The present subject matter relates to ammunition articles with plastic components such as cartridge casing bodies, and, more particularly, a base insert used with the plastic cartridges.
It is well known in the industry to manufacture bullets and corresponding cartridge cases from either brass or steel. Typically, industry design calls for materials that are strong enough to withstand extreme operating pressures and which can be formed into a cartridge case to hold the bullet, while simultaneously resist rupturing during the firing process.
Conventional ammunition typically includes four basic components, that is, the bullet, the cartridge case holding the bullet therein, a propellant used to push the bullet down the barrel at predetermined velocities, and a primer, which provides the spark needed to ignite the powder which sets the bullet in motion down the barrel.
The cartridge case is typically formed from brass and is configured to hold the bullet therein to create a predetermined resistance, which is known in the industry as bullet pull. The cartridge case is also designed to contain the propellant media as well as the primer. However, brass is heavy, expensive, and potentially hazardous. For example, the weight of .50 caliber ammunition is about 60 pounds per box (200 cartridges plus links).
The cartridge case, which is typically metallic, acts as a payload delivery vessel and can have several body shapes and head configurations, depending on the caliber of the ammunition. Despite the different body shapes and head configurations, all cartridge cases have a feature used to guide the cartridge case, with a bullet held therein, into the chamber of the gun or firearm.
The primary objective of the cartridge case is to hold the bullet, primer, and propellant therein until the gun is fired. Upon firing of the gun, the cartridge case expands to seal the chamber to prevent the hot gases from escaping the chamber in a rearward direction and harming the shooter. The empty cartridge case is extracted manually or with the assistance of gas or recoil from the chamber once the gun is fired. Typically, the brass case has plastically deformed due to the high pressures leaving it larger than before it was fired.
One of the difficulties with polymer ammunition is having enough strength to withstand the pressures of the gases generated during firing. In some instances, the polymer may have the requisite strength, but be too brittle at cold temperatures, and/or too soft at very hot temperatures. Additionally, the spent cartridge is extracted at its base, and that portion must withstand the extraction forces generated from everything from a bolt action rifle to a machine gun. In bolt action weapons, the extraction forces are minimal due to the pressure having completely subsided prior to extraction and that extraction is performed by a manual operation by the shooter. Auto-loading semi automatic and fully automatic weapons operate in a different manner where some of the energy of the firing event is utilized to extract the spent case and either load the next in a closed bolt design or ready the bolt to load the next round by storing potential energy in a spring mechanism in a open bolt weapon.
The extraction and ejection of the cartridge are both a part of this firing routine, but are fundamentally different. Extraction deals with removing the spent casing from the chamber while ejection is the mechanism in which the spent case, once extracted, is removed from the weapon. Ejection is often accomplished with a spring in the bolt face which acts to propel the case in at an angle and direction to expel the casing. In other weapons systems, the case can be pushed out by a lever in the weapon that acts on the casing as it is being extracted rearward and provides a force that provides the required energy to expel the casing.
Since the base extraction point can be an area of failure, numerous concepts have developed to overcome the issues. Inventors like Daubenspeck, U.S. Pat. No. 3,099,958 have developed full metal inserts that are both overmolded (i.e. the polymer of the cartridge case is molded over the metal and undermolded (i.e. the polymer of the cartridge is molded inside the insert. This allows the insert to be added as part of the polymer molding process. Other references, illustrate inserts that are added to the cartridge after it is formed. In these instances, the metal insert is either friction fit or screwed on to the back of the cartridge case. See, U.S. Pat. No. 8,240,252.
In addition, both U.S. Pat. Nos. 8,240,252 and 9,188,412 disclose case wall thicknesses for polymer ammunition. Both only illustrate examples of case walls with thickness ratios between the neck and the case wall over 1.5. While discussing smaller ratios, there was no support for such a finding. Nor was it clear where the minimum thicknesses are measured from.
In addition, the '412 patent discussed conventional brass cartridge case dimensions. Again, while failing to identify the exact position for the measurements, the '412 patent provides the following:
This clearly illustrates that conventional brass cartridges have ratios less than 1.
While these solutions may function for isolated rounds or within certain weapons there is no way to determine what type of friction fit will function with all rounds and weapon systems. Hence a need exists for a polymer casing that can perform as well as or better than the brass alternative. A further improvement is the base inserts joined to the polymer casings that are capable of withstanding all of the stresses and pressures associated with the loading, firing and extraction of the casing.
