This document discloses a projectile body and corresponding ammunition round for small arms or a light firearm. To provide context, the term “small arms” is intended to denote firearms used by an individual including for example pistols, rifles, submachine guns, assault rifles and light machine guns; while the term “light firearm” is intended to denote a “firearm” designed for use by two or more persons serving as a crew and may include heavy machine guns, and anti-aircraft guns all being less than about 100 mm in calibre.
A round of ammunition for small arms or a light firearm typically comprises a case and a projectile. The case has one end which is crimped onto the projectile. An opposite end of the case is formed with a planar base wall that seats a primer. A volume of propellant is held within the cartridge between the projectile and an inside of the planar base wall. When the ammunition round is used, the primer is initiated usually mechanically by striking with a firing pin. This in turn causes deflagration of the propellant. Deflagration of the propellant results in the rapid generation of a large volume of gas. This gas expels the projectile from the case and propels the projectile through the barrel of the small arms or light firearm. The case may be expelled either automatically or manually. Ammunition has also been proposed which does not comprise a case. This is sometimes known as caseless ammunition. An example of such ammunition is set out in U.S. Pat. No. 2,307,369 (Ferrel). This discloses a round of ammunition comprising a caseless projectile having a body defining a cavity which is filled with a propellant charge. One end of the projectile is closed by an integral nose while an opposite end is closed by a firing cap. A soft metal jacket or sleeve is applied to the exterior of the projectile. The jacket is provided with shoulders that are configured to: engage with rifling of a barrel of a firearm; or, seal against the bore of a smooth bore firearm from which it is fired.
A projectile body and a corresponding ammunition round are disclosed. The round of ammunition may be used with or without a case. One general idea behind the disclosed projectile body and ammunition is to facilitate an equalisation of pressure between a portion of a length of the outside of the round and the inside of a barrel of a firearm from which the ammunition is fired. This is believed to reduce drag and thereby increase muzzle velocity. Additionally, this pressure equalisation allows for the use of a wider range of materials of construction than if the equalisation of pressure is not possible. The structure of the projectile body is in substance the same irrespective of whether the corresponding round is cased or caseless. Provision of a case easily adapts the round to be used with conventional small arms and light firearms without need of any modification to the firearm.
For ease of description throughout the remainder of this specification including the claims the term “firearm” is to be used to denote both small arms and light firearms as defined herein above. Thus, and in order to remove any doubt, the term “firearm” is intended to denote a firearm designed for use by two or more persons serving as a crew and may include heavy machine guns, and anti-aircraft guns all being less than about 100 mm in calibre; and pistols, rifles, smoothbore firearms, submachine guns, assault rifles and light machine guns. Also the terms “round”, “ammunition”, “round of ammunition” and “ammunition round” are all intended to have the same meaning and define a ready to fire assembly of components comprising a projectile body, a charge of propellant, a primer and optionally a case.
In one aspect there is disclosed a projectile body for an ammunition round for small arms or light firearm, the projectile body being elongated and comprising:
In one embodiment the projectile body comprises a plurality of holes wherein the holes are spaced about the longitudinal axis of the body.
In one embodiment each of the one or more holes has an outer opening on the seal bound outer surface portion and an inner opening that opens into the cavity and wherein for at least one of the holes the outer opening of that hole is closer to the first end than the inner opening of that hole.
In one embodiment the one or more holes are provided with temporary sealing devices. The temporary sealing devices may comprise one of (a) a frangible seal, (b) a seal arranged to eject from the holes, or (c) a seal arranged to melt or combust; all by action of deflagration of propellant held in the cavity.
In one embodiment when the cavity holds propellant comprising a plurality of grains of a solid propellant each hole is arranged to have a diameter at least at one point between the cavity and the seal bound outer surface portion that is no greater than about three times an average grain size of propellant.
In one embodiment the body comprises a boat tail portion located between an end of the seal bound outer surface portion of the body and the second end.
In one embodiment the first end terminates with a planar surface perpendicular to the longitudinal axis.
In one embodiment the first end terminates in a point being coaxial with the longitudinal axis.
