiles or mines characterised by the warhead, the intended effect, or the material
    • F42B12/72Projectiles, missiles or mines characterised by the warhead, the intended effect, or the material characterised by the material
    • F42B12/74Projectiles, missiles or mines characterised by the warhead, the intended effect, or the material characterised by the material of the core or solid body
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B21MECHANICAL METAL-WORKING WITHOUT ESSENTIALLY REMOVING MATERIAL; PUNCHING METAL
    • B21KMAKING FORGED OR PRESSED METAL PRODUCTS, e.g. HORSE-SHOES, RIVETS, BOLTS OR WHEELS
    • B21K21/00Making hollow articles not covered by a single preceding sub-group
    • B21K21/06Shaping thick-walled hollow articles, e.g. projectiles
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F42AMMUNITION; BLASTING
    • F42BEXPLOSIVE CHARGES, e.g. FOR BLASTING, FIREWORKS, AMMUNITION
    • F42B12/00Projectiles, missiles or mines characterised by the warhead, the intended effect, or the material
    • F42B12/72Projectiles, missiles or mines characterised by the warhead, the intended effect, or the material characterised by the material
    • F42B12/76Projectiles, missiles or mines characterised by the warhead, the intended effect, or the material characterised by the material of the casing
    • F42B12/78Projectiles, missiles or mines characterised by the warhead, the intended effect, or the material characterised by the material of the casing of jackets for smallarm bullets ; Jacketed bullets or projectiles
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F42AMMUNITION; BLASTING
    • F42BEXPLOSIVE CHARGES, e.g. FOR BLASTING, FIREWORKS, AMMUNITION
    • F42B33/00Manufacture of ammunition; Dismantling of ammunition; Apparatus therefor
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F42AMMUNITION; BLASTING
    • F42BEXPLOSIVE CHARGES, e.g. FOR BLASTING, FIREWORKS, AMMUNITION
    • F42B8/00Practice or training ammunition
    • F42B8/12Projectiles or missiles
    • F42B8/14Projectiles or missiles disintegrating in flight or upon impact
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F42AMMUNITION; BLASTING
    • F42BEXPLOSIVE CHARGES, e.g. FOR BLASTING, FIREWORKS, AMMUNITION
    • F42B12/00Projectiles, missiles or mines characterised by the warhead, the intended effect, or the material
    • F42B12/02Projectiles, missiles or mines characterised by the warhead, the intended effect, or the material characterised by the warhead or the intended effect
    • F42B12/20Projectiles, missiles or mines characterised by the warhead, the intended effect, or the material characterised by the warhead or the intended effect of high-explosive type
    • F42B12/22Projectiles, missiles or mines characterised by the warhead, the intended effect, or the material characterised by the warhead or the intended effect of high-explosive type with fragmentation-hull construction
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F42AMMUNITION; BLASTING
    • F42BEXPLOSIVE CHARGES, e.g. FOR BLASTING, FIREWORKS, AMMUNITION
    • F42B12/00Projectiles, missiles or mines characterised by the warhead, the intended effect, or the material
    • F42B12/02Projectiles, missiles or mines characterised by the warhead, the intended effect, or the material characterised by the warhead or the intended effect
    • F42B12/34Projectiles, missiles or mines characterised by the warhead, the intended effect, or the material characterised by the warhead or the intended effect expanding before or on impact, i.e. of dumdum or mushroom type
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F42AMMUNITION; BLASTING
    • F42BEXPLOSIVE CHARGES, e.g. FOR BLASTING, FIREWORKS, AMMUNITION
    • F42B12/00Projectiles, missiles or mines characterised by the warhead, the intended effect, or the material
    • F42B12/02Projectiles, missiles or mines characterised by the warhead, the intended effect, or the material characterised by the warhead or the intended effect
    • F42B12/36Projectiles, missiles or mines characterised by the warhead, the intended effect, or the material characterised by the warhead or the intended effect for dispensing materials; for producing chemical or physical reaction; for signalling ; for transmitting information
    • F42B12/38Projectiles, missiles or mines characterised by the warhead, the intended effect, or the material characterised by the warhead or the intended effect for dispensing materials; for producing chemical or physical reaction; for signalling ; for transmitting information of tracer type

Definitions

  • the present invention relates to a tool and a method for manufacturing a projectile with a caliber in the range from 4.6 mm to 20 mm, in particular a deformation bullet, partial decomposition bullet, partial or full jacket bullet, hard core bullet or a tracer bullet. Furthermore, the present invention provides a projectile with a caliber in the range of 4.6 mm to 20 mm, in particular a deformation bullet, partial fragmentation bullet, partial or full jacket bullet, hard core bullet or a tracer bullet.
  • the intermediate and the projectile according to DE 10 2017 011 359 A1 have generally proven themselves, as they are extremely easy to implement, but Uniform deformation of the blank can be achieved, so that a precise projectile can be provided that is optimized in terms of the deformation properties in wound ballistics, in particular for a specific area of application.
  • the intermediate/projectile cold-formed in this way has proven to be advantageous, especially with regard to the desired partial decomposition-deformation behavior in wound ballistics, especially for an often limited speed range.
  • the intermediates and projectiles are only partially suitable for bullet types other than deformation bullets.
  • the mandrel tools are subjected to very high loads and can be improved, particularly for mass production.
  • mandrel tools in particular are made of hard metal or hardened steel, even small tensile stresses can lead to violent breakage of the mandrel, as these materials are very susceptible to violent breakage under tensile stresses.
  • the intermediate and the projectile are in accordance with DE 10 2017 011 359 A1 structurally limited in terms of the length-diameter ratio of the cavity.
  • the cavity on the ogive side may only be approximately as deep as the diameter of the cavity. This means that a deep cavity results in a thin-walled ogive section. A thick-walled ogive section can therefore only have a minimal cavity depth. Due to these constructive constraints, the projectile is designed in such a way that it is only suitable for a limited speed range and only deforms as desired in a limited speed band.
  • a projectile having a caliber in the range of 4.6 mm to 20 mm for ammunition is provided.
  • the projectile can be a deformation bullet, a partial decomposition bullet, a partial or full jacket bullet, a hard core bullet or a tracer bullet.
  • Caliber is generally referred to as a measure of the outside diameter of projectiles or bullets and the inside diameter of a firearm barrel.
  • the core on the nose side of the bullet is not surrounded by jacket material and is exposed.
  • the front of the bullet deforms due to the high pressure when it hits and penetrates the target.
  • the projectile can deform into a mushroom shape (mushrooming) or at least partially deform.