Thus, the invention includes a high strength polymer-based cartridge having a polymer case, with a first end having a mouth, a neck extending away from the mouth, the neck having a neck thickness (Tn), a shoulder extending below the neck and away from the first end, and a body formed below the shoulder and having a case thickness (Tc), The body can have a flat portion comprising a pull thickness (Tp), and a dip, closer to the shoulder than the flat portion and comprising a dip thickness (Tb). The body having a base interface portion 114. The base interface portion having a minimum thickness in both this section of the cartridge and the entire cartridge. The cartridge can also include an insert attached to the polymer case opposite the shoulder. In some examples the insert is metal or metal alloy. The insert can have a flat section contacting the flat portion and comprising an insert wall thickness (Ti), and a bulge engaging the dip to maintain the insert on the polymer case. Further, the cartridge has a projectile disposed in the mouth having a particular caliber.
In one example, the case thickness, the pull thickness, the dip thickness, and the insert wall thickness are related by Tp+Tb+Ti=Tc. These variables also have ranges where Tp equals approximately 15-33% of Tc, Tb is greater than or equal to Tp, and Tc is a function of the projectile and a ballistic performance for the projectile.
In one example, the neck thickness (Tn) and the dip thickness (Tb) are related by 1.0≤Tb/Tn≤1.5 or just <1.5.
In another example, the ratio of the minimum thickness of the base interface portion to the neck thickness is between about 1.0 and about 1.5.
The drawing figures depict one or more implementations in accord with the present teachings, by way of example only, not by way of limitation. In the figures, like reference numerals refer to the same or similar elements.
In the following detailed description, numerous specific details are set forth by way of examples in order to provide a thorough understanding of the relevant teachings. However, it should be apparent to those skilled in the art that the present teachings may be practiced without such details. In other instances, well known methods, procedures, and/or components have been described at a relatively high-level, without detail, in order to avoid unnecessarily obscuring aspects of the present teachings.
Referring now to
The relief 118 can be formed as a thinner wall section of the neck 106. It can be tapered or straight walled. If the relief 118 is tapered, the inner diameter will increase in degrees as it moves from the mouth 108 down the neck 106. Alternately, the relief 118 can be stair stepped, scalloped, or straight walled and ending in a shelf 120. Additionally, an example of the adhesive can be a flash cure adhesive that cures under ultraviolet (UV) light. Further, once cured, the adhesive can fluoresce under UV in the visual spectrum to allow for visual inspection. Additional flash cure adhesives can fluoresce outside the visual spectrum but be detected with imaging equipment tuned to that wavelength or wavelength band.
The features on the case interface portion 220 generally mirror those on the base interface portion 114 so the two can connect. The insert 200 can have a flat section 400 leading to a first incline 402. At the end of the first incline 402 is a bulge 404 which is generally flat until the second incline 406 which then can end in a vertical tip 408. These features 400, 402, 404, 406, 408 in metal, particularly the first incline 402 and the bulge 404 can be used to keep the base 200 on the case 102. The flat section 400 can have a thickness Ti. The angle of 402 is important such that the angle must be steep enough to restrain the two components from separating. The Tp and the angle together determine the amount of resistance force. The present invention has a 60 degree angle, though a minimum of a 45 degree angle on feature 402 up to a maximum of 90 degrees is possible.
However, the reduced wall thicknesses of the base interface portion 114 can be points of failure since the polymer is the thinnest where most stresses occur during ejection of the round 100 after firing. Metal inserts, whether molded or friction fit, can fail in at least two ways. The two common ways are “pull-off” and “break-off.” In a pull-off failure, the metal insert is pulled away from the polymer cartridge during extraction, thus the base is ejected, but the reminder of the cartridge remains in the chamber. The polymer is not damaged, just the bond between the metal and polymer failed and the base “slipped” off. In break-off failure, the polymer is broken, typically at the thinnest point, and the insert, along with some polymer, are ejected. Pull-off failure can occur in any type cartridge, while break-off failure is less common in reduced capacity polymer cartridges. Reduced capacity, e.g. subsonic polymer rounds, are already thickening the walls inside the cartridge, and can alleviate this issue. Break-off primarily occurs in supersonic or standard rounds where maximum capacity is an important factor and the wall thickness Tc is at its minimum.
To overcome these problems, the inventors have identified certain critical thicknesses that overcome pull-off and break-off failures.