In one embodiment the first end comprises a ballistic soft tip coupled with the first end of the body.
In various embodiments the cavity is a single cavity for holding the propellant and has a longitudinal center line co-axial with longitudinal axis of the body.
In all embodiments the projectile body may optionally comprise a sleeve disposed in the cavity and wherein the one or more holes extend through the sleeve into the cavity, wherein propellant for propelling the projectile body is held in the sleeve.
In all embodiments the projectile body may be arranged such that a spacing L between outer most points of two axially most spaced apart seals satisfies the relationship L≥D, where D is the diameter of the maximum of diameter of the projectile body.
In a second aspect there is disclosed an ammunition round comprising:
In a third aspect there is disclosed an ammunition round comprising:
In some embodiments of the ammunition round of the third aspect, the case and the projectile body are relatively dimensioned so that the case at least partially overlies at least one seal on the projectile body. Thus in such embodiments the case may for example: wholly overlie or cover every seal; or, leave wholly exposed a forward most seal and completely overlie or cover all other seals; or partially cover a forward most seal and completely overlie or cover all other seals.
However in alternate embodiments of the ammunition round of the third, the case and the projectile body are relatively dimensioned so that every seal on the projectile lies outside of the case.
In one embodiment of the ammunition round of the second or third aspects, the quantity of propellant is such that substantially the entire cavity is filled with the propellant. However in alternate embodiments of the third aspect a portion of the propellant is in the cavity and another portion of the propellant is between the second end of the projectile and the one end of the case.
In some embodiments of the third aspect the projectile and the case are relatively dimensioned such that a space is formed between the second end of the projectile body and the base of the case and the propellant is retained between an inner surface of the cavity and the base of the case. In one form of such embodiments the propellant is provided in a volume greater than that of the space so that at least a proportion of the propellant is held in the cavity. However in an alternate form of such embodiments the propellant is provided in a volume to substantially fill the space and the cavity.
Notwithstanding any other forms which may fall within the scope of the projectile body and corresponding ammunition round as set forth in the Summary specific embodiments will now be described, by way of example only, with reference to the accompanying drawings in which:
The round 10 comprises a projectile 14 having an elongated body 16 with a first end or tip 18 and an axially opposed second end 20. The tip 18 constitutes the leading end of the round 10 and is closed. A cavity 22 is formed in the body 16 and extends from an inside of the tip 18 to the second end 20. A quantity of propellant 24 is held within the cavity 22 for propelling the projectile. In one embodiment (for example the embodiment of
The projectile body 16 is provided with a seal arrangement which in the illustrated embodiments is constituted by a plurality of seals 26a, 26b, 26c and 26d (hereinafter referred to in general as “seals 26”) that extend about an outer surface 30 of the body 16. Each seal 26 protrudes radially from the body 16 to form a substantial seal against an inner circumferential surface 32 of the barrel 12. The seals 26 in this embodiment are arranged in two sets of two seals where the seals in a set are spaced relatively closely to each other, but the sets are spaced apart by a greater distance. Specifically the seals 26a and 26b form a first set of seals; and seals 26c and 26d form a second set of seals.
The seal arrangement preforms various functions including: creating a seal between the body projectile 16 and the barrel 12 to stop pressure escaping forward of the projectile; stabilize/support the projectile 14 near its front and rear as it travels down the barrel 12; minimise drag down the barrel 12; and, for a cased embodiment of the round 10, support the projectile body 16 in the case. At least two seals are required to perform all of these functions, one at or near the first end/tip 18 and a second spaced from the first seal and nearer the second end 20.
Each pair of mutually adjacent seals forms a corresponding seal bound outer surface portion of the body. For example seals 26a and 26b form a seal bound outer surface portion of the body (of a relatively short axial length); as do the pair constituted by inner most seals 26b and 26c, (of a substantially greater axial length). The seal bound outer surface portion 36 between the seals 26b and 26c accommodates one or more holes 38. The one or more holes 38 are formed in a body 16 to enable fluid communication between the cavity 22 and the seal bound outer surface portion 36.