  • the projectile can therefore deliver its energy to the target medium much more effectively than a full-jacket bullet, in which the jacket completely surrounds the core, but has a lower penetrating power.
  • Such bullets are used in particular as hunting bullets because, when shot appropriately, they lead to a quicker death of the game being shot at due to the effective energy release in the game's body than full metal jacket bullets.
  • Partial decomposition bullets are usually designed in such a way that they disassemble in a controlled manner down to a defined residual body. The suction effect of the remaining body ensures that the fragments of the front, dismantled core part largely leave the target. Deformation bullets expand when they hit the target and remain stable in mass. As a rule, deformation bullets are designed in such a way that they hardly lose any weight at the target. The effect is primarily achieved by increasing the cross-section of the evenly expanding projectile and maintaining the same weight.
  • Hard core bullets are also known as penetrators or AP bullets (armor piercing) and are suitable for military use against armored targets, such as armored vehicles or protective vests.
  • Hard core bullets consist of usually consists of a bullet jacket and a hard core inserted and/or embedded in it.
  • the hard core usually consists of pure tungsten, tungsten carbide or hardened steel with a hardness greater than 550 HV. Tungsten and tungsten carbide are ideal for penetrating ammunition for two reasons. Due to the high specific density, the tungsten core or tungsten carbide core has a high kinetic energy, which promotes penetration. Furthermore, the material is very hard, which means that the abrasive penetration process causes less damage to the core itself.
  • the front part is made of hard material and the back part is made of softer material in order to make the projectile's guide band as gentle as possible when running.
  • Another hard core bullet construction principle is only two parts, with a hard core being placed in a thick-walled bullet shoe.
  • the bullet shoe is made of soft material, which means that the barrel-friendly aspect only comes into play because of the bullet shoe.
  • Solid floors are also called solid floors or monolithic floors and are made in particular from one material.
  • the bullet material is usually a soft, ductile material, preferably metal with a density of more than 5 g/cm 3 Copper, tombac, brass or even pure lead can be used as solid bullet material.
  • the intended use of solid bullets is often found in special applications. For example, to be able to hit targets behind glass panes. The projectile nose is flattened so that penetrating the glass pane does not lead to a change in the trajectory.
  • solid bullets can be massively formed or produced by machining. This makes this structure suitable for small and large series.
  • Full jacket bullets usually have a bullet jacket made of deformable material, such as tombac, and a bullet core arranged therein, which is manufactured separately from the bullet jacket.
  • the bullet core is usually made of a softer material compared to the deformable material of the jacket.
  • the core represents the majority of the weight of the projectile and is preferably made of a high-density material.
  • the jacket transfers the twist transmitted by the barrel to the core.
  • the jacket allows a low-friction Pressing through the firearm barrel must be ensured.
  • the jacket also has the task of protecting the core, which is usually made of soft material, from the considerable forces that arise when the projectile is launched and in flight.
  • the full frontal enclosing of the core with the jacket prevents the projectile from opening in the wound ballistic medium and ensures a certain penetration ability on hard targets.
  • the precision of the projectile as well as the aerodynamics of the full jacket bullet are reduced by the frontal enclosure of the core compared to the partial jacket bullet.
  • the bullet core With a partially jacketed bullet, the bullet core is not completely covered by a jacket material, but is exposed in the area of the bullet front, which leads to the desired deformation of the projectile after it has penetrated a target.
  • Tracer bullets or tracer bullets are usually used exclusively for military purposes, as they are used to mark a target to be fired at or a direction to be fired at in a training or war zone.
  • the basic structure of a tracer bullet corresponds to that of a full jacket bullet.
  • a pyrotechnic set is pressed into the rear. This set burns during projectile flight, ignited by the hot propellant powder when fired. This burn serves to visualize the projectile flight.
  • the projectile is made from an intermediate with a tube section of essentially constant wall thickness, which makes up at least 50% of the longitudinal extent of the intermediate, by means of cold forming, in particular extrusion.
  • the pipe section can also make up at least 60%, at least 70%, at least 80% or at least 90% of the intermediate.
  • the intermediate is tubular, in particular it consists of the intermediate. It was shown that with such an intermediate with a pipe section of significant length, a particularly precise production of projectiles using much more delicate tools is possible purely through a cold forming process in a technically simple manner, with a significantly lower working pressure being able to be used for the forming process. which improves the possibility of mass production. In addition, the manufacturing tolerances have been significantly improved.
  • the initial outside diameter of the intermediate was essentially corresponds to the caliber of the projectile to be manufactured, so that the metal material in the area of the outer diameter, especially near the surface, is hardly solidified or deformed on the finished projectile.
  • This makes it possible to achieve a significantly more homogeneous metal structure, which has a positive effect on precision and/or a desired deformation in the case of a deformation bullet.
  • the tube section also makes it possible to penetrate very deeply into the intermediate with very delicate tools, whereby very long service lives can be achieved compared to the solid body, since the tools are little affected due to the tube shape of the intermediate, especially in contrast to a solid material intermediate, as has been the case so far.
  • the pipe section is particularly characterized by the fact that the outer diameter is based on the permissible tension dimension according to CIP, SAAMI or STANAG.
  • the tension dimension defines the intermediate outside diameter in the range from -0.15 mm to +0.05 mm.
  • a projectile with a caliber in the range of 4.6 mm to 20 mm is provided.
  • the projectile is made from an intermediate with a tube section of essentially constant wall thickness, which makes up at least 50% of the longitudinal extent of the intermediate, in particular by means of cold forming, in particular extrusion.
  • the pipe section can also make up at least 60%, at least 70%, at least 80% or at least 90% of the intermediate.
  • the intermediate is tubular, in particular it consists of the intermediate.
  • an inner tube diameter of the intermediate is at most 50% of an outer tube diameter of the intermediate.
  • the outside diameter of the tube serves as a reference for the inside diameter of the tube, since this can be chosen so that it essentially corresponds to the caliber of the projectile to be manufactured, so that no further forming is necessary to obtain the desired dimensions.
  • the thick wall thickness of the pipe section is crucial, since the pipe section is quite massive and resistant to the pressing forces that occur.
  • a projectile with a caliber in the range of 4.6 mm to 20 mm is provided.
  • the projectile is made from an intermediate with a tube section of essentially constant wall thickness, which makes up at least 50% of the longitudinal extent of the intermediate, in particular by means of cold forming, in particular extrusion.
  • the pipe section can also make up at least 60%, at least 70%, at least 80% or at least 90% of the intermediate.
