This invention relates to an ammunition cartridge, in particular for rifles and firearms.
Conventional ammunition cartridges for firearms and guns of various sizes and purposes typically comprise a brass casing containing a propellant charge in the form of powder or granules of an explosive substance, and a projectile assembled in a gripping fit at an open tubular sleeve end of the casing. Although various ignition systems have been developed, the most common ignition systems for ammunition cartridges comprise an ignition charge mounted in a primer cap located on the casing base wall that ignites upon impact by a firing pin of the weapon. The ignition charge ignites the propellant charge whereby during the explosion the projectile is accelerated in the barrel of the weapon. Since the ignition of the propellant starts from the base wall of the cartridge, propellant powder is ejected from the casing during combustion, a portion of the propellant substance finishing its combustion in the barrel chamber of the weapon.
The pressure generated by combustion of the propellant substance must not exceed a certain level in order to prevent damage to the weapon. In many conventional weapons the pressure generated by the combusting propellant should not exceed around 4000 bars. This limits the propulsion force that the propellant charge can impart. Moreover, in conventional ammunition cartridges, the propellant is often not optimally consumed. Due to the projection of propellant substance out of the casing the combustion of the substance occurs at lower temperatures. It also may depend to a certain extent on the characteristics of the weapon, in particular manufacturing tolerances and wear that influences the fit between the projectile and the barrel chamber and the fit between the casing and the combustion chamber.
Although ammunition cartridges are manufactured in very large quantities, the brass casings are relatively costly to manufacture. Conventional casings are made of a single deep drawn piece of brass or steel and filled from the open end with propellant in powder form before fitting the projectile.
In view of the foregoing it is an object of the invention to provide an ammunition cartridge with improved performance, in particular that allows to generate a high and well controlled acceleration of the projectile without exceeding the chamber pressure tolerance.
It is advantageous to provide an ammunition cartridge that is economical to manufacture in large quantities, and to provide a method and tools for enabling the aforegoing.
It is advantageous to provide an ammunition cartridge that is light, compact, and uses less materials for a given performance, and to provide methods and tools for enabling the aforegoing.
It is advantageous provide improved ammunition cartridges that can be used in existing weapons.
Objects of this invention have been achieved by providing the ammunition cartridge according to claim 1.
Objects of this invention have been achieved by providing the method of producing an ammunition cartridge according to claim 23.
Objects of this invention have been achieved by providing a tool mechanism for producing an ammunition cartridge according to claims 29 and 31.
Dependent claims recite various advantageous features or variants.
Disclosed herein, according to an aspect of the invention, is an ammunition cartridge comprising a rigid casing including a tubular sleeve and a base closing an end of the casing, a projectile mounted at another end of the casing, a propellant charge contained inside the casing, and an ignition device, wherein the ignition device comprises an ignition charge arranged to ignite the propellant charge at a point of ignition distal from the base and proximal the projectile.
In an advantageous embodiment, the ignition device comprises a movable transmission pin extending from the base to the ignition charge positioned proximal the projectile, the transmission pin being actuable by means of a firing pin or hammer, which may be of a conventional weapon, impacting an ignition cap on the base wall.
In an advantageous embodiment, the ignition charge is positioned in an ignition cap located at the base of the cartridge and the ignition device comprises a guide channel configured to channel the deflagration effect of an ignition charge under combustion to one or more nozzles at an ignition end of the guide channel proximal the projectile, the ignition charge located in the cap being actuable by means of a firing pin or hammer, which may be of a conventional weapon, impacting the ignition cap on the base wall.
In an advantageous embodiment, the propellant charge comprises a plurality of portions of different composition or properties with different combustion characteristics.
In an embodiment, at least two of said portions of propellant charge have different densities.
In an embodiment, at least two of said portions of propellant charge have different chemical compositions.
In an advantageous embodiment, any one or more of the propellant charge portions comprise components that retard and/or accelerate the combustion process.
In an embodiment, at least two charge portions are separated by at least one combustion speed regulation material selected to either retard or to accelerate combustion.
In an advantageous embodiment, the propellant charge is in a solid self-supporting preform.
In an advantageous embodiment, the propellant charge comprises a concave face facing towards the point of ignition.
In an advantageous embodiment, the propellant charge solid self-supporting preform comprises a combustion powder held together with a binding material.