When the round 10 is fired from a firearm the propellant 24 progressively deflagrates. The deflagration causes the rapid generation of a large volume of gas which propels the round 10 along the barrel 12. The majority of the generated gas is exhausted through the second end 20. When the round 10 is not provided with a case, this occurs by virtue of the gas either blowing out or burning through the base seal 23 fitted to the end 20. When the round 10 is used with a case, the release of gas through the end 20 initially ejects the body 12 from the case. Irrespective of whether the round 10 is cased or caseless, the pressure of the generated gas acts substantially instantaneously in all directions.
Thus gas within the cavity 22 will exert pressure on the walls of the body 16 tending to increase the outer diameter of the body 16 and pushing the surface 30 toward the surface 32. Also gas pressure acts between the inner surface 32 of the barrel from the second end 20 up to the seal 26b. However, in the region 39 between the portion 36 and the surface 32, which is sealed from the proximal end of the barrel 12, the pressure of the deflagrating gas is exerted substantially from within the cavity 22 only. (The region 39 is a dynamic region because the projectile is travelling along the barrel 12.) The provision of the holes 38 in the present embodiment allows fluid communication between the cavity 22 and the seal bound outer surface portion 36. As a result, there will be a substantial equalisation of gas pressure on opposite sides of the wall of the body 16 about the seal bound outer surface portion 36. Consequently, there is substantially no net force applied from the cavity 22 onto the corresponding portion of the body 16 that may otherwise tend to cause radial expansion of the body 16 so as to contact the surface 32. In turn this minimises the risk of increasing drag thereby maximising muzzle velocity.
Due to the equalisation of pressure arising from the provision of the holes 38 it is possible to make the body 16 from materials which may have a lower strength than those which would otherwise be required in order to resist such radial expansion. Some of these materials may have a relatively high density (e.g. lead) but in the absence of the holes 38 would need relatively thick wall to resist radial expansion. This would reduce the volume of the cavity and thus the amount of propellant 24. As the present embodiment enables the use of thinner walls it is possible to make for example the body 16 from lead without reducing the volume of the cavity 22. An alternately beneficial effect of this embodiment is that it enables the body 16 to be made from thinner walled material than would otherwise be possible in order to resist the outward radial expansion. In the first instance, where say a lower strength but higher density material is used, greater stopping power may be derived by virtue of the increased mass having regard to the kinetic energy of the projectile 14 being calculated using the equation E=½ mv2. However in the second instance where a projectile is manufactured with thinner walls and may otherwise be possible in the absence of the holes 38, increased stopping power is achieved by virtue of the lighter mass being able to accelerate more quickly and reach higher muzzle velocity. It would be recognised from the aforementioned kinetic energy equation of E=½ mv2, that improving velocity provides a squared increase in kinetic energy.
The holes 38 may be considered as pressure bleed or equalisation holes. A plurality of such holes 38 can be provided spaced about the axis 25 of the projectile 14 in such a manner as to ensure no adverse impact on the balance and stability of the projectile. For example, four holes 38 may be provided in a common transverse plane spaced 90° apart about the axis 25. The holes 38 are shown in this embodiment as circular in transverse section, but other transverse section shapes are possible such as but not limited to oval, oblong, and rectangular. In one embodiment in order to prevent or at least minimise the expelling of propellant 24 through the holes 38 during manufacture, transport, storage or an initial phase of deflagration, the holes 38 may be dimensioned to have, at least at one point between the cavity 22 and the seal bound outer surface portion 36, an internal diameter D1 that is no greater than three times an average grain size of the propellant. By dimensioning the holes 38 in this manner grains are more likely to bridge across the inner diameter of the holes 38 rather than pass through and escape from the holes 38. However the bridged grains will form pathways that allow the escape of gas through the holes 38.