  • the intermediate is tubular, in particular it consists of the intermediate.
  • an internal cross section of the intermediate is point-symmetrical, deviates from a circular shape and is constant in the longitudinal direction.
  • the internal cross section of the intermediate can therefore have any regular or irregular point-symmetrical shape.
  • the outer surface of the tube forms a cylindrical surface.
  • the internal projectile geometry can be easily and flexibly realized by appropriate design of the internal tube cross section, while otherwise maintaining the projectile geometry, the particular forming manufacturing process and the external shape of the projectile.
  • any internal geometries with different deformation properties can be produced in a simple manner.
  • a significant advantage of the fact that the defined inner contour of the intermediate is retained even after forming, in particular cold forming, of the intermediate into a projectile is that further cost reduction potential arises since simple, for example purely conical stamps can be used.
  • the bullet cavity can be notched either with a segmented mandrel in a round tube-shaped intermediate or with a defined inner contour and a cone-shaped punch.
  • Defined inner contours of the tubular intermediate can, for example, be star-shaped, like a non-convex regular polygon and, for example, have 10 to 100 edges of equal length.
  • the projectile made from the star-shaped intermediate has a quick response at low impact speeds, due to the strong notch effect.
  • Another defined inner contour is a polygon, also called a polygon, which comprises a closed line and in particular whose 5 to 50 edges are all the same length.
  • the internally polygonal intermediate described previously leads to a projectile that deforms at increased impact speeds because the notch effect is weaker compared to the star-shaped intermediate.
  • a projectile made from an intermediate that has an internal hexagonal shape as a defined inner contour has an even lower notch effect.
  • This shape is also called polylobular and consists of 3 to 40 circular elements of equal length connected together.
  • Further options for controlling the responsiveness as well as the susceptibility to decomposition are conceivable using tubular intermediates with V-shaped notches.
  • the notch depth, the notch angle and/or the number of notches can vary and be adapted to the ballistic requirements. Since the intermediate according to the invention is an extrusion profile, delicate constructions with 5 to 10 deep grooves or 5 to 20 ribs are also conceivable.
  • an outer diameter of the intermediate essentially corresponds to the caliber of the projectile.
  • a significant advantage of this embodiment is that the external dimensioning of the intermediate is already selected such that the intermediate already has the external dimension of the projectile to be manufactured.
  • the dimension-sensitive caliber of the projectile can be adjusted in a simpler and more precise manner during the blank or intermediate production, without the outer skin of the intermediate having to be changed during the subsequent, particularly cold-forming, production of the projectile shape. It has turned out that from a manufacturing perspective it is much easier to preset the outer diameter and not just during the much more complex projectile production or shaping.
  • a projectile with a caliber in the range of 4.6 mm to 20 mm is provided.
  • the projectile is made from an intermediate with a tube section of essentially constant wall thickness.
  • the pipe section can make up at least 50%, in particular at least 60%, at least 70%, at least 80% or at least 90%, of the longitudinal extent of the intermediate.
  • the intermediate is tubular, in particular it consists of the intermediate.
  • the pipe section has a projectile casing surrounding a central cavity, which has a projectile front that tapers in particular in the manner of an ogive and an adjoining projectile rear with a solid rear area which opens into a floor.
  • the pipe section i.e. the bullet casing with the bullet rear, bullet front and bullet base, is made in one piece.
  • an average hardness on the floor of the projectile corresponds to at least 103%, in particular at least 105%, of the average hardness if the projectile were made from a solid intermediate, and / or an average hardness in the area of a jacket area of the rear of the projectile surrounding the cavity is at most 90 %, in particular at most 85% or at most 80%, corresponds to the average hardness if the projectile were made from a solid intermediate.
  • the average hardness is an average value of the individual hardness values at the corresponding points or sections and is intended to indicate the trend, although it may be that the conditions described do not apply to individual values.
  • the hardness values can be determined using the Vickers hardness test (HV).
  • the inventors have identified individual characteristics in the hardness curve in order to distinguish a projectile produced according to the invention from previously known projectiles, which reveal numerous advantages of the present invention.
  • the softer area in the rear of the bullet has a positive influence on the barrel life of the firearm and results in a longer tool life.
  • a soft intermediate area of the projectile is particularly relevant for long tool life. The softer the intermediate area of the final projectile remains due to the previous operations, the The tools had to do less forming work during the operations. This results in a longer tool life.
  • the hardness values are values close to the surface. For example, these can be measured a few millimeters below the outer surface of the projectile.
  • the casing area of the tail of the projectile surrounding the cavity has a guide band defining a maximum outer diameter of the projectile for engaging in a pull-field profile of a firearm barrel.
  • a soft guide band particularly increases the advantages described in terms of barrel life of the firearm and tool life.
  • an averaged hardness of the guide band over its entire radial depth, in particular up to the cavity is softer, in particular at least 10%, at least 15% or at least 20%, softer than the averaged hardness when the projectile is made of a solid intermediate would be produced.
  • the tail of the bullet in the axial projection of the cavity i.e. at the rear of the cavity, has a solidified core region which extends in the longitudinal direction of the projectile, in particular to the floor of the bullet, with a higher average hardness than the tail of the bullet areas adjacent to the core region, the average hardness of which is at least 140%, in particular at least 150% or at least 160%, corresponds to the average hardness if the projectile were made from a solid intermediate.
  • the material of the projectile and/or the intermediate is copper, aluminum, iron, such as soft iron, silver, titanium, tungsten, tin, zinc, magnesium , lead, cadmium or alloys thereof.
  • a tool for pressing an intermediate used in a particularly cylindrical die which has a pipe section with a cavity with a substantially constant Diameter in order to produce a projectile designed in particular according to one of the previously described aspects or exemplary embodiments with a caliber in the range of 4.6 mm to 20 mm.
  • the tool can in principle be made of a rigid, in particular inelastic, material and can, for example, consist of one piece.
  • the tool includes a holding section where an operator or a machine can hold and operate the tool. Furthermore, the tool has a shaping section that tapers in the direction away from the holding section with a tip, an elongated, at least partially curved, in particular concavely shaped, or conical guide part adjoining the tip for guiding the tool within the cavity of the intermediate and a projection-free part thereon subsequent at least partially curved, in particular concavely shaped, or conical pressed part with a different inclination as the guide part to the tool longitudinal axis.
  • the guide part of the shaping section arranged adjacent to the tip serves to guide the tool within the cavity of the intermediate. Guiding the tool within the cavity of the intermediate has several advantages.