There is a relationship between the angle of the first incline 402, insert 400 “hold” force and stress concentrating at that particular point. The smaller the angle of the first incline 402 the insert 400 has more movement or “wiggle room”. This lowers the amount of stress that can be concentrated at point on the cartridge body. However, this weakens the pull resistance and the insert 400 is more likely to be pulled off during extraction. In contrast, as the angle of the first incline 402 increases, the more fixed the insert 400 is to the body, thus having greater pull-off strength. However, this now increases the amount of localized stress that is applied to the body by the insert. Thus, as the angle increases, the likelihood of break-off failure increases.
There is also a relationship between the dip thickness Tb and the pull thickness Tp. Thickening the dip thickness Tb to reduce the likelihood of break-off failure reduces the pull thickness Tp by making the dip 304 shallower, decreasing the bulge 404 penetration, and increasing the likelihood of pull-off failure. The converse is also true, increasing the pull thickness Tp thins the dip thickness Tb and makes break-off failure more common.
The inventor determined certain ratios of thicknesses to prevent both types of failure. The first relationship is that of the thickness of the cartridge 100 at the insert section:
Tb+Tp+Ti=Tc
Or, that the cumulative thickness of the dip thickness Tb, pull thickness Tp, and insert thickness Ti must equal the thickness of the case Tc so that there is a smooth outer cartridge wall for loading and extraction from the weapon's chamber. The proportions of the thicknesses Tb, Tp and Ti do not have to be equal, and the inventor determined optimal ranges for each in relation to Tc. In one example, the pull thickness Tp is between 15-33% Tc, the dip thickness Tb can be greater than or equal to the pull thickness Tp or, in a different example can be at least 20% of Tc. The insert thickness Ti can be the remainder of the sum of the pull and dip thicknesses Tp, Tb.
Additionally, one example can have the pull thickness Tp at approximately 0.010 inches or greater, while another example can have 0.005 inch. However, while more pull thickness Tp is helpful, there is a point of diminishing returns based on maximizing the size of the propellant chamber 116. Other examples range the pull thickness Tp between approximately 0.010-0.020 inches for a single snap design, a double snap design can drop the thickness to 0.005. Table 1 below sets out some experimental results:
There can be limits to how thick and thin certain elements are. The cartridge and the firearm chambered for that cartridge have to function together. For consistency throughout the industry and the world, dimensions of the cartridge case and the firearm chambers for a particular caliber are very tightly dimensionally controlled. A variety of organizations exist that provide standards in order to help assure smooth functioning of all ammunition designed for a common weapon. Non-limiting examples of these organizations include the Sporting Arms and Ammunition Manufacturers' Institute (SAAMI) in USA, the Commission Internationale Permanente pour l'epreuve des armes a feu portatives (CIP) in Europe, as well as various militaries around the globe as transnational organizations such as the North Atlantic Treaty Organization (NATO).
SAAMI is the preeminent North American organization maintaining and publishing standards for dimensions of ammunition and firearms. Typically, SAAMI and other regulating agencies will publish two drawings, one that shows the minimum (MIN) dimensions for the chamber (i.e. dimensions that the chamber cannot be smaller than), and one that shows the maximum (MAX) ammunition external dimensions (i.e. dimensions that the ammunition cannot exceed). The MIN chamber dimension is typically larger than the MAX ammunition dimension, assuring that the ammunition round will fit inside the weapon chamber. However, and counterintuitively, some chambers actually have a tolerance stackup that provides a crush condition wherein the cartridge MAX is actually larger than the chamber MIN. These and all published SAAMI, NATO, US Department of Defense (US DOD) and CIP drawings are incorporated here by reference.
It is important to note that SAAMI compliance and standardization is voluntary. SAAMI does not regulate all possible calibers, especially those for which the primary use is military (for example, .50 BMG (12.7 mm) calibers are maintained by the US DOD), or the calibers which have not yet been submitted (wildcat rounds, obscure calibers, etc.)
Additionally, the inventors have identified certain thickness ratios.
There is a relationship between the dip thickness Tb and neck thickness Tn that can be defined by:
1.0≤Tb/Tn≤1.5
The ratio of Tb to Tn includes, but is not limited to ratios of 1.00, 1.05, 1.10, 1.15, 1.20, 1.25, 1.30, 1.35, 1.40, 1.45, and 1.50.
Additionally, the relationship between the dip thickness Tb and neck thickness Tn that can also be defined by:
1.0≤Tb/Tn≤1.5
The ratio of Tb to Tn includes, but is not limited to ratios of 1.00, 1.05, 1.10, 1.15, 1.20, 1.25, 1.30, 1.35, 1.40, 1.45.
