Shotguns of any particular gauge may fire different shotshell cartridges with different payloads and propellant loads. With pump action shotguns the recycling occurs after the firing of the shotshell cartridges and occurs manually. Thus, there is no relation of the type of propellant load to the recycling reliability of the shotgun. In gas operated semiautomatic shotguns, the recycling occurs by bleeding off propellant gas from the barrel to actuate a piston connected to the breech block. The reliability of the cycling can be affected by the type of shotshell cartridge fired, the maintenance of the shotgun, as well as the wear on components of the shotgun. A shotgun that reliably cycles for a magnum round that produces higher barrel pressures might not cycle for a lower powered skeet round with lower barrel pressures. And a shotgun that cycles for both a lower powered skeet round and a magnum powered round may subject the cycle mechanism components to higher forces causing premature wear and failure of components or function.
The prior art shotguns disclose attempts to provide active or passive adjustment of the gas entering the piston cylinder or cylinders. Some semiautomatic shotguns allow manual user adjustment, for example, switching between a “normal” and “heavy” load, where the heavy setting allows more gas to escape the system before entering the piston cylinder. In another prior art shotgun, see U.S. Pat. No. 8,443,712, the gas ports are positioned in the cartridge chamber region of the barrel in a manner so as to be covered or not covered depending on the cartridge length. With longer 3 and 3½ inch cartridges some of the ports are covered up by the end of the cartridge body, preventing them from taking in extra gas. This has the effect of reducing the pressure and amount of gas bleed from the barrel reducing the bolt velocity where the cartridges are longer. It does not however, strictly speaking, gauge the energy of the cartridge. It effectively groups the cartridge energy by length. While in general longer cartridges are typically higher energy, this is not always the case. For example, there are high power magnum 2% inch cartridges. In this system such cartridges would be “read” as lower power. The length of the cartridge does not directly determine its energy. Therefore, this system has a coarse resolution of adjustment. A finer adjustment based upon and by determining the actual power of the cartridge would be desirable.
Build-up of debris in the gas operating systems can also impact cycling reliability. Conventional gas operated shotguns bleed gas pressure from the barrel through ports, conventional ports can shave polymer from the cartridge wads causing reliability issues with the gas operating system. This can be minimized by angling the ports, but this is difficult and expensive in a manufacturing environment. Improvement in versatility, reliability, and simplicity of semiautomatic shotguns when used with different powered shotshell cartridges would be welcomed by the shooting public. Improvements in manufacturing techniques that are cost effective would be welcomed by firearm manufacturers.
A gas operated semiautomatic shotgun has features for faster and more reliable cycling over a wide range of differently powered ammunition and that provides less recoil as compared to conventional semiautomatic shotguns. Additionally, features are provided for more robust mechanisms requiring less cleaning and/or maintenance than conventional gas operated semiautomatic shotguns. Additionally, features are provided for quick, simple, and essentially tool-less disassembly and assembly.
In embodiments, a semiautomatic shotgun has a receiver, a buttstock extending rearwardly, a barrel extending forwardly from the receiver, a magazine tube below the barrel, a fore stock below the barrel at a forward end of the magazine tube, trigger mechanism in the receiver, a gas block assembly at the forward end of the fore stock, a piston in the gas block, the piston engaging a slider connecting to a breech block in the receiver by way of a pair of arms. A plunger assembly extending into the buttstock with a plunger tip projecting into the receiver for engaging the rearward end of the breech block.
In embodiments, the gas block assembly including a gas block fixed to the barrel and fluidly connecting with the barrel bore through holes in the barrel. The gas block assembly including a pair of pressure relief valves. In embodiments, an annular piston in the gas block assembly is positioned in a piston cylinder defined by the magazine tube and the gas block. Upon firing the shotgun, the annular piston is in engagement with a slider on the magazine tube and pushes the slider rearwardly. In embodiments, the slider is unitary with a pair of action bars or legs, and a bolt carrier or breech block. The slider, action bars, and bolt carrier move rearwardly ejecting the spent cartridge in the chamber, re-cocking the hammer, compressing a return spring on the magazine tube, moving a new cartridge into position for chambering. The rear end of the breech block engages the tip of the plunger that extends into the receiver compressing a compressible member of the plunger assembly. In embodiments the compressible member is one or more steel coil springs. In embodiments the compressible member is a rigid polymer tube, for example, urethane. The compressible member dampens the energy of the unitary slider, action bars, and breech block. The polymer compressible member reduces the kick from the rearward traveling breech block. In embodiments, the polymer tube can be compressed about an eighth of an inch, and an interior rear surface of the receiver provides a hard stop to the breech block, action bars, and slider. At the stop point the recoil spring drives breech block, action bars, and slider forwardly loading the next cartridge into the chamber and pushing the annular piston back into the gas block assembly and putting the breech block into the in-battery position.