  • the aligned tool movement in the direction of the longitudinal axis of the cavity reliably ensures that an essential aspect of the present invention, namely the ability to use lower pressing forces and more delicate tools, is retained.
  • the inclination of the outer surface of the pressing part with respect to the longitudinal axis of the tool is greater than the inclination of the outer surface of the guide part with respect to the longitudinal axis of the tool.
  • this makes it possible to produce a particularly delicate tool in which the guide part is thin and very elongated, so that it is possible to reach deep into the cavity of the intermediate.
  • the tool according to the invention it can withstand a large number of pressing processes, in particular at least 100, 300, 500, 700 or at least 1000 pressing processes.
  • an axial length of the guide part is based on an internal dimension of the intermediate coordinated so that the tool at the transition from the guide part to the pressed part has an external dimension of up to 1.4 times the diameter of the cavity.
  • This geometric coordination ensures particularly good guidance of the tool within the cavity of the intermediate.
  • an axial length of the guide part and/or the pressing part is at least 80% of a maximum radial distance of the cavity.
  • the axial length of the guide part can be at least as large, at least 1.5 times as large or even at least twice as large as the maximum radial distance of the cavity of the intermediate.
  • its cross section is point-symmetrical, particularly in the area of the guide part and/or the pressing part, and deviates from a circular shape.
  • any regular or irregular point-symmetrical shapes can be considered for the outer cross section of the guide part and/or the pressed part, which can be selected depending on the desired internal geometry of the projectile to be manufactured.
  • an intermediate with a tube section of essentially constant wall thickness is inserted into a particularly cylindrical die and the intermediate is cold-formed, in particular by pressing, by means of a tool designed in particular according to one of the previously described and, for example, according to one of the previously mentioned aspects of the invention or exemplary embodiments cold formed, in particular formed by extrusion, so that at least in sections the outer diameter of the intermediate remains essentially constant and determines the projectile caliber.
  • a tool designed in particular according to one of the previously described and, for example, according to one of the previously mentioned aspects of the invention or exemplary embodiments cold formed, in particular formed by extrusion, so that at least in sections the outer diameter of the intermediate remains essentially constant and determines the projectile caliber.
  • a tubular metallic intermediate is made in particular from copper, aluminum, iron, such as soft iron, silver, titanium, tungsten, tin, zinc, magnesium, lead, cadmium or an alloy thereof for producing a projectile in particular according to the invention, such as a deformation bullet, a partial fragmentation bullet, a partial or full jacket bullet, hard core bullet or a tracer bullet, with a caliber in the range of 4.6 mm to 20 mm for ammunition.
  • the basic idea underlying the present invention in particular using a substantially exclusive cold forming process for producing a projectile, is to use a tubular intermediate, that is to say an intermediate which comprises a pipe section which essentially makes up 50% of the longitudinal extent of the intermediate, can be simple in terms of manufacturing technology Way a particularly precisely manufactured projectile that can be produced with delicate tools can be created, with a lower working pressure being required than is the case in the prior art.
  • a tool designed according to the invention is used.
  • a projectile according to the invention is generally provided with the reference number 1
  • a compact according to the invention is generally provided with the reference number 10
  • a tool according to the invention is generally provided with the reference number 100.
  • an exemplary embodiment of an intermediate 3 or a countersunk intermediate 5 is shown with a pipe section 4 which serves as a bullet blank.
  • the starting material for the intermediate 3 is preferably rod or wire material.
  • the inner tube surface 39 of the intermediate 3, which has a tube section 4 with a substantially constant wall thickness, is defined in particular by the central cavity 45 of the tube section 4.
  • the pipe section 4 is produced in particular by means of shearing, cutting, vibratory grinding or adiabatic separation.
  • the resulting, preferably cleanly separated, intermediate flat surfaces 25 limit the intermediate length Longitudinal direction L.
  • the intermediate flat surfaces 25 of the intermediate 3 can have different or identically shaped intermediate flat surfaces 25 due to one-sided or double-sided countersinking 19 ( Figure 2 ).
  • a basic idea of the present invention is to produce a projectile 1 from a tubular intermediate 3, instead of from a solid wire blank as was previously the case.
  • the thick wall thickness of the intermediate 3, which according to the exemplary embodiment consists entirely of a pipe section 4, can be seen, with a pipe section inner diameter making up approximately 1/3 of a pipe section outer diameter and being essentially constant.
  • the pipe section represents at least 50% of the longitudinal extension of the intermediate 3.
  • the die 7 includes a rotation-shaped die cylinder inner surface 93 with a central front side 101.
  • the front side 101 of the cylindrical die 7 and the taper 95 towards the ejector side of the die 99 are responsible for the shape of the pre-press 9 and for closing the inner tube surface 39 of the rear of the projectile 51.
  • the compact 10 already has a deformed, in particular convexly shaped, inner wall surface 71, which is produced by means of a tool 100 according to the invention.
  • a projectile 1 according to the invention is in Figure 4 shown in a sectional view.
  • the projectile 1 comprises a projectile body 13, which is made in one piece and in particular consists of a homogeneous material, for example of iron material or non-ferrous material, in particular a non-ferrous metal, in particular a copper alloy.
  • the one-piece structure of the in Figure 4 Visible projectile 1 has a positive effect on the manufacturing tolerances, this has a positive effect on the imbalance and thus on the projectile precision.
  • the projectile body 13 comprises a conical projectile tail 51 and a projectile front 53 that tapers like an ogive.
  • the projectile front 53 is formed by a circumferential bow wall 41 which encloses a central cavity 45 that is open towards the front of the projectile 1. By bending the ogive-shaped floor front 53, a bow fold 33 is created in the bow wall 41.
  • the guide band 63, the design of the cavity 45 and the choice of material and its hardness are of particular interest.
  • the choice of material is preferably a material that fits into the tensile field profile of the firearm barrel with little resistance so that the projectile can be accelerated efficiently.
  • the guide band 63, which is in contact with the actual tension field profile, is important here.
  • the diffusion coefficient of the guide band 63 should also be as impermeable as possible to the partner material of the barrel so that cold welding is prevented.
  • the low-resistance penetration of the projectile into the tensile field profile can be achieved not only by the material properties but also by the design of the cavity 45.
  • the cavity 45 creates an elastic deflection possibility, which further reduces the press-through resistance.
  • the tail 51 and the tail bevel 61 are of particular interest.
  • the tail of the projectile can be designed in geometrically narrow tolerances through the manufacturing process in a die 7; reproducible, geometrically narrow tolerances in the tail mean high precision during projectile flight.
