The present invention is generally directed to a wad for containing and deploying shot from a shotgun cartridge. Specifically, the present invention is directed to a wad having weighting elements for axially shifting the center of gravity of the wad and correspondingly the separation between the wad and the shot load.
Shotgun cartridges typically comprise a propellant charge, a wad and a shot load, all of which are contained within a plastic or paper shell reinforced at one end with a metal case head to contain and direct the created propellant gases through the opposite end of the cartridge. The shotgun wad typically comprises a polymer or fabric body that obturates against the barrel during firing to prevent escape of propellant gases around the slug or through the shot. The wad often comprises a forward facing cup portion or wings that contains the shot or slug as the shot travels through the barrel. Upon exiting the barrel, aerodynamic drag on the cup or the flaring of the wings slows the wad separating the wad from the slug or shot and freeing the projectile(s) to travel onto the target alone.
A primary consideration is determining the performance of a shot loaded shotgun cartridge is determining the maximum effective range at which there is sufficient shot density to accurately strike a target. A standard measurement for determining the effective range of the shotgun cartridge is patterning or measuring the percentage of shot that strikes within a 30 inch circle at 40 yards or other predetermined distance. The tightness of the pattern or the percentage of shot that strikes within the circle can be affected the size and shape of the shot, the size of the propellant load and the separation point between the wad and the shot. For the purposes of this disclosure, the separation point is the point during flight in which wad dispenses the shot load from the cup portion.
In particular, the conventional understanding of the effect of the wad on patterning of the shot load is that the longer the wad remains with the shot during flight, the greater the likelihood that the wad will worsen the patterning of the shot load or produce an irregular shot pattern. Wads are typically designed to incur significant aerodynamic drag upon leaving the muzzle through a forward facing cup portion or flaring wings that slow the wad while the shot and slug continues onto the target. The intentionally poor aerodynamic qualities of the wad can cause the wad to tumble or veer off the desired trajectory. The greater the distance of the separation point from the muzzle the more likely that the wad may negatively impact the trajectory of the shot or the slug. As a result, the wad is typically designed to have a separation point as close to the end of the muzzle as possible.
In certain wads, the wad is commonly formed by folding four separate wings together to define the walls of the cup. The wings flare open immediately upon leaving the muzzle to slow the wad and release the load as soon as possible. Similarly, certain shotgun chokes, such as disclosed in U.S. Pat. No. 7,523,581, slow the wad as the wad passes the choke to begin to separate the shot from the load even before the wad exits the muzzle. In both configurations, the wad is rapidly slowed to facilitate a separation point as close to the muzzle of the barrel as possible.
A similar consideration is that different shot patterns and densities are required for different uses. A choke is typically placed at the muzzle of the shotgun to set the rate at which the shot expands to control the resulting shot pattern. Different chokes are used to create different shot patterns. However, because the choke is positioned at the muzzle of the shotgun, a conventional choke may not sufficiently constrict the shot pattern such that the desired shot pattern is obtained. Certain shotgun cartridges, such as disclosed in U.S. Pat. No. 7,243,603, contain a shot container for receiving the shot and placed within the wad. Upon firing, the shot container is released from the wad and travels a distance with the shot retained within the container before dispensing the shot to expand radially. However, the shot container adds an additional feature to the manufacturing of the shotgun cartridges and can also potentially negatively influence the resulting shot pattern. In addition, the container occupies space within the already limited dimensions of the shotgun cartridge that could be otherwise used for the propellant charge or shot load.
The conventional understanding in the art is that the wad is a hindrance to achieving the desired shot patterning. However, the conventional means of controlling the shot pattern are not always sufficient to provide the desired shot pattern.
The present invention is generally directed to a shotgun wad having a weighted front end that shifts the center of gravity of the wad axially forward toward the nose end of the wad. Each wad can comprise a nose portion defining a forward facing cup portion for receiving a shot load and a tail portion defining a rear facing cup portion interfacing with a propellant charge. The forward weighting of the wad and overall increased weighting of the wad increases aerodynamic stability and the momentum of the wad such that the wad maintains its initial trajectory for a greater distance before aerodynamic drag causes the wad to tumble or veer off the initial trajectory. The improved aerodynamic stability allows for a delayed separation point between the wad and the shot providing denser patterning down range. In one aspect, the improved stability can also reduce the tumbling or oscillation of the wad in flight, which can alter the shot pattern as the shot load is dispensed from the wad providing inconsistent or uneven patterning.
