The present disclosure relates to firearm projectiles, and more specifically, to cartridges and bullets having a polymer tip.
In the sport of hunting, responsible hunters go to great lengths to ensure a quick, clean and humane kill. Hunters seek to select the best rifle, cartridge, bullet and optics for the particular species being hunted and the specific conditions likely to be encountered (e.g., rough terrain and thick underbrush). Hunters also practice marksmanship so that a shot can be carefully placed even under challenging circumstances. If a bullet is poorly placed, the game animal may travel a long distance through rough terrain after having been shot. In these situations, there is a risk that the wounded game animal will not be recovered.
Firearm projectiles, specifically bullets, may be designed as “hollow-points”, having a central pit or generally hollowed out frontal cavity that causes the projectile to “upset” or expand upon impact with a target. Expansion may decrease penetration and as a result, increase the amount of kinetic energy transfer from the projectile to the target for improved stopping power. However, the central pit or hollowed out design may result in diminished aerodynamic characteristics. For example, the hollowed out design may increase axial drag which can reduce overall projectile accuracy and range.
To help counteract this, in some instances, hollow-point bullets may have a converging polymer tip that is inserted into the frontal cavity to mimic the shape of a spritzer or pointed bullet.
Embodiments of the disclosure are directed to an expanding projectile for firing from a gun, the projectile including a projectile body and an expansion configured tip. In one or more embodiments, the projectile body includes a metal jacket extending from a tail portion to a nose portion and surrounding an interior solid core. The metal jacket is tapered along the nose portion to an annular forward edge where the jacket defines an opening to an interior region including a forward facing interior surface of the interior solid core. In one or more embodiments the expansion configured tip is positioned in the opening of the projectile and tapered forwardly from the annular forward edge to an ogive tip that defines a spitzer-type aerodynamic shape of the total projectile.
Various embodiments of the disclosure provide benefits from improved expansion characteristics for projectiles that impact a target at medium to lower impact velocities. In various instances, when a projectile is fired and begins to travel downrange, the forward velocity of the projectile will decay along over time and distance due to aerodynamic drag. As such, a projectile may fail to fully expand upon impact with a target at or beyond a certain range, as the projectile will lack the necessary velocity upon impact to cause projectile expansion. Alternatively, known projectiles will vary their mush
This can be particularly true for projectiles with polymer tips. For example, known projectiles with polymer tips generally include tips that, upon impact, are pushed axially rearward towards the tail end of the projectile and compressed within the interior region. As such, known projectiles with conventional polymer tips can impede the path of fluid into the interior of the projectile, in turn impeding projectile expansion. As such, known polymer tips typically result in a higher impact velocity threshold for expansion, as compared to un-tipped projectiles.
As such, certain embodiments are directed to an expansion configured tip for low impact velocity consistent symmetrical expansion of a projectile. In various embodiments, the expansion configured tip is configured to provide, upon impact, one or more fluid pathways into the interior region of the projectile for improved projectile expansion characteristics at medium to lower impact velocities. This results in a projectile with improved expansion characteristics at longer ranges or at reduced impact velocities compared to known expanding projectiles while still maintaining the aerodynamic improvements of a polymer tipped round.
In addition, certain embodiments are directed to an expansion configured tip formed using a relatively high density or high strength material such as a steel, tungsten, other metal, or ceramic material. In various embodiments, the expansion configured tip is formed from other materials that are stronger more dense or harder than polymer. As such, one or more embodiments provide benefits in an expanding projectile with improved munition durability before and after firing. For example, one or more embodiments provide improved resistance to rough product handling, violent magazine and feed ramp function, and excessive tip heating due to aerodynamic drag. In addition, one or more embodiments provide benefits in an expanding projectile with improved penetration characteristics. As such, certain embodiments provide and expanding projectile with improved terminal performance through barriers and that routinely break apart conventional bullets upon impact.
In addition, various embodiments can change the visual appearance of an expanding projectile. For example, one or more embodiments include geometric features, such as tip radii and/or angles, shown to have an effect on the light performance. The bullet and casing may be nickel covered
As such, one or more embodiments are directed to an expanding projectile including a projectile body including a metal jacket extending from a tail portion to a nose portion and surrounding an interior solid core. In various embodiments, the metal jacket is tapered at the nose portion in a forward direction to an annular forward edge, the annular forward edge defining an opening in the metal jacket to an interior cavity extending from the opening in a rearward direction to a forward facing interior surface of the interior solid core.