  • the tail bevel 61 influences the aerodynamic vortex shedding during projectile flight and can thereby influence the aerodynamic resistance.
  • the projectile front 53 and the tip 29 also influence the aerodynamics.
  • a narrow ogive and a thin tip mean a variant with less aerodynamic drag.
  • Projectile 1 shown can include a deformation bullet, a partial decomposition bullet or a partial jacket bullet, which can be designed to meet the application-specific requirements, in particular terminal ballistics.
  • the diameter of the opening 35 of the projectile 1 has a significant influence on the hydrostatic pressure inside the cavity 45 of the projectile, which occurs when the projectile 1 penetrates a wound ballistics, also called gelatinous mass.
  • This hydrostatic pressure ultimately has an influence on the deformation properties of the projectile 1 and thus on the energy release in the target.
  • a large opening diameter means a high hydrostatic pressure and a rapid response in the gelatinous mass, whereas a smaller diameter means a slightly delayed response.
  • the wall thickness of the tip 29 counteracts the opening diameter 35; the stronger the wall thickness, the stronger the hydrostatic pressure must be in order to be able to achieve an increased energy release effect in the gelatinous mass.
  • the number and shape of the wall slots 43 determines the breaking behavior of the projectile 1, the more acute the wall slots 43 are, the stronger their notch effect, which leads to a radial weakening of the projectile front 53 and to a faster deformation of the projectile 1 in the gelatinous mass.
  • the design of the cavity 45 has an influence on the increase in diameter of the projectile 1 after it hits the gelatinous mass.
  • a short cavity 45 leads to a smaller deformation on the projectile nose 53, which leads to a reduced energy release in the gelatinous mass.
  • With an elongated cavity 45 which, as in Figure 4 As can be seen, extending in the longitudinal direction L from the opening 35 to the rear of the projectile 51, an increased energy release and thus reduced penetration depth in the gelatinous mass is realized.
  • an intermediate 3 made of metal is provided, preferably made of a non-ferrous metal or ferrous metal ( Figure 5 ), which is obtained from continuous tube raw material or bar material such as a tube by cutting.
  • the intermediate 3 consists in particular of a homogeneous material and is constructed in one piece.
  • the intermediate 3 is formed into a pre-press 9 by setting, in particular cold formed, for example by pressing or extrusion ( Figure 6 ).
  • Figure 6 As from a comparison of the Figures 5 and 6
  • the length of the intermediate 3 expands, with the outer diameter essentially corresponding to the caliber of the projectile 1.
  • the increase in length and diameter results from the central tapered cavity section 75 introduced during setting, which extends from an end face 31 of the pre-compression 9 through the pre-compression 9 to the opposite end face 37 of the pre-compression 9.
  • the introduction of wall slots 43 A segmented tool 100 causes a material shift, which manifests itself in a longitudinal expansion, in particular in the direction of the end face 31.
  • the tapering cavity section 75 which is located on the opposite end face 37, is formed by a particularly convexly shaped inner wall surface 71.
  • the setting can take place via a tool-die arrangement, with the external geometry of the tool 100 determining the geometry of the hollow space section 65.
  • wall slots 43 oriented in the longitudinal direction L of the pre-press 9 or a pressed part 10 are cold-formed on an inner wall surface 71 of the pre-compression 9, which will be explained in detail later.
  • the pre-compression 9 is pre-pressed to form the compact 10 according to the invention ( Figure 7 ).
  • the blank is turned. This requires a mechanical turning operation.
  • the pre-compression 9 is cold-formed in the direction of the end face 31 of the pre-compression 9, so that an ogive-like projectile front 53 is formed by compressing the front wall 41.
  • the bow wall 41 is also cold-formed on the outside, in particular with the formation of bow folds 33, of a bow wall 41 which tapers at least in sections in the shape of an ogive. Due to the bow wall 41 tapering towards the tip 29, the wall thickness of the section forming the later floor front 53 increases compared to the original bow wall 41 of the pre-press 9.
  • the compact 10 produced in this way consists of a metal body 113 made of a particularly homogeneous material, preferably made of iron or non-ferrous material, and is then further cold-formed to form an in Figure 8 projectile body 13 shown, which largely already has the complete geometry of the final projectile 1.
  • the projectile body 13 is sharpened starting from the compact 10 in the longitudinal direction L, so that the narrowest possible tip 29 of the projectile is created, the internal geometry of the central cavity 45 being changed directly behind the opening 35, in particular widened in the direction of the rear of the projectile 51, in particular being formed into a thin channel becomes.
  • a rear cavity 21 is additionally formed, which is delimited in the longitudinal direction of the projectile in the direction of the projectile front 53 by a rear cavity base section 59.
  • the material of the hollow cylinder 65 flows along the tool 100 and thus defines the rear cavity wall thickness b in Figure 9 .
  • the rear cavity 21 is formed by a hollow cylinder 65 and delimited by a hollow cylinder inner surface 67.
  • the rear cavity 21 can be filled with another material.
  • This material can include a ferrous metal, a non-ferrous metal, a polymer or a mixture of polymer and metal powder and is used to tare the weight and center of gravity or to increase penetration.
  • a pipe intermediate 3 made of metal, preferably made of a non-ferrous metal or ferrous metal, is provided ( Figure 9 ), which is obtained from continuous tube raw material or bar material such as a tube by cutting.
  • the intermediate 3 consists in particular of a particularly homogeneous material and is constructed in one piece.
  • the intermediate 3 is formed into a pre-press 9 by setting, in particular cold formed, for example by pressing or extrusion ( Figure 10 ).
  • Figure 10 As from a comparison of the Figures 9 and 10
  • the length of the intermediate 3 expands, with the outer diameter essentially corresponding to the caliber of the projectile 1.
  • the increase in length and diameter results from the central, initially cylindrical, then tapering cavity section 75 introduced during setting, which extends from an end face 31 of the pre-compression 9 through the pre-compression 9 to the opposite end face 37 of the pre-compression 9.
  • the introduction of the wall slots 43 by the segmented tool 100 causes a material shift, which manifests itself in a longitudinal expansion, in particular in the direction of the end face 31.
  • the cavity section 75 which is initially cylindrical in the longitudinal direction L and then tapers, and which extends to the opposite end face 37, is formed by a concavely shaped inner wall surface 71. Setting can be done using a tool-die arrangement, with the external geometry of the tool 100 determining the internal geometry of the hollow cylinder 65.
  • the central cavity 45 Figure 10 owns compared to Figure 6 a larger volume, which results in other ballistic properties such as penetration properties similar to full metal jacket bullets.