The forward weighting of the center of gravity of a wad, according to an embodiment of the present invention, creates an increased axial separation between the center of gravity and the center of pressure improving the overall stability of the wad. For the purposes of this disclosure, the center of pressure is the average location of the air pressure acting on the wad as the wad travels through the air. The conventional understanding is that the forward center of gravity is provided by the shot load and the most effective way of improving the wad stability is to move the center of pressure rearward as shown in U.S. Pat. No. 3,516,360, which is herein incorporated by reference in its entirety. The inherent drawback is that as the shot load is dispensed from the wad cup, the center of gravity of the wad shifts rearward decreasing the aerodynamic stability of the wad. It has been discovered to be advantageous to front weight the wad itself to avoid a significant loss of stability as the shot load is dispensed from the wad and the overall center of gravity of the wad and contents combination (after the shot load departs) shifts rearward.
Similarly, the weight distribution of conventional wads is typically governed by thickness of the portion of the wad between the forward facing cup containing the shot load and the rear facing cup interfacing with the propellant charge. The thickness of the intermediate portion is often varied as a space filling or saving technique after the overall length of the cartridge, type of shot load, the size of the propellant charge, type of propellant, the weight ratio of the shot load to the propellant charge and other factors are varied to affect some aspect of the cartridge performance. In particular, target load cartridges that typically comprise with lighter shot loads and smaller propellant loads can comprise thick tail portions to fill the empty space within the projectile shifting the center of gravity of the wad rearward and lowering the aerodynamic stability of the wad. Accordingly, the front weighting of the wad itself improves the aerodynamic stability of the wad even if the tail portion is varied to fill or make space within the cartridge.
The extended flight along the initial trajectory positions the separation point at a greater distance from the barrel. In contrast to the conventional understanding, maintaining the wad with the shot to a separation point further from the barrel muzzle does not negatively influence the shot pattern and instead advantageously provides denser patterning at longer ranges. In one aspect, the reduced tumbling from the axial separation also eases the separation of the wad from the shot load providing the advantage of denser patterning further down range provided by a delayed separation point while avoiding the negative effect of a wad beginning to tumble or veer off trajectory as the shot load is separating from the wad.
In one aspect, the weighted shotgun wad can comprise a molded nose portion and a separately molded tail portion. In this configuration, the nose and tail portions can each comprise generally tubular cup shapes wherein the closed end of each cup are affixed together to define a wad having a forward facing cup and a rear facing cup. The nose portion can be molded from a different material from the tail portion, wherein the nose portion comprises a higher density material than the tail portion. The more heavily weighted nose portion shifts the center of gravity axially forward relative to the center of pressure as compared to similarly shaped wads molded as a unitary body or of the same material throughout. In this configuration, nose portions comprising different weighting can be provided and affixed to the tail portion allowing tailoring of the separation point by adjusting the relative axial separation of the center of gravity and center of pressure. The customizability of the wad provides the added advantage of allowing the wad to be tailored for different shot sizes and propellant loads to optimize the separation point for the desired shot patterning. The interchangeability of the nose and tail portions of the shotgun wad also simplifies the manufacturing process as only a single type of tail portions must be manufactured.
In one aspect, the wad can be molded as a single unitary body with a weighted ring portion molded or fitted to the nose portion of the unitary body. In one aspect, the weighted ring can be overmolded onto the nose portion of the same material to provide additional material at the tip of the nose portion for shifting the weighting of the unitary body. Alternatively, the ring can comprise a different denser material overmolded, adhered or otherwise affixed to the nose portion of the unitary body. In this configuration, the ring can comprise a polymer, a metal, a composite material or other denser material for providing a front weighted nose portion. The ring can have an increased axially length to provide additional material for increasing the weight at the front end of the wad.
In one aspect, the wad can be molded as a single unitary body with a rearward portion of the nose portion overmolded over a weighted forward ring portion of the nose portion. In embodiments either one of the nose portion and the tail portion may be overmolded on the other of the nose portion and tail portion, forming a unitary wad. In embodiments, each of the nose portion and the tail portion comprise a specific polymer of like polymer to facilitate the adhesion of the nose portion and the tail portion.