In embodiments, a semiautomatic shotgun has a gas operating system that includes a pair of non-adjustable pressure relief valves mounted in a gas block on the barrel positioned at a forward end of the fore stock. The pressure relief valves have conical valve seats and a conical engaging surface on an axially movable hollow valve member. The valve member with apertures proximate the conical engaging surface extending to the hollow interior of the valve member. The pressure relief valves, when activated by a predetermined gas pressure vents gas forwardly out of the open front of the valve through the hollow valve member providing a high volume and fast acting gas vent system. In embodiments, the pressure relief valves also vent laterally out of a side port in the valve housing and A plurality of rows of circumferential rib segments provide a scrubbing action inside of the pressure relief valve housing minimizing or eliminating potential carbon buildup. Longitudinal grooves on the exterior of the valve member in between the circumferential rib segments provide a vent pathway to the side port.
A semiautomatic shotgun, the shotgun comprising a barrel, a cycling piston in a cylinder defining a piston chamber below the barrel, the barrel having a propellant gas diversion from a pair of ports in the barrel, through a pair of first gas passageways, into a pair of lateral chambers positioned on both sides of the barrel, each of the chambers having pressure relief valves therein. The chambers each further having a second gas passageways to the piston chamber for recycling the shotgun.
In embodiments, the barrel may have multiple gas ports for bleeding the propellant gas into the dual regulating valve system. In embodiments, each valve can have two barrel ports providing gas thereto for regulating the pressure level entering the piston chamber. In embodiments, each valve can have four barrel ports providing gas thereto for regulating the pressure level entering the piston chamber. In embodiments, each valve can have six barrel ports providing gas thereto for regulating the pressure level entering the piston chamber. In embodiments, each valve can have eight barrel ports providing gas thereto for regulating the pressure level entering the piston chamber. The inventors have discovered that multiple ports positioned forward of the cartridge chamber has several beneficial effects. First, compared to multiple ports at the cartridge chamber, it is believed less energy for propelling the shot is lost at this location as the shot has already reached a high velocity. Second, multiple ports provide an increased area for bleeding more gas without the potential of shaving the wads as a single port with comparable area. Third, where a single port is utilized, typically the hole is drilled at a 45 degree angle (facing rearwardly) so that the polymer shotgun wads passing by are exposed to minimal sharp hole edges that can create polymer shavings. The smaller holes may be drilled at 90 degrees to the barrel axis; this is a much easier and less expensive manufacturing process than drilling barrel holes at angles to the axis. The smaller holes are, for example, less than 0.070 inches in diameter and do not appear to create any wad shavings. Moreover, the inventors have discovered that longer barrels require fewer holes for the same cycling energy. The longer barrels creating greater gas pressures rearward of the wad and shot traveling down the barrel. In embodiments, a shotgun has several interchangeable barrels of different lengths that all provide the wide range of different powered shotgun shells without any adjustment to the shotgun. The receiver may readily accept the several different barrels that perform equivalently with respect to the cycling capabilities shooting different power level of shells. The longer the barrel of the several barrels, the fewer barrel ports the barrel has. Each of the several barrels may have the same regulator with the same settings
In embodiments, the propellant gas diversion is provided by two clusters of holes one cluster of holes leading to a first regulator cavity and one cluster of holes leading to a second regulator cavity. In embodiments, each cluster has at least four holes drilled in a direction perpendicular to the axis of the barrel, or at least not at a forward or rearward angle with respect to the barrel wall. In embodiments, the holes are less than 0.100 inches in diameter. In embodiments the holes are not larger than 0.067 inches in diameter. The inventors have discovered that a feature and advantage of holes on center with the axis of the barrel of such size is that abrasion or shaving of wads passing by the hole effectively does not happen, effectively eliminating debris entering the gas operating system including the pressure relief valves.
In embodiments, the second gas passageway is offset and nonlinear with the first gas pathway. The lateral chambers each having a cross sectional area greater than the first gas passageways and greater than the second gas passageways.
Embodiments of the shotgun provide a balanced reliable gas diversion system offering consistent cycling operation with different powered shotshell cartridges without the need for adjustment of the pressure relief valves, the pressure relief valves may be non-adjustable by the user.
In one or more embodiments, a semiautomatic shotgun comprises a receiver defining a receiver interior and a barrel attached to a forward portion of the receiver. The barrel has a barrel wall defining a barrel bore extending along a barrel axis of the barrel. The barrel wall defines a firing chamber that is dimensioned and configured to receiving a shell. A breech block is slidably received in the receiver interior. The breech block is movable between a forward position in which the breech block engages the breech end of the barrel for firing a chambered shell and a rearward position in which the breech block contacts a plunger of a spring loaded plunger assembly. In one or more embodiments, the spring loaded plunger assembly comprises the plunger, a first plunger spring, and a second plunger spring. In one or more embodiments, the first plunger spring defines a spring lumen and the second plunger spring is disposed inside the spring lumen defined by the first plunger spring. In one or more embodiments, a return spring provides a return force urging the breech block toward the forward position. In embodiments, the plunger assembly includes a preloaded polymer tubing segment as a spring. In an embodiment, for example, the tubing may be formed of a urethane.