In one or more embodiments, a tip is mounted in the interior cavity and has an exterior surface substantially flush with an exterior surface of the metal jacket. In certain embodiments the tip has a main portion forward of the opening and a tip retention portion that at least partially fills the interior cavity. In certain embodiments the tip retention portion or stem of the tip that includes one or more fracture regions configured to, upon impact of the expanding projectile with a target, fracture or deform to expose one or more fluid pathways into the interior cavity and to the forward facing interior surface for initiating expansion of the projectile body. The fluidic pathways may extend through or past the stem to the core effecting initiating of the expansion. Upon effective initiation of expansion, the bullet continues to expand or mushroom which may be facilitated by skives at the forward end of the bullet body initially defining pedals that peel rearwardly. Bonding of the core to the jacket retains the deformed core material with the jacket even at close ranges.
In embodiments, a bullet with a central axis has a bullet body with a forward ogive portion with a forward opening, a mid-barrel engaging or bearing surface, and a rear boat tail portion. A tip is secured in the forward opening with a conical portion substantially flush with the ogive portion. A meplat is on the forward end of the tip. On the bearing portion, forward and rearward wall portions and a bottom wall defining a circumferential groove, the rearward wall having a lead-in surface or ramp from the bottom wall to the exterior surface of the bearing portion. In embodiments the ramp set an angle of from 20 to 45° measured from a line on the outer surface of the body portion parallel to the bullet axis with the 20 to 45° angle facing forward. In embodiments the ramp is from 18 to 34° as measured above. The ramp can extend a distance of 30 to 40% of the axial length of the groove. In embodiments the groove has a maximum depth of 0.008 inches±20%. The groove reduces the bearing surface contact area and provides a pedaling stop. In embodiments the groove is positioned in the forward half of the bearing surface portion lengthwise and is positioned in the rearward half of the bullet body lengthwise. The bullet body includes a lead core surrounded by a jacket comprising copper. The lead core extends from the within the forward opening rearward to the axial location of the groove. In embodiments the boat tail extends an axial length greater than 12% of total length of the bullet including the tip.
A feature and advantage of embodiments is weight retention at short and long shooting distances, for example from 50 yards to over 900 yards providing a highly effective hunting bullet. In embodiments a core comprising lead is bonded to a the jacket, the lead core extending rearwardly within the jacket to an axial position of where the groove is positioned on the exterior of the jacket, the position of the groove may provide a facilitating effect to pedaling upon impact through the full axial distance, the length of the core. A bullet expansion initiation means is provided with a tip. Such means may be a central fluidic pathway through the tip. In embodiments the fluidic pathway may be provided after fracturing of the forward conical portion of the tip from the stem portion wherein the stem portion is tubular. The fluidic pathway may be through the stem portion where it is tubular or around the stem portion where there are axially extending fluidic pathways on the exterior of the stem portion.
A further feature and advantage of embodiments is advantageous terminal effects at a wide range of bullet velocities and distances. For example, consistent expansion of the bullet occurs over a wide range of velocities which reflect a wide range of distances at which the bullet will perform, specifically perform with a consistent symmetrical mushrooming about the bullet axis, that is at short distances there may be a greater mushrooming effect than longer distances, but even up to 900 or more yards, the bullet can effectively mushroom without asymmetrical deformation pedals may be longer, the terminated bullet may be a longer due to the reduced mushrooming but the bullet still mushrooms. In embodiments, the consistent mushrooming is provided by a fluidic path through the forward opening of the bullet body facilitated by breaking of a conical portion of a tip from a stem portion in the bullet body forward opening. In embodiments, the stem portion may be tubular that then provides a central fluid path directly to the center of the lead core facilitating initiation of expansion of the bullet. Moreover, the tubular configuration facilitates fracture and/or deformation of the tip on impact providing a means for initiating the radial expansion, the mushrooming, of the bullet.
A feature and advantage of embodiments is a bullet with a very high ballistic coefficient providing enhanced hunting performance through a greater range of velocities and distances than conventional bullets and providing upset along with more consistent terminal performance over said greater range of velocities and distances.
A further feature and advantage of the invention is the casing and bullet may both be nickel plated providing a protective finish that facilitates handling of the bullet and provides an aesthetic advantage to discriminate the cartridge from other types of cartridges.
The above summary is not intended to describe each illustrated embodiment or every implementation of the present disclosure.
The drawings included in the present application are incorporated into, and form part of, the specification. They illustrate embodiments of the present disclosure and, along with the description, serve to explain the principles of the disclosure. The drawings are only illustrative of certain embodiments and do not limit the disclosure.
While the embodiments of the disclosure are amenable to various modifications and alternative forms, specifics thereof have been shown by way of example in the drawings and will be described in detail. It should be understood, however, that the intention is not to limit the disclosure to the particular embodiments described. On the contrary, the intention is to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the disclosure.