In another embodiment, the base interface portion 114 has a minimum thickness. The thinnest section is the minimum thickness of the base interface portion 114. The inventors have identified certain thickness ratios relating to the minimum thickness of the base interface portion 114. The neck 106 has a thickness Tn. The base interface portion 114 having a minimum thickness.
There is a relationship between the minimum thickness of the base interface portion and the neck thickness. The ratio of the minimum thickness of the base interface portion to the neck thickness is between about 1.0 and about 1.5. The ratio includes, but is not limited to, ratios of 1.00, 1.05, 1.10, 1.15, 1.20, 1.25, 1.30, 1.35, 1.40, 1.45, and 1.50.
The inventors note that these ratios are larger than in standard brass cases that have ratios between 0.65 and 0.95. This notes some of the inherent differences between using polymer and metal cartridges. Further, ratios larger than 1.5 have been identified in polymer cases but these ratios add increased thickness, and thus weight, unnecessarily to the cartridge. While these weight difference are minute for individual cartridges, there is a cumulative effect as ammunition is typically shipped in bulk and carried in significant quantities by solders in the field. Further these thicknesses can affect the snap fit of the metal insert to the cartridge body proper.
Turning back to
The present invention contemplates all of the factors of standard outside dimensions, maximizing powder chamber dimensions to maximize projectile performance, pull-off failure, break-off failure and manufacturing tolerance for the case and insert. Thus, for any cartridge having matching ballistic requirements, the outer case diameter ODc is set, the inner case diameter IDc can be approximated by the amount of powder for given performance, and the present invention can then be used to size the base interface portion 114 and the case interface portion 220.
Using the above concepts, the base 200 and the case 102 can be friction fit together and withstand the forces necessary during loading, firing, and extraction of the cartridge 100, with no added adhesive at the rear 112 of the case 102 required. This friction fit is also typically water resistant. However, additional water proofing may be required for extreme uses. In one example of the present invention, a sealant 450 is applied only to the first incline 402 before the base 200 and case 102 are assembled. The sealant 450 does not coat the second slope/incline 206, 306 or the dip/bulge 304, 404. In one example, as the base 200 is forced over the base interface portion 114, the bulge 404 keeps the sealant 450 away from the case 102 until it enters the dip 304. Now, the sealant 450 is smeared under pressure along the flat portion/section 300, 400. This keeps the metal/polymer interface for the friction fit. In another example, as the bulge 404 slides over the flat portion 300 and flat section 400, at least the trailing edge of the sealant 450 is smeared across the flat portion 300 so that when the bulge 404 finally engages the dip 304, the sealant 450 is generally smeared across and interfaces between the flat portion 300 and flat section 400.
The body snap-fit region 500 on the rear end 112 of the body has two sets of ridges 502, 510 to engage the insert 200. As opposed to a single snap-fit/interface, region, this example of the body snap-fit region 500 can absorb additional torque that certain weapons produce in their cartridge ejection systems. For example, the M240 machine gun's ejection system applies approximately 5 times the ejection force of an AR style semi-automatic rifle and can over torque the insert 200 when extracting the cartridge 100, leading to the insert 200 being pulled from the body 102, leading to jamming. This additional torque produced by the ejector can cause the case to flex during extraction. This flex can lead to jamming of the firearm.
The ejector portion of the firearm is a small plunger that uses compressed spring energy rotate the case from the firearm after extraction to provide for ejection of the spent cartridge 100 from the weapon. The ejector acts on the face 240 of the insert 200 and is depressed when the cartridge 100 is loaded, the ejector extends to rotate the case once it is free of the chamber. At the point in the process at which the cartridge 100 is almost free of the chamber, the maximum case flex occurs as the ejector acts on the insert 200, yet the body 102 of the cartridge 100 is still restrained by the chamber. Due to the two-piece design of the present cartridge 100, this force can cause the joint between the body 102 and the insert 200 to be stressed beyond its limits. At this point, one of several failure modes can occur depending on the design of the joint. If the joint is not sufficiently rigid, the insert 200 can be pried from the case body 102 either partially or fully removed. When partially removed, the cartridge 100 is able to flex enough during extraction to allow the ejector plunger to partially or fully extend while the case body 102 is still constrained by the chamber. When this occurs, the ejector no longer has enough energy to quickly expel the spent cartridge 100 allowing it to remain in the weapon and cause a jam loading the next round. If the joint is sufficiently rigid yet the case body 102 is not strong enough, a fracture can occur causing either the insert 200 to be partially or fully separated from the case body 102. A partially separated insert 200 can lead to the same failure to eject as a partially removed insert 200. A fully separated insert 200 can be ejected from the weapon yet leave the case body 102 within the weapon also leading to a jam condition. In order for the cartridge 100 to be properly ejected, it must remain sufficiently rigid and strong throughout the process. Due to the nature of plastics, case flex is more likely to occur at elevated temperatures where polymers are more ductile, while fractures are more likely at low temperatures where the polymer is more rigid and brittle. High speed video was used to observe the phenomenon so that proper analysis and corrective actions could be made.