In one or more embodiments, a gas operated mechanism is disposed about the magazine tube and the gas operated mechanism comprises an annular shaped piston. In one or more embodiments, combustion gasses apply pressure to a forward facing surface of the annular shaped piston, the pressure applied to the annular shaped piston creates a rearward force, and the rearward force urges the breech block toward the rearward position. In one or more embodiments, a slider is disposed about the magazine tube at a location rearward of the annular shaped piston. In one or more embodiments, a port leg and a starboard leg extend between the slider and the breach block. In one or more embodiments, combustion gasses apply pressure to a forward facing surface of the annular shaped piston, the pressure applied to the annular shaped piston creates a rearward force, and the rearward force is transferred to the breech block by the sleeve, the starboard leg and the port leg, the action bars.
In one or more embodiments, a semiautomatic shotgun comprises a receiver defining a receiver interior and a breech block that is slidably received in the receiver interior. The breech block is movable between a forward position in which the breech block engages the breech end of the barrel for firing a chambered shell and a rearward position in which the breech block is positioned rearward of the breech end of the barrel for discharging a spent shell. A barrel and a magazine tube extend forwardly from a forward portion of the receiver. The barrel has a breech end and a muzzle end. A barrel wall of the barrel extends between the breech end and the muzzle end. The barrel wall defines a barrel bore extending along a barrel axis of the barrel. The barrel wall defines a firing chamber and barrel bore, the firing chamber being dimensioned and configured to receiving a shell. The magazine tube has a rearward end and a forward end. A magazine wall of the magazine tube extends between the rearward end and the forward end. The magazine wall defines a magazine tube bore extending along a magazine axis of the magazine tube. The barrel axis and the magazine axis are parallel and define a vertical plane.
A semiautomatic shotgun in accordance with the embodiments described in the preceding paragraph may further include a gas block assembly including a gas block that is disposed about the magazine tube with the magazine tube extending through the block bore defined by the gas block. The gas block assembly includes a starboard regulator assembly and a port regulator assembly. The gas block defines a starboard regulator cavity and a port regulator cavity. The starboard regulator cavity extends along a starboard regulator axis and the port regulator cavity extends along a port regulator axis. The starboard regulator axis and the port regulator axis define a horizontal plane. In one or more embodiments, the horizontal plane defined by the starboard regulator axis and the port regulator axis is perpendicular to the vertical plane defined by the barrel axis and the magazine axis. In one or more embodiments, the starboard regulator assembly and the starboard regulator cavity are disposed starboard of the vertical plane defined by the barrel axis and the magazine axis. In one or more embodiments, the starboard regulator assembly and the starboard regulator cavity are disposed below the barrel axis and above the magazine axis. In one or more embodiments, the port regulator assembly and the port regulator cavity are disposed portward of the vertical plane defined by the barrel axis and the magazine axis. In one or more embodiments, the port regulator assembly and the port regulator cavity are disposed below the barrel axis and above the magazine axis.
A semiautomatic shotgun in accordance with the embodiments described in the preceding paragraph may further include a sleeve comprising a sleeve wall extending into the block bore defined by a gas block with a portion of the sleeve disposed between an outer surface of the magazine tube and inner surface of the gas block. In one or more embodiments, the magazine tube, the sleeve, and the gas block cooperate to define an annular volume. The annular volume communicates with the barrel bore so that combustion gasses can enter the annular volume. The starboard regulator assembly acts to release combustion gasses when the combustion gasses in the barrel bore and/or the annular volume reaches a first predetermined pressure. The port regulator assembly acts to release combustion gasses when the combustion gasses in the barrel bore and/or the annular volume reaches a first predetermined pressure. In one or more embodiments, the first predetermined pressure and the second predetermined pressure are different. In one or more embodiments, the first predetermined pressure is selected to correspond to a first shotshell load and the second predetermined pressure is selected to correspond to a second shotshell load. In one or more embodiments, the first predetermined pressure and the second predetermined pressure are substantially equal. In one or more embodiments, the first predetermined pressure and the second predetermined pressure have values within about ten percent of one another.