Referring to
In one or more embodiments, the projectile 100 is jacketed or plated, having a projectile body 104 composed of at least two parts including a metal jacket 120 that surrounds an interior solid core 124 depicted in
Described further herein, in one or more embodiments the interior solid core 124, is composed of a malleable material, relative to the metal jacket 120 for expansion of the projectile body 104 upon impact with a target. In some embodiments, the interior solid core 124 is composed of lead, alloyed lead, or other suitable core material for expansion of the projectile body 104 upon impact. In various embodiments, the metal jacket 120 is composed of unalloyed copper, a copper alloyed with another metal, or other suitable projectile jacketing or plating material. For example, the metal jacket 120 may be composed of a copper-zinc alloy for covering the interior solid core 124 while firing the projectile from a barrel. The core material may be bonded to the jacket such as is described in U.S. Pat. Nos. 4,879,953; 4,793,037; 5,641,937; and 3,756,158 for example. These patents are incorporated herein by reference for all purposes.
In some embodiments, the projectile 100 is a lead-free projectile, where the projectile body 104 is a single, unitary piece of non-lead material. For example, in some embodiments, the body 104 is entirely composed of unalloyed copper, a copper alloyed with another metal, or other suitable non-lead material.
Described further herein, in one or more embodiments, the tip 116 defines a most forward portion for the projectile 100. In various embodiments, the tip 116 is a unitary structure having an exterior surface 128 that is substantially flush with an exterior surface 132 of the metal jacket 120 for forming a spitzer aerodynamic shape for the total projectile 100.
As such, in various embodiments, the exterior surface 128 of the tip 116 extends from a rearward portion 136, which is positioned directly adjacent to a forward portion 140 of the metal jacket 120, to a forward point 144 of the tip 116. In various embodiments, the tip 116 has a substantially pointed or ogive shape with a taper from the rearward portion 136 to the forward point 144 defined by an aspect ratio of the width 145 of the projectile 100 at the rearward portion 136 to the total length 146 of the projectile 100.
In various embodiments, the aspect ratio is in the range of 6.00 to 10.00. In certain embodiments the aspect ratio is in the range of 7.00 to 8.00. However, in various embodiments the aspect ratio can be higher or lower depending on the design and type of projectile 100.
In various embodiments, projectile 100 can be sized according to various different calibers. For example, in certain embodiments, the projectile could be a .308 Winchester round, 0.17 HMR, 0.22 Hornet, 0.223 Remington, 0.223 WSSM, .243 Winchester, 0.257 Roberts, .270 Winchester, 7 mm Remington Magnum, 0.30-06 Springfield, .300 Winchester Magnum, .338 Winchester Magnum, 0.375 H&H, 45.70 Gov't, and .458 Winchester Magnum. However, in certain embodiments, the projectile 100 could be sized to various other types of calibers not listed, but known in the art. The calibers of embodiments herein are utilized and suitable for hunting. In embodiments the bullet sizes are no greater than 50 caliber.
Referring to
Expanding projectile 200 is jacketed, including a projectile body 104 composed of a metal jacket 120 extending from the tail portion 108 to the nose portion 116 and surrounding an interior solid core 124. The metal jacket 120 and nose portion 116 tapers in a forward direction, indicated by arrow 208 on a central axis 212. The metal jacket 120 extends to an annular forward edge 216 that defines an opening in the metal jacket 120 to expose a forward facing interior surface 220 of the interior solid core 124 and defines a scoop that facilitates opening upon impact with a target media that has a fluidic basis.
The interior solid core 124 is composed of a relatively malleable material so that, upon impact, the interior core material is compressed rearwardly, and the projectile 200 expands or mushrooms for increased transfer of kinetic energy to a target. In certain embodiments, the forward facing interior surface 220 is a substantially flat surface normal to the central axis 212. However, in some embodiments, the forward facing interior surface 220 may be asymmetrical, have a central indentation or depression, or may have other shape based on the design of the projectile 200, on manufacturing variations, or on other factors.
In one or more embodiments, the expanding projectile 200 includes a central cavity 224 extending from the opening defined by the annular forward edge 216 to the forward facing interior surface 220. In some embodiments, the size and shape of the central cavity 224 is defined by the forward facing interior surface 220 and the interior surface 228 of the metal jacket 120, forward of the forward facing interior surface 220. In various embodiments, the central cavity 224 has a conical shape or other shape in the interior of the projectile 200. In certain embodiments, the central cavity 224 can extend into the interior solid core 124 for enhancing mushrooming characteristics of the expanding bullet 200 upon impact.