  • wall slots 43 oriented in the longitudinal direction L or in the pressing direction P of the pre-press 9 or the pre-press 10 are cold-formed on the inner wall surface 71 of the pre-press 9, which will be explained in detail later.
  • the pre-compression 9 is pre-pressed to form a compact 10 ( Figure 7 ).
  • the blank is turned over in a turning operation.
  • the pre-compression 9 is cold-formed in the direction of the end face 31 of the pre-compression 9, so that an ogive-like projectile front 53 is formed by compressing the front wall 41.
  • the bow wall 41 is also cold-formed on the outside to form a bow wall 41 that tapers at least in sections in the shape of an ogive.
  • the wall thickness of the section forming the later floor front 53 increases compared to the original bow wall 41 of the pre-press 9 and the cavity 45 created when setting is due to the concave design of the tapering cavity section of the pre-press 9 constructed in an ellipsoidal manner.
  • the compact 10 produced in this way consists of a metal body 113 made of a particularly homogeneous material, preferably of iron or non-ferrous material, and is then further cold-formed to form an in Figure 12 projectile body 13 shown, which largely already has the complete geometry of the final projectile 1.
  • the projectile body 13 is sharpened starting from the compact 10 in the longitudinal direction L, so that the rotationally ellipsoidal cavity 45 of the projectile 1 in Figure 12 is narrower than in Figure 11 .
  • Rear cavity 21 which is delimited in the longitudinal direction of the floor in the direction of the floor front 53 by a rear cavity base section 59, is formed.
  • the rear cavity 21 is formed in the radial direction by a hollow cylinder 65 and delimited by a hollow cylinder inner surface 67.
  • the cylindrical rear cavity 21 is delimited from the central cavity 45 by a central constriction 27.
  • the rear cavity 21 can be filled with another material.
  • This material can include a ferrous metal, a non-ferrous metal, a polymer or a mixture of polymer and metal powder and is used to tare the weight and center of gravity or to increase penetration.
  • the increase in length and diameter results from the central cavity section 75, introduced during setting, which tapers in the direction of the opposite end face 37 and which extends from a sharp edge 23 of the pre-compression 9 through the pre-compression 9 to the opposite end face 37 of the pre-compression 9.
  • Pressing in the conical tool 100 causes a material shift, which manifests itself in a longitudinal expansion, in particular in the direction of the end face 31.
  • the tapered cavity section 75 which is located on the opposite end face 37, is formed by a conically shaped inner wall surface 71.
  • the setting can take place via a tool-die arrangement, with the external geometry of the conical tool 100 determining the geometry of the hollow space section 65.
  • the blank is turned. This requires a particularly mechanical turning operation.
  • the pre-compression 9 is cold-formed in the direction of the sharp edge 23 of the pre-compression 9, so that a preliminary stage of a projectile front 53 is formed by compressing the front wall 41.
  • the front wall 41 is also cold-formed on the outside to form a front wall 41 that tapers at least in sections. Due to the preferably symmetrically introduced, front and rear conical cavities, the insertion process of the stamp causes material buildup on the front side of the conical tool 47. A central constriction 27 is created which completely separates the two preferably conical cavities.
  • the compact 10 produced in this way consists in particular of a metal body 113 made of homogeneous material, preferably of iron or non-ferrous material, and is then further cold-formed to form an in Figure 15 projectile body 13 shown.
  • a material is filled into the cavity sections 75 on the front and rear sides, which is preferably soft and ductile and has a high material density.
  • the rear filler 117 can influence the penetration properties of the projectile 1; for example, if a hard rear filler is used, the projectile 1 can penetrate deeper.
  • the front filler 119 is preferably made of a ductile metal such as lead or tin and can influence the front deformation mechanism.
  • the projectile body 13 is sharpened in the longitudinal direction L starting from the compact 10, so that a tip 29 of the projectile is realized.
  • FIG. 17 A schematic representation of a fired, deformed projectile 33, which results from firing a projectile 1 according to the invention and striking the projectile 1 on a target, in particular a standard target, such as a gelatinous mass, is shown in Figures 17 and 18 pictured.
  • the deformed projectile 49 differs from the prior art projectiles in particular in the formation of segment vanes 111 which are bent radially outwards upon impact with a target.
  • the front wall 41 is torn open along the wall slots 43 and the outer surface 87 is turned outwards, with the cavity base section 57 remaining intact. This creates a Spider-like deformed bullet that is greatly expanded in relation to the longitudinal axis of the bullet, which causes increased resistance when penetrating the gelatinous mass and thus increases the energy release and reduces the penetration depth.
  • the deformation behavior results, on the one hand, from the cold forming and the geometry of the central cavity 45 and, on the other hand, from the wall slots 43 made in the inner wall surface 71 of the pre-pressed part 9, which remain as slots on the finished projectile 1 on the inner wall surface 71 of the projectile front 53.
  • the cold forming increases the strength of the inner wall surface 71 transversely to the longitudinal direction L compared to the strength of the inner wall surface 71 in the longitudinal direction L and the deformation behavior can be controlled in a targeted manner through the wall slots 43.
  • the impact speed at which the projectile 1 begins to deform also called the response behavior, is determined by the diameter of the opening 35. As in Figure 17 can be seen, the projectile points 1 in Fig. 17 bent segment flags 111.
  • the front wall 41 When hitting a target, the front wall 41 opens along the wall slots 43, during which only the rear of the projectile 51 with the cavity base section 57 remains largely undeformed.
  • the length, number and depth of the wall slots 43 can be used to specifically adjust how wide the bow wall 41 opens and thus how large the expansion and bending of the segment flag 111 is. In this way, the deformation behavior of the projectile 1,33 can be changed independently of the strength of the bow wall 41.
  • expensive heat treatment processes, such as annealing, after cold forming can be dispensed with and the projectile 1 according to the invention can therefore be produced particularly easily and cost-effectively.
  • the impact speed of the projectile 1 on the gelatinous mass is also responsible for the final shape of the deformed projectile 49.
  • Figure 17 For example, shows a deformed bullet that hit at high speed. The segment flags 111 are bent more strongly due to the hydrodynamic pressure.
  • a projectile 1 is shown with an impact speed typical of a projectile, which reshapes the segment flags 111 to a smaller mass upon impact. At a different impact speed the Segment flags 111 are deformed more parallel to the longitudinal direction L, which is what the Figure 17 corresponds.
  • the distance between the floor 17 and the cavity base section 57 can be designed so that a rupture disk-like pressure relief valve is implemented, with which the excess floor opening pressure can be reduced.