A semiautomatic shotgun in accordance with one or more embodiments comprises a receiver, a barrel and a magazine tube. The barrel and the magazine tube both extend forward beyond a forward end of the receiver with the magazine tube being located below the barrel. In an embodiment, a gas operated mechanism is disposed about the magazine tube. In an embodiment, the gas operated mechanism comprises a gas block assembly that including an annular shaped piston. In an embodiment, the annular shaped piston extends into a block bore defined by a gas block of the gas block assembly. In an embodiment, the block bore extends along a block bore axis. In an embodiment, the gas block assembly includes a starboard regulator housing defining starboard regulator cavity that extends along a starboard regulator axis. In an embodiment, the starboard regulator housing comprises a first starboard male thread and the first starboard male thread is disposed in threaded engagement with a first starboard female thread of the gas block. In an embodiment, a starboard valve member is disposed in the starboard regulator cavity with a seating surface of the starboard valve member is biased to seat against a complementary surface of the starboard regulator housing by a starboard spring. In an embodiment, a forward end of the starboard spring seats against the starboard valve member and a rearward end of the starboard spring seats against a starboard retainer. In an embodiment, the starboard retainer comprises a second starboard male thread and the second starboard male thread is disposed in threaded engagement with a second starboard female thread of the starboard regulator housing. In an embodiment, the gas block assembly includes a port regulator housing defining port regulator cavity that extends along a port regulator axis. In an embodiment, the port regulator housing comprises a first port male thread and the first port male thread is disposed in threaded engagement with a first port female thread of the gas block. In an embodiment, a port valve member is disposed in the port regulator cavity with a seating surface of the port valve member is biased to seat against a complementary surface of the port regulator housing by a port spring. In an embodiment, a forward end of the port spring seats against the port valve member and a rearward end of the port spring seats against a port retainer. In an embodiment, the port retainer comprises a second port male thread and the second port male thread is disposed in threaded engagement with a second port female thread of the port regulator housing. In an embodiment, the starboard regulator axis, the port regulator axis, and the block bore axis define a triangular prism comprising a first base, a second base and three side faces. In an embodiment, the starboard regulator axis and the block bore axis define a first plane and a first side face of the triangular prism lies in the first plane. In an embodiment, the port regulator axis and the block bore axis define a second plane and a second side face of the triangular prism lies in the second plane. In an embodiment, the starboard regulator axis and the port regulator axis define a third plane and a third side face of the triangular prism lies in the third plane.
A semiautomatic shotgun in accordance with one or more embodiments comprises a receiver defining a receiver interior and a barrel attached to a forward portion of the receiver. The barrel has a breech end and a muzzle end. A barrel wall of the barrel extends between the breech end and the muzzle end. The barrel wall defines a barrel bore extending along a longitudinal axis of the barrel. The barrel wall defines a firing chamber with the barrel bore, the firing chamber being dimensioned and configured to receiving a shell.
In one or more embodiments, a breech block is slidably received in the receiver interior. The breech block is movable between a forward position in which the breech block engages the breech end of the barrel for firing a chambered shell and a rearward position in which the breech block is positioned rearward of the breech end of the barrel for discharging a spent shell. A magazine tube is attached to a forward portion of the receiver. The magazine tube has a rearward end and a forward end. A magazine wall of the magazine tube extends between the rearward end and the forward end. The magazine wall defines a magazine tube bore extending along a longitudinal axis of the magazine tube.
In one or more embodiments, the semiautomatic shotgun includes a sleeve having a circular or tubular shape and comprising a sleeve wall. The sleeve wall having an outer surface and an inner surface. The inner surface of the sleeve wall defining a lumen. The sleeve is positioned so that the sleeve wall encircles the magazine tube with the magazine tube extending through the lumen. The sleeve has a rearward end and a forward end. A first sealing ring is disposed between the inner surface of the sleeve and an outer surface of the magazine tube. In embodiments addition sealing rings may be placed between the inner surface of the sleeve and an outer surface of the magazine tube. One or more second sealing rings may be disposed between the outer surface of the sleeve and an inner facing bore surface of the gas block. The space between the inner facing surface of the gas block and the outer surface of the magazine tube defining an annular expansion chamber and the sleeve defining an annular piston.
In one or more embodiments, the gas block defines a channel and an upward facing opening fluidly communicating with the channel. The barrel extends into the channel. In one or more embodiments, the gas block is fixed to the barrel. The gas block has a rearward end and a forward end. The gas block has a body extending in a forward direction from the rearward end to the forward end and extending in a rearward direction from the forward end to the rearward end. The body of the gas block defines a pair of chambers, a starboard regulator cavity and a port regulator cavity.