The inventions herein are applicable to existing configured wads to increase the range, to vary the pattern density or to allow providing a variety of differently performing shotgun shell cartridges by changing the wad to a like configured wad only with different weighting characteristics. For example, in a known wad, aspects of the inventions herein are applicable to wads with a tail portion comprising fin slits cut into the end of the tail portion such that the end opens into a plurality of rearward extending fins once the wad leaves the muzzle. The fins open as the wad leaves the muzzle to extend radially outward and axially rearward stabilize the wad in flight such that the wad flies straight through the air. Adding forward weighting can further enhance the flight characteristics and shot gun shell performance. Also, known wads have nose portions with a u-shape cut that opens into a flap that allows the elongated walls of the nose portion to flex as the wad travels through the barrel and the air. The flexing of the elongated walls dislodges any shot wedged into the cup portion from the initial acceleration of the wad during firing. Although such configurations typically move the center of pressure forward on the wad, forward weighting by the techniques disclosed herein can still provide performance enhancement. Other known wad configurations, by utilizing forward weighting techniques disclosed herein may also have there performance enhanced and provide manufacturing advantages such as easily providing series of differently performing shotgun shell cartridges by simply providing different forward weighting configurations.
A method for making a wad, according to an embodiment of the present invention, can comprise pre-molding the nose portion from a first material before molding the tail portion over a portion of the nose portion from a second material. Alternatively, the tail portion can be pre-molded from the second material before the nose portion is over-molded onto the tail portion from the first material According to an embodiment, the nose portion and the tail portion can be separately molded and fitted together such that the nose and tail assemblies can separate during flight. The first material can comprise a stiff and dense polymer or lightweight metal. The second material can comprise a polymer that is lighter than the first material such that the center of gravity is shifted toward the front of the nose. Depending on the desired separation point, the relative difference in weight between the first polymer and the second material can be adjusted to customize the separation point. As the tail and nose portion are separately formed, the tail portion can be standardized while the nose assemblies can be varied to have different separation points to have different resulting shot patterns. The modular design provides significant manufacturing advantages as the tail portion can be standardized.
A method for making a wad, according to an embodiment of the present invention, can comprise pre-molding the wad, wherein the wad comprises a nose portion and a tail portion. In one aspect, the nose portion and tail portion can be separately molded and fitted together. In another aspect, the nose and tail portions can be molded together as a single unitary body. The method can further comprise fitting a weighting ring to the nose portion of the wad. In one aspect, the weighting ring can be overmolded onto the nose portion 34. In another aspect, the weighted ring can be separately molded or manufactured and adhered or otherwise affixed to the nose portion of the wad. The method can also comprise varying the weight of the ring to tailor the separation point of the wad from the shot.
In embodiments, overmolding one of (a first component) the tail portion and nose portion to the other (second component) of the tail portion and nose portion, the first component can have structure, such as a protruding flange, such that the overmolded second component has a mechanical connection formed by the overmolding process.
Embodiments of the invention include coinjection molding the nose portion and the tail portion, with the nose portion and the tail portion comprising different formulations whereby the nose portion is denser than the tail portion. In such embodiments, the nose portion may be a first formulation and the tail portion a second formulation with the first formulation being denser than the second formulation. In embodiments both formulations are polymers. In embodiments both formulations comprise a common polymer thereby assuring adhesion between the two formulations.
Embodiments of the invention include coinjection molding portions of the nose portion defining a weighted nose portion with the rest of the nose portion and the tail portion, with the weighted portion of the nose portion comprising a first formulation and the balance of the nose portion and the tail portion comprising a second formulation with the first formulation being denser than the second formulation. In embodiments both formulations are polymers. In embodiments both formulations comprise a common polymer thereby assuring adhesion between the two formulations.
Particular embodiments of the invention provide a method of manufacturing shot gun cartridges that vary the shot pattern, particularly the shot spread at desired distances, by altering only the wadding in a shotgun shell and maintain all other configurations and quantities the same. That is, by providing a particular shotgun shell with differently weighed wads, the separation time is varied, the stability of the flight may be enhanced, and extended and the shot pattern varied as desired. In embodiments, the weight of conventional wad material, such as polyethylenes, have a specific gravity of less than 1.0, typically less than 0.975. By adding filler material, the specific gravity can be increased by, for example 10%, to 1.1 or greater. Fillers may be conventional fillers used in injection plastic molding, glass fibers, carbon, carbon fibers, steel, iron particles, or other materials may be used that increase the specific gravity of the material. In embodiments the entire wad material may have such a fillers or fillers, increasing the entire weight of the wad. In embodiments, just the nose portion, or a forward portion of the nose portion may be filled with such. Thus, particular embodiments of the invention include shotgun shell wads formed of polyethylene filled thereby increasing the density and weight of the nose portion or forward portion of the nose portion; in embodiments, the entire length of the wad may utilize the polyethylene filled with the weighting material. In other embodiments, polymers may be selected that have a density greater than 1.0 and utilized for the nose portion or a forward portion of the nose portion, in conjunction with an attached tail portion. In other embodiments, the nose portion may be a blended polymer or copolymer formed of the material of the tail portion, and another more dense polymer, thereby increasing the weight of the nose portion, moving the center of gravity forward in the wad, and delaying separation of the wad and the shot load after firing, enhancing the stability of the wad during flight, thereby enhancing the shot pattern and generally increasing the range of the shotgun shell cartridge.