In certain embodiments, the central cavity 224 has an undercut shape, as the metal jacket 120 tapers from the forward facing interior surface 220 to the opening such that the opening has a diameter smaller than that of the width of the forward facing interior surface 220 and defines undercut corner regions 232. As used herein, the undercut corner regions 232 are defined as the portion of the cavity 224 exterior to an axially extending cylinder with the radius equal to the opening.
In one or more embodiments, the tip 204 defines a most forward tip for the projectile 200. The tip 204 is a unitary structure including a main portion 236 and a tip retention portion 240 rearward of the main portion 236 and opening. The main portion 236 has an exterior surface 244 substantially flush with the exterior surface 132 of the metal jacket 120 for forming a relatively streamlined or spitzer aerodynamic shape.
In various embodiments, the tip retention portion 240 is a plug element that, when assembled in the central cavity 224, resists axial movement of the tip 240 and retains it in place in the projectile body 104. In one or more embodiments, tip retention portion 240 is a cylindrical plug. In certain embodiments, tip retention portion 240 can have other shapes, for example, tip retention portion 240 could be rectangular, hexagonal, or have other suitable shape.
In one or more embodiments, the tip retention portion 240 includes a blind hole or axial recess 248 along the central axis of the tip 204 from a rear end 252 of the tip retention portion 204 to a recess end point 256 within the interior of the tip 204.
In certain embodiments, the axial recess 248 is cylindrical hole that defines a tubular sidewall 260 of the tip retention portion 240. In various embodiments, the axial recess 248 has a diameter 264 to define a thickness 268 of the sidewall 260. For example, in one or more embodiments, the diameter 264 of the axial recess 248 is approximately in the range of 10% to 70% of a total diameter 272 of the tip retention portion 240. As a result, in some embodiments, the sidewall 260 has a thickness 268 in the range of 45% to 15% of the total diameter 272 of the tip retention portion 240. In some embodiments, the axial recess 248 has a diameter 264 in the range of 80% to 60% of the total diameter 272 of the tip retention portion 240. As a result, in some embodiments, the sidewall has a thickness 268 in the range of 10% to 20% of the total diameter 272 of the tip retention portion 240. However, in various embodiments, the diameter of the axial recess 248 and the corresponding thickness of the sidewall 260 can be selected as any suitable value, described further below.
In one or more embodiments, tip retention portion 240 includes a fracture region 266. Fracture region 266 is a portion of the tip 204 that is configured to fracture or deform upon impact of the projectile 200 with a target, described further below. As such, the fracture region 266 provides a weak point for the main portion 236 of the tip to break off such as at the juncture 267 of the main portion and tip retention portion, while still leaving the main portion 236 as solid as possible to resist the heating of air friction that occurs during projectile flight. In various embodiments, the fracture region 266 includes portions of the tip retention portion 240 that are designed to fracture or deform at a particular impact velocity or impact force. For example, in one or more embodiments, the fracture region 266 is configured to fracture or deform at impact energies associated with velocities as low as 1500 feet per second. In some embodiments, the fracture region 266 is configured to fracture or deform at impact energies associated with velocities as low as 1000 feet per second. For example, in certain embodiments, the fracture region 266 is configured to fracture or deform at impact energy as low as 800 foot pounds. However, in various embodiments, fracture regions can be designed to fracture at higher or lower impact velocities or with various energy requirements based on the structural strength of the fracture region.
For example, depicted in
In one or more embodiments, the axial recess 248 extends from the rear end 252 to the recess end point 256 that is within the interior of the tip 204 and which is forward of the end 216 of the metal jacket 120. As such, in various embodiments, the tubular sidewall 260 is in contact with the metal jacket 120 at the annular forward end 216.
In certain embodiments, the axial recess 248 extends through at least 50% to 80% of the total length 280 of the tip 204. For example, referring to
Referring to
In certain embodiments, the number of and location of fractures or deformation of the tip 204 can vary based on normal deviations in materials and manufacturing of the tips 204, the amount of and location of force on the tip 204 upon impact, and other various factors.
For example, depicted in
In
Depicted in
Depicted in
In various embodiments, the torque or force required to fracture or deform the tip 204 is based on the materials used in the tip 204. For example, in one or more embodiments, the tip 204 can be constructed from polymer, elastomer, metal, ceramic or other material. In various embodiments, the energy required to fracture the tip 204 will depend upon the material used on and the design of the tip 204. For example, thinner or weaker structural portions of the tip 204 will have different energy requirements for deformation or fracture than thicker and stronger structural portions of the tip 204.