In one or more embodiments, the starboard regulator cavity comprises a forward starboard bore, a rearward starboard bore and a starboard step or shoulder defining a valve seat between the forward starboard bore and the rearward starboard bore. The forward starboard bore extends in the forward direction away from the starboard valve seat. The starboard rearward bore extends in the rearward direction away from the starboard valve seat. The forward starboard bore is defined by a forward bore surface of the gas block. The rearward starboard bore is defined by a rearward bore surface. The starboard valve seat comprises a starboard valve seat surface extending between the forward starboard bore surface and the starboard rearward bore surface. The forward starboard bore has a first diameter, the starboard rearward bore has a second diameter. In one or more embodiments, the second diameter is greater than the first diameter. The forward starboard bore surface meets the starboard valve seat surface at an edge. A starboard valve member is disposed in the starboard regulator cavity. A seating surface of the starboard valve member is biased to seat against the edge by a starboard spring. A starboard guide extends through a lumen defined by the starboard spring and into a starboard pocket defined by the starboard valve member.
In one or more embodiments, the starboard forward bore of the starboard regulator cavity fluidly communicates with the barrel bore via a starboard passageway defined by the gas block and a starboard hole defined by the barrel. The forward starboard bore of the starboard regulator cavity fluidly communicates with the annular volume via a starboard aperture. Upon firing a shell with the shotgun, combustion gasses within the barrel enter the annular volume via the starboard hole and the port hole to move the sleeve and a slider rearward for cycling a mechanism disposed in the receiver interior.
In one or more embodiments, the semiautomatic shotgun includes a slider comprising a slider wall. The slider wall has an outer surface and an inner surface with the inner surface defining a lumen. The slider is positioned so that the slider wall encircles the magazine tube and the magazine tube extends through the lumen. The slider having a rearward end and a forward end. The slider wall extends between the rearward end and the forward end. A slider assembly includes the slider and a starboard leg having a forward end and a rearward end. A portion of the starboard leg proximate the forward end is fixed to the slider. A portion of the starboard leg proximate the rearward end engages the mechanism disposed inside the receiver interior. The slider assembly also includes a port leg having a forward end and a rearward end. A portion of the port leg proximate the forward end is fixed to the slider. A portion of the port leg proximate the rearward end engages the mechanism disposed inside the receiver interior.
A feature and advantage of embodiments of the invention is that the two regulators can be adjusted to have different pressure relief points wherein considering restricted volumetric passages to each, one may release for a certain barrel pressure, for example for a lowered powered cartridge, and the other does not release. And wherein for a higher pressure cartridge, both regulators may release.
A feature and advantage of embodiments is a semiautomatic shotgun that reliably cycles shotshells of different propellant loads.
A feature and advantage of embodiments is a semiautomatic shotgun with non adjustable pressure relief valves.
A feature and advantage of embodiments is a semiautomatic shotgun that reliably cycles shotshells of different propellant loads. In embodiments, a one-piece unitary action bar facilitates disassembly, cleaning, and maintenance.
A feature and advantage of embodiments is a semiautomatic shotgun with pressure relief valves that are self-cleaning, non-adjustable (without breaking high strength thread lock) and highly reliable, and resist carbon buildup.
A feature and advantage of embodiments is a semiautomatic shotgun that provides dual pressure relief valves adding reliability, redundancy, and a compact form factor. Moreover, the gas from the propellant is provided to the piston in a more balanced manner than conventional gas operated shotguns.
A feature and advantage of embodiments is a semiautomatic shotgun that is “over-gassed” taking more gas out of the barrel than typical. The over-gassing provides a wider range of cycling different powered shells and is accommodated by an enhanced recoil buffer system that allows faster cycling for high powered shells while minimizing the recoil felt by the user. Additionally a one piece action bar assembly eliminates or minimizes failures of the cycling system coming apart with loosening of connectors at this high speed of recycling. In embodiments, the gas ports are at least six inches from the rearward end of the firing chamber providing sufficient gas for operating the cycling mechanism with a wide range of differently powered shells without, it is believed sacrificing any meaningful kinetic energy of the projectiles being fired. Moreover, utilizing multiple ports per valve, rather than one, provides easier less costly manufacturing.
A feature and advantage of embodiments is a semiautomatic shotgun that provides dual pressure relief valves adding reliability, redundancy, and a compact form factor. Moreover, the gas from the propellant is provided to the piston in a more balanced manner than conventional gas operated shotguns.
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 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, for example, to
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Referring to
In one or more embodiments, a return spring 142 provides a return force urging the breech block 38 toward the forward position.
Referring to
In one or more embodiments, a gas operated mechanism 36 is disposed about the magazine tube 120 and the gas operated mechanism 36 comprises an annular shaped piston 250. In one or more embodiments, combustion gasses apply pressure to a forward facing surface of the annular shaped piston 250, the pressure applied to the annular shaped piston creates a rearward force, and the rearward force urges the breech block 38 toward the rearward position. In one or more embodiments, a slider 150 configured as a sleeve is disposed about the magazine tube 120 at a location rearward of the annular shaped piston 250. In one or more embodiments, an action bar 163 comprising a port leg 166 and a starboard leg 164 extend between the slider 150 and the breach block 38. In one or more embodiments, combustion gasses apply pressure to a forward facing surface of the annular shaped piston 250, the pressure applied to the annular shaped piston creates a rearward force, and the rearward force is transferred to the breech block 38 by the sleeve, the starboard leg 164 and the port leg 166.