Particular embodiments of the invention provide a method of tightening and/or uniformizing the shot patterns of shot gun shell cartridges by extending the time (and distance) that the wad with the shot cup stays in engagement with the shot. In embodiments, this is accomplished by increasing the density of the material of the wad at the nose portion or at the forward portion of the nose portion, thereby increasing the weight of the nose portion and thereby moving the center of gravity of the wad forward.
The above summary of the various representative embodiments of the invention is not intended to describe each illustrated embodiment or every implementation of the invention. Rather, the embodiments are chosen and described so that others skilled in the art can appreciate and understand the principles and practices of the invention. The figures in the detailed description that follow more particularly exemplify these embodiments.
The invention can be completely understood in consideration of the following detailed description of various embodiments of the invention in connection with the accompanying drawings, in which:
While the invention is 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 invention 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 invention as defined by the appended claims.
As shown in
According to an embodiment, the tail portion 42 can comprise at a plurality of fins 46 defined by slits 48. The fins may provide obturation with the barrel upon firing and the ends 49 of the fins flare radially outward as the wad 22 leaves the muzzle of the gun to engage the air and stabilize the wad 22 during flight. In one aspect, the fins 46 can move the center of pressure rearward axially relative to the center of gravity to further improve the aerodynamic stability of the wad 22 as depicted in
In embodiments, the nose portion 34 can comprise a first material, while the tail portion 36 can comprise a second material, wherein the first material has a higher density than the second material to shift the center of gravity of the wad 22 forward axially toward the nose end of the wad 22 away from the center of pressure of the wad 22 compared to the position of the center of gravity in the configuration where the first material is the same as the second material. In embodiments, the first material can comprise a density of at least 0.90 g/cm3. In another embodiments, the first material can comprise a density of at least 0.95 g/cm3. In yet another aspect, the first material can comprise a density between about 0.90 g/cm3 and about 1.00 g/cm3. In embodiments, the first material will have a density at least 5% higher than the second material. In embodiments, the first material will have a density at least 10% higher than the second material. In embodiments, the first material will have a density at least 20% higher than the second material. In embodiments, the first material will have a density at least 40% higher than the second material. In embodiments, the first material will have a density at least 100% higher than the second material. In embodiments, both the first and second material can comprise high density polyethylene polymers and copolymers of varying densities as well as other durable polymers.
In embodiments, the nose portion 34 can comprise a weight 10% greater than the tail portion 36. Alternatively, at least 5% more of the total weight of the wad 22 is positioned in the nose portion 34 than the tail portion 36. In another aspect, the nose portion 34 can comprise a weight 20% greater than the tail portion 36. Alternatively, at least 10% more of the total weight of the wad 22 is positioned in the nose portion 34 than the tail portion 36. In yet another aspect, the nose portion 34 can comprise a weight 30% greater than the tail portion 36. In this configuration, at least 15% more of the total weight of the wad 22 is positioned in the nose portion 34 than the tail portion 36.
In embodiments, the total weight of the wad 22 can comprise at least 50 grains for a 2¾ inch 12 gauge shotgun cartridge 20, with the nose portion 34 weighing more than the tail portion 36. In another aspect, the wad 22 can weigh at least 55 grains for a 2¾ inch 12 gauge shotgun cartridge 20, with the nose portion 34 weighing more than the tail portion 36. In yet another aspect, the wad 22 can weigh at least 55 to 60 grains for a 2¾ inch 12 gauge shotgun cartridge 20, with the nose portion 34 weighing more than the tail portion 36. In this configuration, the nose portion 34 can weigh about 5 to 15 grains more than the tail portion 36. A person of ordinary skill in the art can appreciate that the overall weight of the wad 22 can increase or decrease proportionally for different cartridge 20 diameters including, but not limited to 0.410 gauge, 20 gauge, 16 gauge and 10 gauge. Similarly, a person of ordinary skill in the art can appreciate that the overall weight of the wad 22 can increase or decrease proportionally for different cartridge 20 lengths including, but not limited to 3 inch and 3½ inch cartridges 20.