If for any reason it is found necessary to form the holes larger than the above dimensions, alternative sealing arrangements of the holes may be necessary to prevent leakage of the propellant. The selection of the sealing arrangements shall be such that upon deflagration, the holes become sufficiently clear to allow the equalisation of the pressures to occur in the same manner as if the holes were unsealed. Indeed irrespective of hole diameters in other embodiments each or any hole 38 may be provided with temporary sealing arrangements or devices such as (a) a frangible seal, (b) a seal arranged to eject from the holes, or (c) a seal arranged burn away or melt; all by action of deflagration of propellant held in the cavity. A frangible seal may be a thin metal foil or plastic film; an ejectable seal may be made from of a stopper made form cellulose, wood or cork; while sealing devices that burn or melt be also be made from paper, wax, plastics, lead, or thin metal foil. The sealing arrangements or devices of course also act to retain the propellant within the cavity 22 during manufacture, handling, transport and storage. Additionally the sealing arrangements or devices can provide protection against the external environment to minimize degradation due to for example moisture absorption or oxidation.
In the present embodiment shown in
Further features and variations of the projectile 14 and corresponding round 10 will now be described.
In the depicted embodiment, the tip 18 is in the form of an ogive. The ogive has a radius R of about 2.5 times diameter D of the projectile 14. The diameter D of the round is its maximum diameter and corresponds with the calibre of the round. Thus with reference to
The seals 26 in this embodiment are formed integrally with and from the same material as the body 14. That is the seals 26 and the body 14 constitute a one piece structure. This may be achieved for example by a casting process, swaging, machining, or a combination of any or all. It is however also possible to form the seals separately from the body 14 and subsequently engage or otherwise couple the seals 26 to the body 14. For example this may be achieved by providing grooves in the body 14 and subsequently seating split ring bands in the grooves which act as the seals 26. Such seals can be made for example from a material having radial resilience or spring nature such as spring steal; or materials which are plastically deformable such as lead or copper; also it is not necessary for the seals 26 to be made from the same material as the body 16. In a further variation, the seals 26 may be made separately from the body 14 and formed as single continuous rings which are subsequently cast into the body 14. That also results in the seals 26 and the body 14 constituting a one piece structure. The core of the projectile could be clad in a material of different composition to better suit the purpose of sealing and contact with the firearm bore.
In the present embodiment the seals 26 are arranged as two pairs. A first pair of seals 26a and 26b is located adjacent or near the tip 18 while the second pair of seals 26c and 26d is spaced from the first pair in an axial direction toward the second end 20. The spacing between the inner most seals 26b and 26c defines the seal bound outer surface portion 36. In alternate embodiments, the seals may be provided as two single seals that are axially spaced along the body 14 to form the seal bound outer surface portion 36. Thus with reference to
A spacing L between outer most points of the two axially most spaced apart seals 26a and 26d will preferably satisfy the relationship L≥D. Naturally in the event of the seal arrangement comprising two sets of two or more seals, as in the specific embodiment shown in
Although in some cases L<D is possible, for stability of the projectile 10 as it travels down the barrel 12 it is believed the outer most seals 26a and 26d should be separated by at least one diameter of the projectile 14. In other embodiments, this spacing may be equivalent to the length of the parallel sides of the body 16. In this regard, it will be noted from
When the seals are provided as sets of two seals 26a, 26b; and 26c, 26d the spacing between each seal in its respective set may be in the order of the axial length of each seal.
It will be noted that in this embodiment the forward most or leading seal 26a is formed with a rounded leading face being a contiguous portion of the tip 18 with a change in radius of curvature. A trailing face 40 of the seal 26a forms a right angle shoulder with the outer surface 30 of the body 16. Each of the seals 26b, 26c and 26d has a circumferential outer surface of constant radius and is formed with right angle leading and trailing faces 42 and 44 (shown in relation to seal 26d only). The axial length of the seals 26b, 26c and 26d are the same as each other, but shorter than the axial length of the seal 26a.
As discussed above, a rear portion of the projectile 14 is formed in the configuration of a boat tail 46. The provision of a boat tail 46 improves the ballistic performance of the round 10 and also allows seating of the projectile 14 in a case or cartridge deeper than if the boat tail was not present, therefore allowing more of the propellant charge to be contained within the projectile body. (This is explained in greater detail below with reference to
In one embodiment the entirety of the cavity 22 of the projectile is filled with propellant 22 so that there is in essence no free space (save for the holes 38) within the cavity 22. As a consequence, upon initial burning of the propellant 24 the resultant gas pressure has the effect of compacting the propellant against interior walls of the cavity 22. This is to be contrast in situations where a projectile may include for example a cavity in the tip 18 which is not filled with propellant; or otherwise has a cavity 22 that is not completely filled with propellant. In such instances, the perceived advantages of containing the deflagrating propellant within the projectile body may not be fully realized.