Referring, for example, to
A semiautomatic shotgun in accordance with the embodiments described in the preceding paragraph may further include a gas block assembly 200 including a gas block 220 that is disposed about the magazine tube 120 with the magazine tube 120 extending through the block bore 222 defined by the gas block 220. The gas block assembly 200 includes a starboard regulator assembly 320 and a port regulator assembly 420. The gas block 220 defines a starboard regulator cavity 322 and a port regulator cavity 422. The starboard regulator cavity 322 extends along a starboard regulator axis 340 and the port regulator cavity 422 extends along a port regulator axis 440. The starboard regulator axis 340 and the port regulator axis 440 define a horizontal plane. In one or more embodiments, the horizontal plane defined by the starboard regulator axis 340 and the port regulator axis 440 is perpendicular to the vertical plane defined by the barrel axis 24 and the magazine axis 140. In one or more embodiments, the starboard regulator assembly 320 and the starboard regulator cavity 322 are disposed starboard of the vertical plane defined by the barrel axis 24 and the magazine axis 140. In one or more embodiments, the starboard regulator assembly 320 and the starboard regulator cavity 322 are disposed below the barrel axis 24 and above the magazine axis 140. In one or more embodiments, the port regulator assembly 420 and the port regulator cavity 422 are disposed portward of the vertical plane defined by the barrel axis 24 and the magazine axis 140. In one or more embodiments, the port regulator assembly 420 and the port regulator cavity 422 are disposed below the barrel axis 24 and above the magazine axis 140.
A semiautomatic shotgun in accordance with the embodiments described in the preceding paragraph may further include a sleeve 252 comprising a sleeve wall 262 extending into the block bore 222 defined by a gas block 220 with a portion of the sleeve 252 disposed between an outer surface of the magazine tube 120 and inner surface of the gas block 220. In one or more embodiments, the magazine tube 120, the sleeve 252, and the gas block 220 cooperate to define an annular volume 264. The annular volume 238 communicates with the barrel bore 22 so that combustion gasses can enter the annular volume 238. The starboard regulator assembly 320 acts to release combustion gasses when the combustion gasses in the barrel bore 22 and/or the annular volume 238 reaches a first predetermined pressure. The port regulator assembly 420 acts to release combustion gasses when the combustion gasses in the barrel bore 22 and/or the annular volume 238 reaches a first predetermined pressure. In one or more embodiments, the first predetermined pressure and the second predetermined pressure are different. In one or more embodiments, the first predetermined pressure is selected to correspond to a first shotshell load and the second predetermined pressure is selected to correspond to a second shotshell load. In one or more embodiments, the first predetermined pressure and the second predetermined pressure are substantially equal. In one or more embodiments, the first predetermined pressure and the second predetermined pressure have values within 10% of one another.
Referring, for example, to
The semiautomatic shotgun 10 includes a gas block assembly 200 with regulators or pressure relief valves 202, 204. The gas block 220 defining a block bore 222. The magazine tube 120 extends through the block bore 222 defined by the gas block 220. The block bore 222 may extend along a block bore axis 224. The sleeve 252 extends into the block bore 222 defined by a gas block 220 with a portion of the sleeve 252 being disposed between an outer surface of the magazine tube 120 and inner surface of the gas block 220. A second sleeve ring 232 is disposed between an outer surface of the sleeve 252 and an inner surface of the gas block 220. The second sleeve ring 232 defining a slot 242. The magazine tube 120, the sleeve 252, and the gas block 220 cooperate to define an annular volume 264. A stop ring 234 is received in the lumen defined by the sleeve wall 262.
The gas block 220 defines a channel 240 and an upward facing opening fluidly communicating with the channel 240. The barrel 20 extends into the channel 240. In one or more embodiments, the gas block 220 is fixed to the barrel 20. The gas block 220 has a rearward end and a forward end. The gas block 220 has a body 246 extending in a forward direction from the rearward end to the forward end and extending in a rearward direction from the forward end to the rearward end. The body 246 of the gas block 220 defines a starboard regulator cavity 322 and a port regulator cavity 422.