In some embodiments, the tip 116 could be constructed using a combination of materials. For example, in one or more embodiments, the tip 116 could be constructed from a combination of metal and polymer, with polymer portions located at strategic areas that are designed to fracture at lower energy requirements than a solid metal tip 116.
Referring to
For example, expanding projectile 400 is jacketed, including a metal jacket 120 defining a projectile body 104 extending from the tail portion 108 to a nose portion 112 and surrounding an interior solid core 124. The metal jacket 120 extends to an annular forward edge 216 that defines an opening in the metal jacket 120 to expose an interior solid core 124 and a forward facing interior surface 220. In one or more embodiments, the expanding projectile 400 includes a central cavity 224 extending from the opening defined by the annular forward edge 216 to the forward facing interior surface 220.
In one or more embodiments, the expanding projectile 400 includes a tip 404 defining a most forward tip for the projectile 400. The tip 404 is a unitary structure including a main portion 408 and a tip retention portion 412 rearward of the main portion 408 and opening. The main portion 412 has an exterior surface 414 substantially flush with an exterior surface 132 of the metal jacket 120 for forming a relatively streamlined or spitzer aerodynamic shape.
In various embodiments, the tip retention portion 412 is a plug element that, when assembled in the central cavity 232, resists axial movement of the tip 404 and retains it in place in the projectile body 104. In various embodiments, tip retention portion 412 is a cylindrical plug. In certain embodiments, tip retention portion 412 can have other shapes, for example, tip retention portion 412 could be rectangular, hexagonal, or have other suitable shape.
In one or more embodiments, the tip retention portion 412 includes a shoulder portion 414 and a neck portion 416 that is connected to the main portion 408. In various embodiments, the neck portion 416 defines a generally thinner and structurally weaker portion of the tip retention portion 412 having a thinner area of material for connection to the main portion 408. For example, in one or more embodiments, the neck portion 416 has a thickness 424 and a width 428 compared to a shoulder width 432 of the shoulder portion 414. In certain embodiments, the neck portion 416 has a thickness 424 approximately in the range of 33% to 10% of the width 432 of the shoulder portion 420. In some embodiments the neck portion 416 has a thickness 428 approximately in the range of 5% to 20% of the total length 437 of the tip 404.
In one or more embodiments, tip retention portion 412 includes a fracture region 434. Similarly as described above with reference to
For example, depicted in
In various embodiments, the shoulder portion 420 includes one or more axial recesses 432. As used herein, axial recess refers to any hole or cut out portion in the tip 404 that extends lengthwise or substantially parallel to the central axis of the tip 404. For example, axial recesses 432 are offset from the central axis of the tip, but extend lengthwise from the rear end 435 to a recess end point 436. In certain embodiments, the axial recess 432 extends through at least 40% to 80% of the total length 437 of the tip 404. For example, referring to
Referring to
In addition, in certain embodiments, the fracture region 434 is constructed to have sufficient structural integrity to maintain its form during firing and projectile flight but is constructed to reliably deform or fracture upon impact. For example, depicted in
Further, in various embodiments, the tip 404 is designed to, as a result of fracture or deformation, provide an opening 440 or passageway for fluid to enter the interior of the projectile and to contact the forward facing interior surface 220.
For example, depicted in
In
Depicted in
As described above, in various embodiments, the torque or force required to fracture or deform the tip 404 is based on the materials used in the tip 404. For example, in one or more embodiments, the tip 404 can be constructed from polymer, elastomer, metal, ceramic or other material. In various embodiments, the energy required to fracture the tip will depend upon the material used on and the design of the tip 404. For example, thinner or weaker structural portions of the tip 404 will have different energy requirements for deformation or fracture than thicker and stronger structural portions of the tip 404. In some embodiments, the different portions of the tip 404 can be constructed from different materials. For example, in some the main portion 408 or other elements of the tip 404 could be constructed from at least one of metal or ceramic and the fracture region 434 could be constructed from a polymer material. A suitable material for the tip has been found to be polyphenylsulfone (PPSU). Transparent polymers may be utilized providing visibility of the cavity from exterior of the bullet.
In certain embodiments, the number of and location of fractures or deformation of the tip 404 can vary based on normal deviations in materials and manufacturing of the tips 404, the amount of and location of force on the tip 404 upon impact, and other various factors.
Referring to
For example, referring to
Referring to
As a result of the splines 712 four axial recesses 724 are defined extending from a rear end 728 of the tip retention portion 708 to a rear end 732 of the main portion 704. Further, a fracture region is defined in the tip retention portion 708 by the splines 712 as the tip retention portion 708 is configured to either deform or fracture upon impact to expose one or more openings into the axial recesses 724, which would expose interior surfaces of an expanding projectile, as described above.