To compensate, an example of the present invention now can include a lower snap ridge 502 proximate the second end 112 in combination with an upper snap ridge 510, both formed on the polymer body 102. The lower snap ridge 502 has a lower snap length 504. This length 504 is measured along a vertical axis 124 of the cartridge 100 (see
The second snap-fit, or interference, region is an upper snap ridge 510 closer to the first end 110 than the lower snap ridge 502. The upper snap ridge 510 has an upper snap length 512 shorter than the lower snap length 504 (e.g., 504>512). Also, as with the lower snap region 502, an upper snap first edge 514 can be proximal the second end 112 and can have a slope which can be approximately 15°. An upper snap second edge 516 farther from the second end 112 than the upper snap first edge 514 can be sharp as well. In some examples, be set at approximately 90°.
The above combination of features can provide increased strength and pull resistance. This can be shown in
Turning now to
The insert 200 can further include a shoulder 608 disposed between the flash hole 216 and the insert snap fit region 600 that can contact the polymer case second end 112. Again, this minimizes the edge contact that can be stress points.
In one example, the body snap-fit region 500 has a body snap-fit diameter 518 and the insert snap-fit region 600 has an insert snap-fit diameter 610 approximately less than the body snap-fit diameter 518. Since the insert snap-fit region 600 engages over the body snap-fit region 500, this means that, in one example an average inner diameter 610 of the insert snap-fit region 600 is smaller than an average outer diameter 518 of the body snap fit region 500. In different examples, the diameters can be taken from the smallest point, the largest point, or an average over some or all of the regions 500, 600. The body snap-fit diameter 518 and the insert snap-fit diameter 610 can both be taken from the same points (e.g., both from the smallest point) or differing points depending on the design and caliber. Said differently, the case 102 can be pre-loaded in compression thus allowing for permanent plastic expansion of the metal insert 200 during firing while keeping the mechanical, interference lock from disengaging.
In another example, the body snap-fit region 500 further comprises a body spacer region 520 between the lower snap ridge 502 and the upper snap ridge 510. The insert snap-fit region 600 can have a matching insert spacer region 612.
Turning now to
For purposes of developing an understanding of the casing strains during assembly, firing, and extraction a preliminary finite element analysis of one example of the invention was done. The results of the analysis are subject to change as a result of the mesh convergence analysis, material model parameter sensitivity, and validation analyses using specific validation test data from real specimens. The scope of the work was to perform a stress analysis of an idealized example of the invention.
Note that in the examples above, the present invention can be used with single polymer body cases or multiple part polymer cases. The cases can be molded whole or assembled in multiple parts. The polymers herein can be any polymer or polymer metal/glass blend suitable to withstand the forces of loading, firing and extracting over a wide temperature range as defined by any commercial or military specification. The metal or metal alloys can be, again, any material that can withstand the necessary forces. The base can be formed by any method, including casting, hydroforming, and turning. The above inventive concepts can be used for any case for any caliber, either presently known or invented in the future.
While the foregoing has described what are considered to be the best mode and/or other examples, it is understood that various modifications may be made therein and that the subject matter disclosed herein may be implemented in various forms and examples, and that the teachings may be applied in numerous applications, only some of which have been described herein. It is intended by the following claims to claim any and all applications, modifications and variations that fall within the true scope of the present teachings.
This application is continuation of U.S. patent application Ser. No. 17/265,179 filed Feb. 1, 2021, which is a 371 National Stage of PCT/US2019/043743, filed Jul. 26, 2019, which claims priority to U.S. Provisional Patent Application No. 62/711,968, filed Jul. 30, 2018, which are hereby incorporated by reference in their entirety.
Number | Date | Country | |
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62711958 | Jul 2018 | US |
Number | Date | Country | |
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Parent | 17265179 | Feb 2021 | US |
Child | 17941125 | US |