  • the resulting hole in the floor of the bullet not only reduces the bullet opening pressure, but also has stabilizing effects in the gelatinous mass.
  • Tools 100 according to the invention basically have a holding section 107 for gripping, clamping or the like of the tool 100 and a tapering shaping section 108 adjoining the holding section 107, which can also be referred to as a press head, with a press tip/guide tip 85, one on the press tip/guide tip 85 adjoining elongated, at least partially concave or conical guide part 79 for guiding the tool 100 within the cavity 45 of the pipe section 4 and an adjoining at least partially concave or conical pressed part 80 with a different inclination to the longitudinal axis of the tool.
  • the conical pressing part 80 and the conical guide part 79 of the tool 100 have six segment edges 77 on an outer lateral surface 87 which are uniformly distributed in the circumferential direction and are polygonal in the radial direction from the outer lateral surface 87, and are therefore polygonal in cross section.
  • the pressing part 80 merges into the guide part 79 without any projections.
  • the segment edges 77 extend to the concave shaping section 89 and the convex shaping section 91 along the longitudinal direction L at the plan areas 105 of the press head 108.
  • the segment edge 77 of the press head 108 can each According to the design, they have concave shaping section 89 and convex shaping section 91 ( Figures 19 and 20 ), exclusively concave shaping section 89 ( Figure 21 ) or have exclusively convex shaping section 91.
  • the tool shank 83 of the tool 100 transitions in the longitudinal direction L from a round area 107 forming a holding section via a transition area 103 into a flat area 105 forming a pressing flank.
  • the press head 108 is equipped with a press tip/guide tip 85, which can be segmented analogously to the number of segment edges 77.
  • the axial length of the guide part 79 is matched to the inner dimension of the pipe section 4 in such a way that the tool has an outer dimension of up to 1.4 times the diameter of the cavity at the transition from the guide part 79 into the pressed part 80.
  • the part of the tool 100 that is in contact with the intermediate 3 is designed such that the axial length of the guide part 79 and/or the pressing part 80 is at least 80% of a maximum radial distance of the cavity.
  • Figure 22 shows an unsegmented press head 108 according to the invention, with an unsegmented press tip/guide tip 85.
  • a tool 100 can be seen, which has a polygonally shaped end face 97 and rectangularly shaped segment flanks 81.
  • a general advantage of the present invention is that the internal shape can be adjusted very flexibly during pipe extrusion.
  • any internal geometries with different deformation properties can be produced in a simple manner in conjunction with the press head.
  • Metals especially non-ferrous metals, have the property of becoming harder due to deformation. That is, a large deformation leads to a large increase in the hardness of the raw material.
  • hardness curves as in Figures 34 and 35 shown, one can indirectly draw conclusions about the degree of forming and the production process.
  • Fig. 34a, b and 35a, b is a sectional view of the projectile 1 according to the invention Figure 4 pictured.
  • a Vickers hardness distribution is shown on the sectional view surface, and a corresponding color scale with reference values is located between the Fig. 34a, b and 35a, b .
  • the Figures 34a and 34b represent a projectile 1, which is made from a solid material intermediate, this solid material can be, for example, a wire section and is cylindrical, the material is also holeless, which is why it is also called a solid intermediate.
  • the Figures 35a and 35b represent a projectile 1 made from a tube
  • the tubular intermediate 3 preferably consists of a tube section 4 made from the tube, whereby the tube can be either in rod form or wound up and is separated by machining or by cutting, squeezing or grinding.
  • the Figures 34a and 35a show the hardness distribution of a projectile 1, manufactured from hard intermediate material.
  • the projectile 34a is made of solid intermediate material
  • the projectile in Figure 35a is made from a tubular intermediate 3 with wall thickness a.
  • the Figures 34b and 35b show the hardness distributions of a projectile made of soft copper.
  • the projectile 34b is made of a solid material intermediate manufactured, the projectile in Figure 35b is made from a tubular intermediate 3 with wall thickness a.
  • Fig. 34a, b and 35a, b is to be understood as meaning that the absolute material hardness according to Vickers was determined on the finished projectile 1.
  • the selected copper hardnesses differ measurably from one another; this can be done with non-destructive material testing, for example ultrasound, or with destructive material testing, for example with indenters. Such differences in hardness can arise due to different alloys, different raw material production or different post-processing, such as annealing.
  • the hardness values of the tip 29 and the hardness values of the projectile front 53 of the projectile 1 are increased compared to the rest of the projectile body 13. Due to the reduced deformation during the pressing process, the projectiles 1, which are made from the tubular intermediate 3, are softer in the area of the guide band 63, compared to the projectiles which are made from a solid material intermediate, also called a wire blank. This softer area has a positive influence on the barrel life of the firearm and results in a longer tool life for the die 7 and the tool 100. A soft intermediate area of the projectile 1 is particularly relevant for long tool life. The softer the intermediate area of the final projectile 1 remains due to the previous operations, the less forming work the tools had to do during the operations. This results in a longer tool life. Accordingly, a conclusion can be drawn about the tool life from the hardness curve in the pipe projectile according to the invention.
  • the area of the tip 29 marks all projectiles in the Figures 34 and 35 the hardest part due to the high degree of forming.
  • hard copper there is a Vickers hardness of approx. 230 HV in the area of tip 29, regardless of the type of intermediate.
  • soft copper it is approx. 170 HV, regardless of the intermediate type.
  • a second increase in hardness can be seen in the area of the cavity base section 57.
  • the projectile 1 which was made from the tubular intermediate 3 ( Figure 35a, b ) an increase in hardness can be seen from the cavity base section 57 through the floor to the rear constriction 11.
  • the blank consists of a solid intermediate material ( Figure 34a, b )
  • the increase in hardness can be seen particularly on the cavity base section 57.
  • the floor 17 of the projectile 1 made from the tubular intermediate 3 has an average hardness which corresponds to at least 103%, in particular at least 105%, of the average hardness if the projectile 1 were made from a solid material and holeless intermediate. This increase in hardness has a positive influence on the ability of the firing shock to withstand, which leads to improved ballistics.
  • the average hardness in the area of a jacket area of the tail of the projectile 51 surrounding the cavity 45 corresponds to at most 90%, in particular at most 85% or at most 80%, of the average hardness if the projectile 1 were made from a solid material, i.e. a solid and holeless intermediate. This has a positive effect on the load on the firearm barrel.
  • the projectile 1 based on the tubular intermediate 3 has an average hardness at the tail of the projectile 51 of at least 140%, in particular at least 150% or at least 160%, which corresponds to the average hardness if the projectile were made from a solid intermediate.