Referring to
As a result of the splines 812 ten axial recesses 824 are defined extending from a rear end 828 of the tip retention portion 808 to a rear end 832 of the main portion 804. Further, a fracture region is defined in the tip retention portion 808 by the splines 812 as the tip retention portion 808 is configured to either deform or fracture upon impact to expose one or more openings into the axial recesses 824, which would expose interior surfaces of an expanding projectile, as described above.
Referring to
Similarly,
Referring to
For example, referring to
In
Referring to
In one or more embodiments, projectile 1300 includes a tip 1312. In various embodiments, tip 1312 can include a forward central opening 1316 defined by an annular forward edge 1320 at a forward most portion of the tip 1312. Described further below, in various embodiments the central opening 1316 of the tip 1312 is a recess end point for an axial recess that extends through the tip 1300 to expose a forward facing interior surface of the projectile 1300.
For example, referring to
Referring to
Referring to
Referring to
In one or more embodiments, the expanding projectile 1600 includes a central cavity 224 extending from the opening defined by the annular forward edge 216 to the forward facing interior surface 220. In certain embodiments, the central cavity 224 has an undercut shape, as the metal jacket 120 tapers from the forward facing interior surface 220 to the opening such that the opening has a diameter smaller than that of the width of the forward facing interior surface 220 and defines undercut corner regions 232.
In one or more embodiments, the tip 1604 defines a most forward tip for the projectile 1600. The tip 1604 is a unitary structure including a main portion 1608 and a tip retention portion 1612 rearward of the main portion 1608 and opening. As described above, in various embodiments the tip retention portion 1612 is a plug element that, when assembled in the central cavity 224, resists axial movement of the tip 1604 and retains it in place in the projectile 1600.
In one or more embodiments, tip retention portion 1612 tapers rearwardly from a forward portion 1616, adjacent to the main portion 1608, to a rearward portion 1618 adjacent a rearwardly facing end surface 1620 of the tip 1604. For example, tip retention portion 1612 has a first width 1624 at the forward portion 1616 and a second smaller width 1628 at the rearward portion 1618. In various embodiments the second width 1628 is approximately 10% smaller than the first width 1624. In certain embodiments the second width 1628 is approximately 5% to 20% smaller than the first width 1624. In certain embodiments the first width is approximately 20% to 50% smaller than the first width 1624. In various embodiments, the first width 1624 defines the outermost width of the tip. In addition, in certain embodiments the first width 1624 is sized such that the tip fits or couples to the remainder of the projectile 1600 via a friction fit or interference fit with the metal jacket 120 at the opening.
As such, in one or more embodiments, tip retention portion 1612 includes a fracture region 1632 defined by the tapered shape of the tip retention portion 1612. Fracture region 1632 is a portion of the tip 1604 that is configured to fracture or deform upon impact of the projectile 1600 with a target, as described above, thereby providing a fluid pathway into the central cavity 224 and exposing the forward facing interior surface 220. In various embodiments the fracture region 1632 is defined by the tapered shape of the tip retention portion 1612. For example, the tapered shape provides a weak point in the coupling between the tip 1604 and the remainder of the projectile 1600 in the form of a void 1636 between the metal jacket 120 and the tip retention portion 1612 for the main portion 1608 of the tip to deform or break off.
In one or more embodiments, the fracture region 1632 is configured to fracture or deform at impact energies associated with velocities as low as 1500 feet per second. In some embodiments, the fracture region 1632 is configured to fracture or deform at impact energies associated with velocities as low as 1000 feet per second. For example, in certain embodiments, the fracture region 1632 is configured to fracture or deform at impact energy as low as 800 foot pounds. However, in various embodiments, fracture regions can be designed to fracture at higher or lower impact velocities or with various energy requirements based on the structural strength of the fracture region.
Referring to
In one or more embodiments, the tip 1704 defines a most forward tip for the projectile 1700. The tip 1704 is a unitary structure including a main portion 1708 and a tip retention portion 1712 rearward of the main portion 1608 and opening. As described above, in various embodiments the tip retention portion 1612 is a plug element that, when assembled in the central cavity 224, resists axial movement of the tip 1704 and retains it in place in the projectile 1700.