The starboard regulator cavity 322 comprises a forward starboard bore 335, a rearward starboard bore 338 and a starboard valve seat 346 disposed between the forward starboard bore 335 and the rearward starboard bore 338. The forward starboard bore 335 extends in the forward direction away from the starboard valve seat 346. The rearward starboard bore 338 extends in the rearward direction away from the starboard valve seat 346. The forward starboard bore 335 is defined by a forward starboard bore surface 340 of the gas block 220. The rearward starboard bore 338 is defined by a rearward starboard bore surface 342. The starboard valve seat 346 comprises a starboard valve seat surface 348 extending between the forward starboard bore surface 340 and the rearward starboard bore surface 342. The forward starboard bore 335 has a first diameter, the rearward starboard bore 338 has a second diameter. In one or more embodiments, the second diameter is greater than the first diameter. The forward starboard bore surface 340 meets the starboard valve seat surface 348 at a starboard edge 344. A starboard valve member 330 is disposed in the starboard regulator cavity 322. A seating surface of the starboard valve member 330 is biased to seat against the starboard edge 344 by a starboard spring 332. A starboard guide 334 extends through a lumen defined by the starboard spring 332 and into a starboard valve member pocket 352 defined by the starboard valve member 330.
The forward starboard bore 335 of the starboard regulator cavity 322 fluidly communicates with the barrel bore 22 via a starboard first passageway 354 defined by the gas block 220 and a starboard hole 50 defined by the barrel 20. The forward starboard bore 335 of the starboard regulator cavity 322 fluidly communicates with the annular volume 264 via a starboard aperture 350. Upon firing a shell with the shotgun, combustion gasses within the barrel 20 enter the annular volume via the starboard hole 50 and the port hole 52 to move the sleeve 252 and a slider 150 rearward for cycling a mechanism 36 disposed in the receiver interior 34.
The slider 150 comprising a slider wall 160. The slider wall 160 has an outer surface and an inner surface with the inner surface defining a lumen sized for the magazine tube 120. The slider 150 is positioned so that the slider wall 160 encircles the magazine tube 120 and the magazine tube 120 extends through the lumen. The slider 150 having a rearward end and a forward end. The slider wall 160 extends between the rearward end and the forward end. A slider assembly 161 includes the slider 150 and a starboard leg 162 having a forward end and a rearward end. A portion of the starboard leg 162 proximate the forward end is fixed to the slider 150. A portion of the starboard leg 162 proximate the rearward end engages the mechanism 36 disposed inside the receiver interior 34. The slider assembly 161 also includes a port leg 164 having a forward end and a rearward end. A portion of the port leg 164 proximate the forward end is fixed to the slider 150. A portion of the port leg 164 proximate the rearward end engages the mechanism 36 disposed inside the receiver interior 34. The semiautomatic shotgun 10 also includes a trigger 40, a trigger guard 42, a buttstock 44, a fore stock 46 and a cap 48.
The port regulator cavity 422 comprises a forward port bore 435, a rearward port bore 438 and a port valve seat 446 disposed between the forward port bore 435 and the rearward port bore 438. The forward port bore 435 extends in the forward direction away from the port valve seat 446. The rearward port bore 438 extends in the rearward direction away from the port valve seat 446. The forward port bore 435 is defined by a forward port bore surface 440 of the gas block 220. The rearward port bore 438 is defined by a rearward port bore surface 442. The port valve seat 446 comprises a port valve seat surface 448 extending between the forward port bore surface 440 and the rearward port bore surface 442. The forward port bore 435 has a first diameter, the rearward port bore 438 has a second diameter. In one or more embodiments, the second diameter is greater than the first diameter. The forward port bore surface 440 meets the port valve seat surface 448 at a port edge 444. A port valve member 430 is disposed in the port regulator cavity 422. A seating surface of the port valve member 430 is biased to seat against the port edge 444 by a port spring 432. A port guide 434 extends through a lumen defined by the port spring 432 and into a port valve member pocket 452 defined by the port valve member 430.
The forward port bore 435 of the port regulator cavity 422 fluidly communicates with the barrel bore 22 via a port passageway 454 defined by the gas block 220 and a port hole 52 defined by the barrel 20. The forward port bore 435 of the port regulator cavity 422 fluidly communicates with the annular volume 264 via a port aperture 450. Upon firing a shell with the shotgun, combustion gasses within the barrel 20 enter the annular volume via the port hole 52 and the port hole 52 to move the sleeve 252 and a slider 150 rearward for cycling a mechanism 36 disposed in the receiver interior 34.
In embodiments, the semiautomatic shotgun operates as follows. Cartridges of different power levels may be fired without adjusting of modifying the shotgun. Shotshells are loaded conventionally in the magazine. A shell is chambered by retracting the breech block. Upon firing the shell in the chamber explosive gases pass through the two ports in the barrel into the gas block assembly. A pair of passageway extends to the pair of valve chambers and then to the piston chamber. The passage ways to the piston chamber are selected to be a suitable size to restrict the passage of the gas that is to cause a pressure drop. If the pressure in the valve chambers is above a certain predetermined level, the relief valves open to lower the pressure lever. The valves open by the valve members lifting off of their respective valve seats. The pressure level transferred to the piston is then suitable for reliable and long-lasting operation of the recycling mechanism.