In an example of the round 10 being applied to a 44 magnum calibre firearm, the round 10 may have the following dimensions:
The projectile 14 and case 50 are configured so that when assembled and prior to firing, the front end 54 of the case 50 is adjacent or near the forward most seal 26a. In some but not necessarily all embodiments the front end may be in contact with and/or partially overlie the forward most seal 26a. Also in this embodiment the front end 54 does not extend beyond the forward most seal 26. The case 50 can be configured particularly in relation to its outer diameter to match the breach of any conventional firearm. In this way, the benefits of the caseless version of the round 10 can be enjoyed with any conventional firearm simply by loading the suitably designed projectile 14 into a case 50 configured to match the breach of the firearm.
It should be appreciated that the configuration of the round 10″ is different to a conventional round comprising a projectile and case where the propellant is held within the case between a base of the projectile and inside of the base of the case. This differences lie in that in the present embodiments at least some of the propellant is held within the projectile 14; and, the projectile 14 includes a portion that extends for a substantial length of the inside of the case 50 (being at least about one half but up to the full length of the case 50).
In the event that the projectile 14 extends for substantially the full length of the case the second end 20 of the projectile 14 will be in contact with or close to an inside surface of the base 56. In such circumstances substantially all of the propellant 24 is held within the cavity 22. But in other embodiments where say the projectile 14 occupies from say ½ to ⅔ of the length of the case 50, while all of the propellant 24 still resides between an inside surface of the cavity 22 and the base 56, a substantial volume of the propellant 24 may lie outside of the cavity 22 in a space between the end 20 and the base 56. This may occur for example where the volume of propellant 24 is substantially less than the combined volume of the cavity 22 and the volume of the space between the end 20 and the base 56. Irrespective of the proportion of propellant in the cavity 22, ordinarily the tip 18 will project beyond the forward most end 54 of the case 50.
For the purposes of comparison,
A comparison between the projectiles 14 and 114 highlights the following:
Each of the above differences and/or benefits arise from various features of the disclosed projectile and will be realized whether or not the associated round of ammunition is cased or caseless.
Whilst a number of specific embodiments of the round have been described it should be appreciated that the round may be embodied in many other forms. For example, round 10 is depicted with a projectile 14 having a boat tail 46 near the end 20. However in alternate embodiments, the projectile 14 may be formed with a constant outer diameter up to the end 20. This is particularly applicable in the uncased or caseless version of the round 10. In this instance, if desired, further seals 26 may be formed about the body 16 between the seal 26d and the end 20 to engage and form a seal with the inside surface 32 of the barrel 12. In this event additional holes 38 may be formed between such seal and the seal 26d to provide pressure equalisation.
The round 10, 10′, 10″ may be formed with only two spaced apart seals, for example 26a and 26d. In this instance it will be these seals that form the seal bound outer surface portion 36. In another embodiment the round may be formed with a plurality of axially spaced seals 26 where each mutually adjacent pair forms a respective seal bound outer surface portion (as indeed is the case with the current depicted embodiments with seals 26a, 26b, 26c and 26d) but where there is at least one hole 38 that provides fluid communication between the cavity 22 and two or more of the seal bound outer surface portions. In such an embodiment the seals may be evenly spaced in the axial direction. Irrespective of how many seals 26 are provided in excess of two seals required to form a seal bound outer surface portion, the spacing between the two outer most seals may be a minimum of about one diameter D of the round.
The above and other variations are depicted in
Thus, the round 10c has a plurality of seals 26a, 26g and 26d which protrude radially from the body 16 of the projectile 14 to form a substantial seal against an inner circumferential surface of a barrel of a firearm 12. Further, two of the seals either 26a and 26g; or 26g and 26d; are mutually adjacent and spaced apart in a direction of a longitudinal axis of the body 16 to form respective seal bound outer surface portions of the body. Naturally, the seal 10c may comprise further variations such as forming each of the three sets of single seals as three sets of two or more closely spaced seals. The projectile 10c may be used in either a cased or uncased version in the same manner as described above in relation to the projectile 10.