In embodiments, the center of gravity of the wad will be closer to the leading edge than the trailing edge. In embodiments, the center of gravity will be shifted at least 5% of the length of the wad forward compared to a wad of the same shape where the nose portion and tail portion are formed of the same material. In embodiments, the center of gravity will be shifted at least 10% of the length of the wad forward compared to a wad of the same shape where the nose portion and tail portion are formed of the same material. In embodiments, the center of gravity will be shifted at least 20% of the length of the wad forward compared to a wad of the same shape where the nose portion and tail portion are formed of the same material. In embodiments, the center of gravity will be shifted at least 30% of the length of the wad forward compared to a wad of the same shape where the nose portion and tail portion are formed of the same material.
In embodiments, the nose portion 14 and tail portion 16 are adapted to be modular such that different nose portions 14 having different weights can be fitted to a tail portion 16 having a consistent weight such that the separation point between the wad 4 and the load 8 can be optimized for the particular load 8 and/or use for the cartridge 2. In this configuration, the nose portion 34 and tail portion 36 can be affixed together with adhesive, molding or other conventional means of securing the nose and tail portions 34, 36 together. The first material can comprise a durable polymer resistant to splitting of the side wall 38, which cause the side walls 38 to petal and slow the wad 22 causing premature separation of the shot load 28 from the wad 22. In one aspect, the fins 46 of the tail portion 36 can cooperate with the axial separation of the center of gravity and the center of pressure to maintain the trajectory of the wad 22 along the initial trajectory of the wad 22 as the wad 22 leaves the muzzle of the barrel.
As depicted in
As depicted in
In operation, the propellant is ignited by the primer 26 and the created gasses expand behind the tail portion 36 of the wad 22 to push the wad 22 and load 28 down the barrel. Unlike conventional wads that separate from the load immediately upon exiting the muzzle, the wad 22 remains with the load 28 until a predetermined distance from the muzzle is reached. The relative weight of the nose portion 34 to the tail portion 36 can be adjusted by changing the relative weight of the nose portion 34 to the tail portion 36. The greater the weight of the nose portion 34 relative to the tail portion 36, the further the separation point is from the muzzle. Similarly, the closer the relative weights of the nose portion 34 and the tail portion 36, the closer the separation point is from the muzzle.
As depicted in
A method for making a wad 22, according to an embodiment of the present invention, can comprise pre-molding the nose portion 34 from a first material before molding the tail portion over a portion of the nose portion 34 from a second material. Alternatively, the tail portion 36 can be pre-molded from the second material before the nose portion 34 is over-molded onto the tail portion 36 from the first material. According to an embodiment, the nose portion 34 and the tail portion 36 can be separately molded and fitted together such that the nose and tail assemblies 34, 36 can separate during flight.
A method for making a wad 22, according to an embodiment of the present invention, can comprise pre-molding the wad 22, wherein the wad 22 comprises a nose portion 34 and a tail portion 36. In one aspect, the nose portion 34 and tail portion 36 can be separately molded and fitted together. In another aspect, the nose and tail portions 34, 36 can be molded together as a single unitary body. The method can further comprise fitting a weighting ring 52 to the nose portion 34 of the wad 22. In one aspect, the weighting ring 52 can be overmolded onto the nose portion 34. In another aspect, the weighted ring 52 can be separately molded or manufactured and adhered or otherwise affixed to the nose portion 34 of the wad 22. The method can also comprise varying the weight of the ring to tailor the separation point of the wad 22 from the shot load 28.
While the invention is amenable to various modifications and alternative forms, specifics thereof have been shown by way of example in the drawings and described in detail. It is understood, however, that the intention is not to limit the invention 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 invention as defined by the appended claims.
The present application is a continuation of U.S. patent application Ser. No. 13/683,795, filed on Nov. 21, 2012, which claims the benefit of U.S. Provisional Patent Application No. 61/562,361, filed on Nov. 21, 2011, all of which are incorporated herein in their entireties by reference.
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Number | Date | Country | |
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20150345918 A1 | Dec 2015 | US |
Number | Date | Country | |
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61562361 | Nov 2011 | US |
Number | Date | Country | |
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Parent | 13683795 | Nov 2012 | US |
Child | 14823769 | US |