In embodiments the piston and piston chamber may be differently configured and still have the advantageous dual regulator arrangement. For example the piston could be cylindrical and engage a tubular cylinder forward of the ammunition chamber or above the ammunition chamber.
In one or more embodiments, the semiautomatic firearm 10 includes a spring 66 that is disposed inside a space defined by the magazine tube. In one or more embodiments, the semiautomatic firearm 10 includes a flange part 62.
Referring to
The fore stock 632 of
The annular piston 642 returns to the full-in position in the gas block when the action arm assembly returns to the forward normal in-battery position, such as show in, for example,
Details of the action bar assembly 620 engaged with the gas operating assembly are illustrated in
Referring to
Referring to
Referring to
“Non-removably attached”, “nonremovable”, and “not dissassembleable by the user” when used herein means secured by welding, or can mean secured with high strength thread lock such that extraordinary means such as heating with a torch is necessary for removal without damage to the components. When used herein a retail sale assemblage means a packaged assembly of firearm components mass produced for retail sale and includes manuals and packaging and typically includes a lock for the firearm. Additionally it may contain a case that includes all components and written material such as manuals/instructions/warnings.
Referring, for example, to
The following United States patents are hereby incorporated by reference herein: U.S. Pat. Nos. 4,601,122, 4,702,146, 4,856,217, 4,872,392, 4,901,623, 5,429,034, 5,867,928, 5,872,323, 5,918,401, 5,959,234, 6,347,569, 6,382,073, 6,470,614, 6,508,160, 6,564,691, 6,619,592, 7,467,581, 7,775,149, 7,946,214, 7,963,061, 8,056,280, 8,065,949, 8,079,168, 8,109,194, 8,230,632, 8,245,625, 8,250,964, 8,312,656, 8,443,712, 8,528,458, 8,850,731, 8,939,060, 9,097,475, 9,212,856, and 9,383,149.
The above references in all sections of this application are herein incorporated by references in their entirety for all purposes. Components illustrated in such patents may be utilized with embodiments herein. Incorporation by reference is discussed, for example, in MPEP section 2163.07(B).
All of the features disclosed in this specification (including the references incorporated by reference, including any accompanying claims, abstract and drawings), and/or all of the steps of any method or process so disclosed, may be combined in any combination, except combinations where at least some of such features and/or steps are mutually exclusive.
Each feature disclosed in this specification (including references incorporated by reference, any accompanying claims, abstract and drawings) may be replaced by alternative features serving the same, equivalent or similar purpose, unless expressly stated otherwise. Thus, unless expressly stated otherwise, each feature disclosed is one example only of a generic series of equivalent or similar features.
The invention is not restricted to the details of the foregoing embodiment(s). The invention extends to any novel one, or any novel combination, of the features disclosed in this specification (including any incorporated by reference references, any accompanying claims, abstract and drawings), or to any novel one, or any novel combination, of the steps of any method or process so disclosed The above references in all sections of this application are herein incorporated by references in their entirety for all purposes.
Although specific examples have been illustrated and described herein, it will be appreciated by those of ordinary skill in the art that any arrangement calculated to achieve the same purpose could be substituted for the specific examples shown. This application is intended to cover adaptations or variations of the present subject matter. Therefore, it is intended that the invention be defined by the attached claims and their legal equivalents, as well as the following illustrative aspects. The above described aspects embodiments of the invention are merely descriptive of its principles and are not to be considered limiting. Further modifications of the invention herein disclosed will occur to those skilled in the respective arts and all such modifications are deemed to be within the scope of the invention.
This application claims priority to U.S. Provisional Application No. 63/132,791 filed on Dec. 31, 2021, and is a continuation-in-part to U.S. patent application Ser. No. 17/361,573 filed on Jun. 29, 2021, which is a continuation-in-part of U.S. patent application Ser. No. 16/506,646, filed Jul. 9, 2019, now U.S. Pat. No. 11,047,635, which is a continuation of U.S. patent application Ser. No. 15/847,822, filed Dec. 19, 2017, now U.S. Pat. No. 10,345,062, which claims the benefit of U.S. Provisional Application No. 62/436,346, filed on Dec. 19, 2016, the disclosures of which are incorporated by reference herein in their entireties.
Number | Date | Country | |
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63132791 | Dec 2020 | US | |
62436346 | Dec 2016 | US |
Number | Date | Country | |
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Parent | 15847822 | Dec 2017 | US |
Child | 16506646 | US |
Number | Date | Country | |
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Parent | 17361573 | Jun 2021 | US |
Child | 17567008 | US | |
Parent | 16506646 | Jul 2019 | US |
Child | 17361573 | US |