The sleeve 70 may be made from a material of higher specific density than that of the body 16. This provides greater overall weight to the projectile 14 than an identically configured projectile without the sleeve and made from a lower specific gravity material. By shaping the sleeve to have a thickened wall near the end 18 the sleeve can bias the increase of overall weight toward the first end 18. However this is not an essential requirement. In an alternate configuration the sleeve can have a constant wall thickness. In one example the body 16 may be made from steel or brass while the sleeve 70 may be made from lead or depleted uranium. The sleeve 70 is not required to provide resistance to radial expansion of the projectile 16. This is due to the presence of the holes 38 which provide pressure equalization between the cavity 24 and the space defined between the seal bound outer surface portion 36 and the inside surface of the barrel 12. According while it is possible for the sleeve 70 to be stronger in terms of resisting radial expansion than the body 16 of the projectile 14 there is no need for this characteristic. Also while in this specific embodiment the boat tail 46 has been omitted this in not essential in order to include a sleeve. This is exemplified by the dotted line 72 in
The cased version of the round of ammunition 10″ as shown in
In each of the variations shown in
In Table 1 below the heading “7 mm Projectile 10 Variation A” is reference to a 7 mm calibre version of the projectile 10 with an OAL of 2″ (2 inches). The heading “7 mm Projectile 10 Variation B” is reference to a 7 mm calibre version of the projectile 10 with an OAL of 3″ (3 inches). The increase in OAL in variation B is spread evenly between the length of the boat tail and the bearing surface, each increasing by ½″ over the equivalent dimensions of variation A.
A comparison between the Berger 7 mm VLD and both variations A and B indicate that for the same diameter D and length of Nose both variations A and B of the present projectile 10 provide a longer bearing surface and boat tail. The longer bearing surface provides improved stability while the increased length in boat tail assists in reducing dynamic drag.
The column “ratio” in Table 1 is the ratio of the length of the characteristic in question in comparison to the diameter D of the projectile in question. Thus for example OAL/D=5.534; D/D=1; BT/D=0.726 etc. The change in these ratios for variations A and B of the projectile 10 in comparison with the corresponding ratio for the Berger 7 mm projectile as shown in Table 1 as headings Δ % A and Δ % B. For example a comparison between the OAL ratios of variation A of the projectile 10 to the Berger projectile to is 7.257/5.534=131% (OAL Δ % A).
Table 2 provides a comparison between three known types of 44 magnum bullets with an equivalent calibre embodiment of the projectile 10.
In Table 2 a comparison between the characteristics of a 44 mag calibre embodiment of projectile 10 with each of the three prior art projectiles is provided in the columns the Δ %1; Δ %2 and Δ %3 respectively.
It should be noted that for both Table 1 and Table 2 the Δ % change while being calculated as a comparison between the respective ratios for a particular characteristic is of course the same a direct comparisons between the characteristics themselves. For example in Table 1 the comparison between the BS lengths of the Berger with projectile 10 variation A is: 0.9/0.541 which as a percentage gives 166%.
For the above comparisons it can be seen that for the same calibre (diameter D) embodiments of the projectile 10 may have an:
In the claims which follow, and in the preceding description, except where the context requires otherwise due to express language or necessary implication, the word “comprise” and variations such as “comprises” or “comprising” are used in an inclusive sense, i.e. to specify the presence of the stated features but not to preclude the presence or addition of further features in various embodiments of the round 10.
Number | Date | Country | Kind |
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2013902843 | Jul 2013 | AU | national |
2013101363 | Oct 2013 | AU | national |
Filing Document | Filing Date | Country | Kind |
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PCT/AU2014/000756 | 7/25/2014 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2015/013742 | 2/5/2015 | WO | A |
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Number | Date | Country | |
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Parent | 14422451 | Jul 2014 | US |
Child | 15425458 | US |