In an advantageous embodiment, the binding material is selected from a group consisting of a starch-based material, a polymer based material, a curable polymer, a thermosetting polymer, a thermoplastic polymer, or a gelatin material.
In an embodiment, the propellant charge solid self-supporting preform comprises an outer supporting layer.
In an advantageous embodiment, the ammunition cartridge further comprises a projectile booster charge positioned adjacent a trailing end of the projectile, the point of ignition of the projectile booster charge positioned adjacent the ignition device such that the projectile booster charge is ignited simultaneously or before the propellant charge is ignited.
In an advantageous embodiment, the projectile comprises a booster charge located in the base of the projectile positioned adjacent the ignition device such that it is ignited simultaneously or before the cartridge propellant charge is ignited.
In an advantageous embodiment, the ignition charge and the booster charge are located adjacent to each other at the base of the projectile such that the booster charge located in the projectile is ignited simultaneously or before the propellant charge is ignited.
In an advantageous embodiment, the projectile booster charge is positioned in a cavity in the trailing end of the projectile.
In an advantageous embodiment, the point of ignition is separated by a thin protective film from the propellant charge.
In an advantageous embodiment, the casing is made of at least two parts including the base and the tubular sleeve that are assembled together.
In an advantageous embodiment, said base and tubular sleeve are welded.
In an advantageous embodiment, the ammunition cartridge further comprises a thermal insulator positioned between the base and the propellant charge.
In an embodiment, the projectile comprises aerodynamic tail fins at a trailing end of the projectile.
Also disclosed herein, according to another aspect of the invention, is a method of producing an ammunition cartridge comprising a rigid casing a projectile, a propellant charge and an ignition device, comprising:
(i) forming the propellant charge in a solid self-supporting preform,
(ii) separately forming a tubular sleeve of the casing and a base of the casing,
(iii) inserting the solid preform propellant charge and the ignition device in the tubular sleeve through a base end of the tubular sleeve and assembling the base to the tubular sleeve,
(iv) assembling the projectile to the tubular sleeve.
In an advantageous embodiment, the ignition device comprises a transmission pin and an ignition cap assembled to said base prior to assembly of the base to the tubular sleeve.
In an advantageous embodiment, the propellant charge is assembled to the ignition device prior to assembly in the tubular sleeve.
In an advantageous embodiment, the ignition device comprise an ignition pin embedded in the propellant charge prior to assembly in the tubular sleeve, the transmission pin extending from the base of the casing to the ignition charge positioned proximal or at the base of the projectile, the transmission pin being actuable by means of a firing pin or hammer, which may be of a conventional weapon, impacting an empty ignition cap located on the base of the casing.
In an advantageous embodiment, the forming of the propellant charge comprises adding a binder material to a combustible propellant substance in powder form and binding the powder in a mold die comprising a shape of the preform.
In an advantageous embodiment, assembling the base to the tubular sleeve comprises welding the base to the tubular sleeve.
In an advantageous embodiment, forming the tubular sleeve includes the operations of:
(i) inserting a tool insert assembly inside a cylindrical tube, the tool insert assembly having a portion with a shape corresponding to an internal shape of the cartridge casing and formed of at least two parts including a shaping insert and a support pin that slidably inserts into a central passage of the shaping insert, the shaping insert comprising a radially compressible body portion that allows the shaping insert to move elastically radially inwardly when the support pin is removed,
(ii) compressing the tubular sleeve to deform it against the tool insert assembly,
(iii) withdrawing the support pin and subsequently withdrawing the shaping insert.
Also disclosed herein, according to another aspect of the invention, is a tool mechanism for forming a casing of an ammunition cartridge, comprising a tool insert assembly having a portion with a shape corresponding to an internal shape of the cartridge casing, the tool insert assembly formed of at least two parts including a shaping insert and a support pin that slidably inserts into a central passage of the shaping insert, the shaping insert comprising a radially compressible body portion that allows the shaping insert to move elastically radially inwardly when the support pin is removed.
In an advantageous embodiment, the support pin comprises a bore finishing tool portion having cutting edges to machine an inside diameter of a neck portion of the casing upon withdrawal of the support pin.