In various embodiments the tip retention portion 1712 is shortened, having a first length 1716 that is between 10% to 40% of a total bullet length 1720 including the tip 1704. In various embodiments, this shortened tip retention portion 1712 provides a void 1724 between the forward facing interior surface 220 and the tip 1704. As a result, the tip 1704 is not supported axially by the interior surface 200 and is supported solely by the metal jacket of the projectile 1700. In various embodiments this allows the tip to, upon impact, telescope into the central cavity 224 upon impact with a target, thereby providing a fluid pathway to the central core 124.
Referring to
In one or more embodiments, the expanding projectile 1800 includes a central cavity 224 extending from the opening defined by the annular forward edge 216 to the forward facing interior surface 220. In certain embodiments, the central cavity 224 has an undercut shape, as the metal jacket 120 tapers from the forward facing interior surface 220 to the opening such that the opening has a diameter smaller than that of the width of the forward facing interior surface 220 and defines undercut corner regions 232.
In one or more embodiments, the tip 1804 defines a most forward tip for the projectile 1800. The tip 1704 is a unitary structure including a main portion 1808 and a tip retention portion 1812 rearward of the main portion 1808 and opening. As described above, in various embodiments the tip retention portion 1812 is a plug element that, when assembled in the central cavity 224, resists axial movement of the tip 1804 and retains it in place in the projectile 1600.
In one or more embodiments, tip retention portion 1812 at a forward portion 1816, adjacent to the main portion 1808. As a result, tip retention portion 1812 has a reduced width at the forward portion 1816. In various embodiments the width at the forward portion is reduced approximately 10% as compared to the wider portions of the tip retention portion 1812. In certain embodiments the reduced width is approximately 5% to 20% smaller. In certain embodiments the reduced width is 20% to 50% smaller.
In various embodiments, the width at the forward portion 1816 defines a fracture region 1832 defined by the tapered shape of the tip retention portion 1812. Fracture region 1832 is configured to fracture or deform upon impact of the projectile 1800 with a target, as described above, thereby providing a fluid pathway into the central cavity 224 and exposing the forward facing interior surface 220. In one or more embodiments, the fracture region 1832 is configured to fracture or deform at impact energies associated with velocities as low as 1500 feet per second. In some embodiments, the fracture region 1832 is configured to fracture or deform at impact energies associated with velocities as low as 1000 feet per second. For example, in certain embodiments, the fracture region 1832 is configured to fracture or deform at impact energy as low as 800 foot pounds. However, in various embodiments, fracture regions can be designed to fracture at higher or lower impact velocities or with various energy requirements based on the structural strength of the fracture region.
Referring to
In various embodiments the tip 1904 is injection molded or insert molded onto the projectile 1900. As a result the polymer material of the tip 1904 fills the area surrounding the central stub 1906 as well as the volume outside of the bullet—to form the tip 1904. As a result, the tip 1904 defines an annular tip retention portion 1912 surrounding the central stub 1906 and that is rigidly locked to the bullet. In addition, as a result of the tapered shape of the metal jacket at the nose portion 116, the molding process defines a fracture region 1932 of thinner material near the main portion 1908. In various embodiments the fracture region 1932 is thinner to promote breakage upon impact, as described above.
Referring to
As a result of the recesses 2012, a fracture region is defined in the tip retention portion 2008, as the tip retention portion 808 is configured to either deform or fracture upon impact to expose one or more openings into the axial recesses 2012, which would expose interior surfaces of an expanding projectile, as described above.
Referring to
As a result of the molding processes, a fracture region 2112, 2212 is defined in the tip retention portions 2108, 2208, as the tip retention portion is configured to either deform or fracture upon impact.
Referring to
Referring to
Referring specifically to
A tip 3120 is inserted into the nose portion 3068 and has an axis an exterior surface 3122 that is substantially flush with the exterior surface 3092 of the ogival portion. The tip 3120 has a main portion configured as a tapered forward portion 3130 that may be conical or ogival with a rounded meplat 3136 and further has a tip retention portion configured as a stem portion 3144 unitary with the main portion. The stem portion 3144 having a rearward end 3146 with a rearward facing surface 3148, an exterior circumferential surface 3152. The tip body defines a hollow core 3158 that extends from the rearward end 3146 of the stem portion 3144 forwardly and may extend into the main portion 3130. The hollow core may be configured as a bore and may have other shapes as well. The stem with the hollow core being tubular.
Referring to
Referring to
In embodiments, the bearing portion extends a length 3270 that is 44% or less of the total bullet length 3118. In embodiments, the bearing portion extends a length 3270 that is 37% or less of the total bullet length 3118. In embodiments, the length of the ogive portion and tip 3119 is greater than 40% of the total bullet length 3118. In embodiments, the length of the ogive portion and tip 3119 is greater than 45% of the total bullet length 3118. In embodiments, the length of the ogive portion and tip 3119 is greater than 50% of the total bullet length 3118.