  • the average hardness in particular of the cylindrical region of the guide band 63 of the projectile 1 based on the tubular intermediate 3, is softer over the entire diameter, in particular at least 10%, at least 15% or at least 20%, softer than the average hardness when the projectile 1 would be made from a solid and holeless intermediate.
  • the projectiles 1 made from pipe intermediate 3 are hard and inhomogeneous, particularly in the area of the tail constriction 11.
  • This inhomogeneity of the hardness curve in the tail of the projectile 51 has the technical effect of stiffening the floor of the projectile 17, which has a positive effect on the internal ballistics during the acceleration process of the projectile 1.
  • the hardening of the tail constriction 11 of the tail of the bullet also creates a kind of predetermined breaking point, which reduces excess hydrodynamic pressure when penetrating the gelatinous mass of the wound ballistics and stabilizes the projectile during penetration.
  • a subdivision of the hardness levels is in Fig. 34a and Fig. 35a visible.
  • the reference symbol w indicates zones with low hardness 120 HV.
  • the reference symbol m indicates zones with medium hardness, approx. 190 HV.
  • the reference symbol h denotes zones of the projectile 1 with increased hardness, approximately 230 HV.
  • the surfaces enclosed by w represent the guide band 63 of the projectile 1 and, due to their soft design, can perform the function of reducing the press-through resistance through the firearm barrel.
  • the hard zones on the bow wall 41 and the tail constriction 11 define the projectile according to the invention
  • Fig 35a the deformation properties.
  • the transition region also called the medium-hard zone m, prevents the segment vanes 111 from tearing off in the projectile 1 according to the invention, made from a tubular intermediate 3.
  • the hardness zones in Project 1 made from a solid intermediate material only have limited ballistically optimized properties.
  • the medium-hard zone m extends up to the guide band 63.
  • the hard zone h extends over the bending point of the segment flags 111.
  • the soft zone w is located exclusively in floor 17.
  • the projectiles 1, which are made from the tubular intermediate 3 differ from those which are made from solid material intermediates in that the projectile front 53 has a shorter transition phase starting from the hard tip 29 with respect to the soft guide band 63.
  • the hard bullet front 53 begins to become softer towards the rear of the bullet after approx. 2/3 of the ogive section and approaches the initial hardness of the intermediate.
  • the bullet, made from solid material has an evenly distributed hardness on the projectile front 53; only after the section of the projectile front 53 does the transition phase of the hardness begin, which extends over the entire guide band 63.
  • the technical effect of the short hardness transition phase in the floor front 53 according to Figure 35 is that the segment flags 111 can bend to the maximum without cracks occurring in the bent segment flags 111. Unloaded or unhardened material can usually be deformed/bent more without damage than loaded material.

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  • Chemical & Material Sciences (AREA)
  • Combustion & Propulsion (AREA)
  • Physics & Mathematics (AREA)
  • Thermal Sciences (AREA)
  • Manufacturing & Machinery (AREA)
  • Mechanical Engineering (AREA)
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EP23173741.2A 2022-05-24 2023-05-16 Outil et procédé de fabrication d'un projectile et projectile Pending EP4283245A1 (fr)

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Citations (5)

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Publication number Priority date Publication date Assignee Title
WO1990005891A1 (fr) * 1988-11-14 1990-05-31 Karl Klaus Mayer Projectile deformable, munition equipee de celui-ci, ainsi que procede de fabrication dudit projectile
US5131123A (en) * 1989-06-29 1992-07-21 Barnes Bullets, Inc. Methods of manufacturing a bullet
DE102016015790A1 (de) * 2016-08-05 2018-03-29 Ruag Ammotec Gmbh Metallisches Vollgeschoss, Werkzeug-Anordnung und Verfahren zum Herstellen von metallischen Vollgeschossen
DE102017011359A1 (de) 2017-12-08 2019-06-13 Ruag Ammotec Gmbh Intermediat zum Fertigen von Projektilen eines Deformationsgeschosses, Projektil, deformiertes Projektil, Werkzeug zum Fertigen des Intermediats und Verfahren zum Herstellen des Intermediats
DE102019135875A1 (de) * 2019-12-30 2021-07-01 Ruag Ammotec Ag Vollgeschoss, Intermediat zum Fertigen eines Vollgeschosses und Verfahren zum Herstellen eines Vollgeschosses

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Publication number Priority date Publication date Assignee Title
US2045964A (en) 1934-12-13 1936-06-30 Berlin Karlsruher Ind Werke Ag Casing projectile
US5943749A (en) 1997-11-04 1999-08-31 The Nippert Company Method of manufacturing a hollow point bullet
BRPI0418281A (pt) 2004-02-06 2007-05-02 Companhia Brasileira De Cartuc projétil de expansão monobloco isento de chumbo e respectivo processo de fabricação
DE102019116125A1 (de) 2019-06-13 2020-12-17 Ruag Ammotec Gmbh Projektil, insbesondere Deformations- und/oder Teilzerlegungsgeschoss, und Verfahren zum Herstellen eines Projektils
DE102020105266B4 (de) 2020-02-28 2021-09-30 Ruag Ammotec Gmbh Projektil, Diabolo, Munition und Verfahren zum Herstellen eines Projektils
DE102021104757A1 (de) 2021-02-26 2022-09-01 Ruag Ammotec Ag Metallisches Übungspatronen-Geschoss

Patent Citations (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
WO1990005891A1 (fr) * 1988-11-14 1990-05-31 Karl Klaus Mayer Projectile deformable, munition equipee de celui-ci, ainsi que procede de fabrication dudit projectile
US5131123A (en) * 1989-06-29 1992-07-21 Barnes Bullets, Inc. Methods of manufacturing a bullet
DE102016015790A1 (de) * 2016-08-05 2018-03-29 Ruag Ammotec Gmbh Metallisches Vollgeschoss, Werkzeug-Anordnung und Verfahren zum Herstellen von metallischen Vollgeschossen
DE102017011359A1 (de) 2017-12-08 2019-06-13 Ruag Ammotec Gmbh Intermediat zum Fertigen von Projektilen eines Deformationsgeschosses, Projektil, deformiertes Projektil, Werkzeug zum Fertigen des Intermediats und Verfahren zum Herstellen des Intermediats
DE102019135875A1 (de) * 2019-12-30 2021-07-01 Ruag Ammotec Ag Vollgeschoss, Intermediat zum Fertigen eines Vollgeschosses und Verfahren zum Herstellen eines Vollgeschosses

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