Also disclosed herein, according to another aspect of the invention, is a tool mechanism for forming a rigid casing of an ammunition cartridge, the casing comprising a base and a tubular sleeve, the tool mechanism configured to form longitudinal grooves in the tubular sleeve to increasing buckling resistance, comprising a swaging operation that generates longitudinal grooves in a flat metal band and a folding operation to fold the metal band into a tube, a longitudinal seam of the tube, formed by longitudinal edges of the metal band coming together, being subsequently welded. The metal band may advantageously be made of steel, instead of brass conventionally used in ammunition cartridges, to reduce costs and weight of the ammunition cartridge.
Further objects and advantageous aspects of the invention will be apparent from the claims, and from the following detailed description and accompanying figures.
The invention will now be described with reference to the accompanying drawings, which by way of example illustrate embodiments of the present invention and in which:
Referring to the figures, an ammunition cartridge 2 comprises a casing 4, a projectile 6, an ignition device 8, and a propellant charge 10. The projectile 6 may have various materials and geometric properties that are per se known in the field of ammunition cartridges and has a diameter configured for a barrel chamber of a weapon. The ammunition cartridge outer shape and dimensions may be configured to conform to a standard size for use with existing weapons, in replacement of existing ammunitions cartridges. The enclosed illustrations and following description are not intended to be limited to any particular caliber of ammunition, it being understood that the principles underlying the invention may be implemented in ammunition cartridges of various dimensional specifications.
The casing 4 generally has a cylindrically shaped tubular sleeve 16 closed at one end by a base 14 at the opposed open end receiving the projectile 6. The projectile receiving end, as is well-known in the art, comprises a neck portion 38 connected via a tapered portion to a major portion 37 of the tubular sleeve portion containing the propellant charge 10, the neck portion 38 having a smaller diameter than the major portion 37. The outer shape of the base may have various configurations depending on the weapon with which it is intended to be used, and may for instance typically comprise a rim 34 and annular groove 36 that serve to eject the casing from the firing chamber of the weapon as is per se well-known in the art.
In an embodiment of the present invention, the casing 4 may be made of a single piece part, for instance a single piece metal part, according to conventional manufacturing processes.
In an advantageous embodiment, the casing may be made of two or more parts, with at least a cylindrical body or sleeve and a base, that are assembled together, by welding, soldering, crimping or other per se known assembling techniques. The multi-part casing allows assembly of the propellant charge 10 into the casing tubular sleeve from the base end 33 before assembly of the base 14 to the tubular sleeve 16, or in a conventional manner from the open neck end 35 once the multi-part casing is assembled. In the embodiment illustrated in
The propellant charge 10 may be in the form of powder or granules as per se known in the art. In an advantageous embodiment according to this invention, the propellant charge is bound in a preform that forms a solid body insertable into the tubular sleeve 16 of the casing 4. The preform may comprise a combustible substance bound together with a binding material.
Various substances with binding properties may be used such as resins, plastics, or asphaltics that hold together a charge of finely divided particles and increase the mechanical strength of the resulting propellant block.
The propellant that has exclusively been used for a long time in conventional military weapons is the so-called smokeless powder or “Gun Powder”. Whether single-base powder (e.g. nitrocellulose), double-base powder (e.g. nitrocellulose plus nitroglycerine) or triple-base powder (e.g. nitrocellulose plus nitroglycerine plus nitroguanidine) these propellants undergo a variety of manufacturing processes providing a pasta-like colloidal mixture of thermoplastic behavior that can be extruded through a variety of dies or mechanically pressed into forms.
The more recent development of low-vulnerability ammunition (LOVA) has led to the use of plastic propellants. They are embedded in curable plastics, thermoset materials, thermoplasts or gelatinizers to form a mixture that can be given various shapes by means of hydraulic mold presses and cutting machines for example. LOVA powders correspond to the traditional Gun Powders and can be adapted according to the desired ballistic characteristics. Propellants can also be mixed with or embedded in various curable or poly-additive plastics such as polysulfides, polyurethane, acrylic acid and the like, or mixed with Silicon, petroleum jelly or gelatinized compounds of plastiline like consistency and given a variety of desired forms. Pre-forming may not be limited to the external dimensions and shapes, it can also include embedded details such as cylindrical or conical apertures that increase the combustion surface and contribute in the steady production of gas.