Referring to
The descriptions of the various embodiments of the present disclosure have been presented for purposes of illustration, but are not intended to be exhaustive or limited to the embodiments disclosed. Many modifications and variations will be apparent to those of ordinary skill in the art without departing from the scope and spirit of the described embodiments. The terminology used herein was chosen to explain the principles of the embodiments, the practical application or technical improvement over technologies found in the marketplace, or to enable others of ordinary skill in the art to understand the embodiments disclosed herein.
This application is a continuation of U.S. patent application Ser. No. 15/870,769 filed Jan. 12, 2018 which claims the benefit of U.S. Provisional Application Nos. 62/445,697 filed Jan. 12, 2017 and 62/518,334 filed Jun. 12, 2017, the entire contents of which are incorporated herein by reference.
Number | Name | Date | Kind |
---|---|---|---|
1080974 | Johnson | Dec 1913 | A |
1135357 | Clyne | Apr 1915 | A |
1328334 | Newton | Jan 1920 | A |
1493614 | Dickerman | May 1924 | A |
1967416 | Leussler | Jul 1934 | A |
3074344 | Devaux | Jan 1963 | A |
3881421 | Burczynski | May 1975 | A |
4044685 | Avcin | Aug 1977 | A |
4108074 | Billing, Jr. et al. | Aug 1978 | A |
4245557 | Knappworst et al. | Jan 1981 | A |
4655140 | Schirneker | Apr 1987 | A |
4685397 | Schirneker | Aug 1987 | A |
5127332 | Corzine et al. | Jul 1992 | A |
5259320 | Brooks | Nov 1993 | A |
5454325 | LeBlank | Oct 1995 | A |
5565649 | Tougeron et al. | Oct 1996 | A |
6070532 | Halverson | Jun 2000 | A |
6317946 | Beal | Nov 2001 | B1 |
6526893 | May et al. | Mar 2003 | B2 |
6546875 | Vaughn et al. | Apr 2003 | B2 |
6675718 | Parker | Jan 2004 | B1 |
7380502 | Emary | Jun 2008 | B2 |
7913626 | Reinhardt et al. | Mar 2011 | B1 |
8186277 | King | May 2012 | B1 |
8393273 | Weeks et al. | Mar 2013 | B2 |
10690463 | Carbone | Jun 2020 | B2 |
20040089186 | Brygdes-Price | May 2004 | A1 |
20070204758 | Spatz | Sep 2007 | A1 |
20110252999 | Carlson et al. | Oct 2011 | A1 |
20120216700 | Dennison | Aug 2012 | A1 |
20140202351 | Muskat | Jul 2014 | A1 |
20160356584 | Monroe et al. | Dec 2016 | A1 |
20160377399 | Burrow | Dec 2016 | A1 |
Number | Date | Country |
---|---|---|
190622505 | May 1907 | GB |
0118483 | Mar 2001 | WO |
Entry |
---|
https://www.nammo.com/product/our-products/ammunition/small-caliberammunition/7-62mm-series/7-62-mm-x-51-armor-piercing-8-m993/. Date accessed: Dec. 13, 2021. |
https://cuttingedgebullets.com/shop?product_list_limit=all. Date accessed: Dec. 15, 2021. |
https://cuttingedgebullets.com/277-6-8mm-100gr-esp-raptor. Date accessed: Dec. 15, 2021. |
https://cuttingedgebullets.com/277-6-8mm-110gr-esp-raptor. Date accessed: Dec. 15, 2021. |
https://cuttingedgebullets.com/277-6-8mm-85gr-esp-raptor. Date accessed: Dec. 15, 2021. |
https://cuttingedgebullets.com/366-9-3mm-210gr-esp-raptor. Date accessed: Dec. 15, 2021. |
https://cuttingedgebullets.com/416-300gr-esp-safari-raptor. Date accessed: Dec. 15, 2021. |
https://www.lehighdefense.com/338-caliber-245gr-match-solid-target-rifle-bullets.html. Date accessed: Dec. 15, 2021. |
https://www.lehighdefense.com/416-caliber-416gr-match-solid-target-rifle-bullets.html. Date accessed: Dec. 15, 2021. |
Number | Date | Country | |
---|---|---|---|
20210055086 A1 | Feb 2021 | US |
Number | Date | Country | |
---|---|---|---|
62518334 | Jun 2017 | US | |
62445697 | Jan 2017 | US |
Number | Date | Country | |
---|---|---|---|
Parent | 15870769 | Jan 2018 | US |
Child | 16897833 | US |