The propellant charge preform may be formed as an individual component that is inserted and assembled to the other components of the ammunition cartridge. In a variant, the propellant charge preform may be formed directly within the cylinder portion of the casing. In a variant, the propellant charge preform may be formed around the ignition device before assembly into the casing. In a variant, propellant charges can be filled in the casing between pre-inserted thin discs or cylindrical walls that have been forced in the casing shell and act as separators. When the propellant is of granular, gelatinous or viscous nature, the preform may also be surrounded partially or fully by a coating, film or thin layer of material that keeps or helps to keep the preform in its intended shape for assembly. The layer of material may for instance be polymer based, paper based, starch based, or gelatinized. In the latter variants, the propellant charge within the center of the preform may be generally loose or held together with a binder material.
The principle purpose of the preform is to allow assembly within the casing, however depending on the embodiment, the binding properties of the preform do not necessarily need to withstand transport and shock once the ammunition cartridge has been fully assembled.
Although the projectile 6 may adopt an essentially conventional shape and use conventional materials as per se well-known in the art, according to an advantageous embodiment of the invention allowing a larger free space inside the cartridge, the projectile may comprise tail fins 64 on the trailing side of the projectile. The fins are configured aerodynamically to provide stable flight to the projectile for use with a weapon with a smooth barrel chamber. In a variant, the fins may be configured to impart a rotational spin to the projectile for use with a smooth barrel chamber of a weapon.
According to an advantageous aspect of the invention, the ignition device comprises a point of ignition 23 that is at a position distal from the base 14 and proximate the projectile 6.
In an embodiment, the ignition device 8 extends from an actuation end 54 positioned on the base 14 of the casing 4, to an ignition end 24 forming the point of ignition that is positioned distal from the base and proximate the projectile 6, configured to ignite the propellant 10 at a position distal from the base 14 and proximate the projectile 6.
According to this aspect of the invention, the propellant thus combusts starting from a position proximate the projectile 6 and thus proximate the neck portion 38 of the casing to generate gas, the direction of combustion moving like in a rocket engine from the projectile end 35 towards the base such that combustion of the propellant occurs within the casing 16 because the pressure generated will oppose the un-combusted propellants from moving into the barrel as this is the case when ignition occurs in the base part of the cartridge.
According to embodiments of the invention, preventing un-combusted propellants to move into the barrel very advantageously ensures a better control of the combustion and the projectile acceleration process. Since un-combusted propellant is not projected into the barrel chamber of the weapon its combustion does not occur at a lower temperature and it does not absorb part of the kinetic energy transferred to the projectile within the barrel chamber. As the combustion of the propellant occurs essentially within the casing, the projectile is displaced in the barrel with a greater rate of progression than with a conventional ignition starting from the base wall. Since the propellant (which would otherwise be displaced in a conventional ignition) can represent a two-digit percentile of the total mass propelled in the barrel, the projectile according to embodiments of the invention, receives an additional propulsion of corresponding kinetic energy. This can either be useful to increase the speed of the projectile, or for a projectile to be propelled at a given speed, to reduce the volume of the propellant charge required and thus if wanted, the size of the ammunition cartridge.
Ignition of the propellant charge 10 at a position proximal the projectile 6 may be achieved in various manners according to embodiments of the invention. In an embodiment as schematically illustrated in
In a variant illustrated in
The ignition device may further comprise a cap 61 as illustrated in
In a variant similar to the embodiment illustrated in
Referring now to
In variants, the ignition device may be activated by other means than by a firing pin. For instance, electrical or electromagnetic trigger mechanisms have been developed and are known in the art, such means also being implementable in the present invention for igniting the ignition charge 56.
Referring now to the embodiments illustrated in
A mathematical simulation of the interior ballistic presented in
The different charge portions 10a, 10b, 10c, 10d may either be made of different materials or be made of the same material but with different properties such as density of packing constituted to influence the rate of combustion and production of gas from the combusting propellant substance.
The propellant charge portions may also have components that retard or accelerate the combustion process. In a variant as illustrated in
In general, it will be desirable to have a generally increasing rate of production of gas from the initial charge portion 10a towards the subsequent charge portions 10b, 10c, 10d in order to maintain a high substantially constant gas pressure within the expanding chamber behind the projectile as it accelerates along a gun barrel chamber. As the combustion of the hybrid charges 10b, 10c, 10d occur when the projectile is further down the barrel, they dispose of much a larger volume than in the case of a single charge. They can generate a much higher gas quantity without exceeding the pressure tolerance of the weapons as shown in
In an advantageous embodiment, the first charge portion 10a immediately adjacent the ignition end 24 of the ignition device 8 may be advantageously provided with a curved or concave face 32 directed towards the ignition end in order to promote a more evenly distributed spatio-temporal ignition of the propellant charge. The curvature of the front face of the propellant charge is essentially designed to receive the thermal energy of the ignition process at a substantially even time. Such a configuration is possible with a propellant charge that is in a solid preform as previously discussed.
Although the propellant charge portions discussed here are illustrated as distinct separate portions, it will be appreciated that in variants it is possible to have a continuous transition of material properties or composition configured to change the rate of combustion and gas production.
In an embodiment, as illustrated in
Referring now to
In an embodiment, the ignition charge 56 is positioned adjacent the projectile booster charge 12 such that it is ignited before the main propellant charge 10 is ignited.
The booster charge 12 serves to propel the projectile in its initial displacement out of the cartridge casing 4, and optionally into the barrel (not represented here), subsequently followed by the ignition of the main propellant charge 10 generating the combustion gas that accelerates the projectile during its travel in the barrel of the weapon. The ignition charge 56 may be separated by a thin film 48 from the propellant charge 10 in order to ensure that the booster charge 12 is ignited simultaneously or prior to the ignition of the propellant charge 10.
As illustrated in
The use of the ignition charge 56, with or without a projectile booster charge 12, to eject the projectile from the cartridge casing 4 and to force it in the barrel plays an advantageous role in the interior ballistic process. It provides the main propellant charge 10, or the first block of hybrid charges 10a, a much larger initial volume that helps reducing significantly the peak pressure generated by the combustion. As illustrated by the simulation presented in
In a variant, the projectile booster charge may be included in or incorporated with the ignition charge 56 that may thus function as both a projectile booster charge and an ignition charge to ignite the propellant charge 10.
Referring to
In the illustrated embodiment, a casing forming tool mechanism 3 comprises a tool die 5 having a cavity portion with a shape corresponding to the outer shape of the ammunition cartridge casing 16, and a tool insert assembly 7 having a portion with a shape corresponding to an internal shape of the cartridge casing 16.
The tool insert assembly 7 according to an aspect of the invention is advantageously formed of at least two parts, a shaping insert 9 and a support pin 11 that slidably inserts into a central passage of the shaping insert 9. The shaping insert 9 comprises a radially compressible body portion 13 that allows the shaping insert 9 and in particular the tapered end portion thereof to compress radially inwardly to facilitate retraction of the insert from the tool die 5 after the casing tubular sleeve has been formed. Without the radially compressible shaping insert, extraction of the tool insert assembly from the tool die 5 may be very variable and difficult due to the inherent elasticity of the casing material. When the support pin 11 is inserted in the central passage of the shaping insert 9, the radially compressible shaping insert 9 becomes rigid and dimensionally accurate and the tool insert assembly 7 can be used for insertion within the tool die 5 to provide an accurate forming of the casing taper 40 and neck portions 38 as shown in
Turning now to
Referring to
Referring to
Embossing the grooves can be achieved by means of two counter rotating forming drums 83 with annular ribs 85 or they can be achieved by a standard press with appropriate stamping dies. Adding the stiffening grooves 80 to the band 81 increases the axial buckling resistance of steel band cartridge cylinders (tubular sleeves) and allows shaping them with an axial press as this is currently done with pressed cartridge bodies.
Without stiffening grooves, thin walled cylinders tend to buckle under axial pressures and require using supporting inserts as described previously. Axial buckling resistance is important because conventional ammunition presses offer, as to date, the highest production rates. In addition, stiffening grooves improve also the mechanical resistance to lateral shocks. Under the high pressures generated by the combustion of the propellant charge these groves also improve the radial elasticity of the cartridge casing, allowing it to press against the weapons combustion chamber. Since the plastic deformation of the cartridge can be reduced, if not avoided, a certain radial elasticity is recoverable as the pressure drops and the empty cartridge detaches itself from the combustion chamber, allowing its easier extraction form the weapon.
Number | Date | Country | Kind |
---|---|---|---|
01493/17 | Dec 2017 | CH | national |
00100/18 | Jan 2018 | CH | national |
00521/18 | Apr 2018 | CH | national |
PCT/IB2018/054608 | Jun 2018 | IB | international |
Number | Date | Country | |
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Parent | 16769470 | Jun 2020 | US |
Child | 17474877 | US |