The present invention generally relates to air guns, and more specifically to a gas spring assembly for an air gun.
An air gun is a rifle, pistol, etc., which utilizes a compressed gas to fire a projectile. Air guns may be powered by, for example, a coil spring loaded piston or an air-spring loaded piston.
Air guns powered by the coil spring loaded piston include a common trigger assembly, a coil spring assembly housed within a compression chamber of the rifle, and a barrel. The coil spring assembly includes a coil spring coupled to a piston. Cocking the gun moves the piston, which compresses the coil spring until a latch on the rear of the piston engages a sear on the trigger assembly. The coil spring assembly permits use of a center, i.e., an in-line latch, wherein the latch on the rear of the piston is generally in-line and concentric with a longitudinal axis of the piston. Actuating the trigger assembly releases the sear of the trigger assembly and allows the coil spring to decompress, pushing the piston forward, and thereby compressing the gas, i.e., air, in the compression chamber directly behind the projectile. Once the air pressure rises to a level sufficient to overcome any static friction and/or barrel restriction between the projectile and the barrel, the projectile moves forward within the barrel, propelled by an expanding column of gas.
The air-spring loaded piston includes a sealed compression cylinder disposed within the piston. The compression cylinder contains a gas, such as air or nitrogen. Cocking the gun moves the piston, which compresses the gas within the compression cylinder until the latch on the rear of the piston engages a sear on the trigger assembly. If the compression cylinder includes a single dynamic compression seal, i.e., if the compression cylinder includes only a single moving seal to contain the pressurized gas within the compression cylinder, then the trigger assembly must engage the piston at an outer surface thereof. In order to use the center, i.e., in-line latch generally associated with the coil spring loaded piston assembly described above, then a double dynamic seal compression cylinder may be utilized, i.e., the compression cylinder includes a center rod for engaging the center latch, and two moving seals to seal the compression cylinder against both the piston and the center rod.
An air gun is provided. The air gun includes a trigger assembly. The trigger assembly is moveable between a cocked position and an uncocked position. The air gun further includes a gas spring assembly. The gas spring assembly includes a compression cylinder and a piston. The piston is slideably disposed over and moveable along a longitudinal axis relative to the compression cylinder. The piston is moveable between a compressed position and an uncompressed position. The gas spring assembly is configured for compressing a gas within the compression cylinder in response to movement of the piston from the uncompressed position into the compressed position. Compressing the gas within the compression cylinder loads the gas spring assembly in preparation for firing a projectile when actuated by the trigger assembly. The air gun further includes a latch assembly. The latch assembly is moveable along the longitudinal axis relative to the trigger assembly and the gas spring assembly. The latch assembly includes a first end and a second end spaced from the first end along the longitudinal axis. The first end is releasably coupled to the trigger assembly when the trigger assembly is in the cocked position. The first end is de-coupled from the trigger assembly when the trigger assembly is in the uncocked position. The second end is releasably coupled to the piston of the gas spring assembly when the piston is in the compressed position. The second end is de-coupled from the piston of the gas spring assembly when the piston is in the uncompressed position.
A gas spring assembly for an air gun is also provided. The gas spring assembly includes a compression cylinder extending along a longitudinal axis, and a piston slideably disposed over and moveable along the longitudinal axis relative to the compression cylinder. The piston is moveable between a compressed position and an uncompressed position. The compression cylinder and the piston are configured for compressing a gas within the compression cylinder in response to movement of the piston from the uncompressed position into the compressed position. The gas spring assembly further includes a latch assembly. The latch assembly includes a barrel portion concentric with the longitudinal axis. The latch assembly is moveable along the longitudinal axis relative to the compression cylinder and the piston. The latch assembly includes a first end and a second end spaced from the first end along the longitudinal axis. The second end is releasably coupled to the piston when the piston is in the compressed position. The second end is de-coupled from the piston when the piston is in the uncompressed position. The latch assembly includes a locking portion disposed adjacent the second end of the latch assembly. The piston includes a receiving end defining an aperture and an interior surface defining a recess adjacent the receiving end. The receiving end is configured for receiving the locking portion therethrough. The recess configured for mechanically interlocking with the locking portion of the latch assembly when the piston is in the compressed position.
Accordingly, the latch assembly couples and/or interconnects the gas spring assembly and the trigger assembly, and permits the gas spring assembly to utilize a single dynamic seal gas spring along with an in-line or center latch system commonly utilized in existing air guns. The single dynamic gas spring in combination with the center latch is a more powerful and/or accurate combination than the double dynamic gas spring/center latch combination or the single dynamic gas spring/side latch combination utilized in the prior art gas spring powered air guns.
The above features and advantages and other features and advantages of the present invention are readily apparent from the following detailed description of the best modes for carrying out the invention when taken in connection with the accompanying drawings.
Referring to the Figures, wherein like numerals indicate corresponding parts throughout the several views, an air gun is shown generally at 20. The air gun 20 includes a stock 22, a trigger assembly 24, a latch assembly 26, a gas spring assembly 28 and a barrel 30. The air gun 20 utilizes a burst of compressed air to fire a projectile. Throughout
Referring to
Actuation of the trigger assembly 24 releases the gas spring assembly 28, which allows the gas spring assembly 28 to decompress. Decompression of the gas spring assembly 28 compresses the air contained within the pressure chamber 32, which fires the projectile.
The stock 22 may include any suitable size and/or shape, and may be configured as a rifle or a pistol. The stock 22 may include and be manufactured from any suitable material, such as a wood material, a plastic material, a composite material, or some other material capable of supporting the components of the air gun 20 during use, while permitting easy manufacture of the stock 22.
The trigger assembly 24 is housed within and supported by the stock 22. As noted above, the trigger assembly 24 is moveable between the cocked position and the uncocked position. The cocked position is generally associated with a ready to fire position, and the uncocked position is generally associated with a post firing, i.e., not-ready to fire position. The trigger assembly 24 may include any trigger assembly 24 commonly known and utilized to fire a weapon. Typically, the trigger assembly 24 includes a trigger 38, which operates a sear 40 through a mechanical connection. However, it should be appreciated that the trigger assembly 24 may be configured in some other manner.
The gas spring assembly includes a compression cylinder 42 and a piston 44. The piston 44 is slideably disposed over and moveable along a longitudinal axis 46 relative to the compression cylinder 42. The longitudinal axis 46 is concentric with the piston 44. As noted above, the piston 44 is moveable between the compressed position and the uncompressed position. The gas spring assembly is configured for compressing a gas within the compression cylinder 42 in response to movement of the piston 44 from the uncompressed position into the compressed position. Compression of the gas loads the gas spring assembly in preparation for firing a projectile when actuated by the trigger assembly 24.
As shown in
The stabilizing element 48 may include a carbide rod or the like extending along the longitudinal axis 46 within the compression cylinder 42. It should be appreciated that the stabilizing element 48 may include some other material and be configured in some other manner capable of reducing vibration in the air gun 20 when fired, other than shown or described herein.
The gas spring assembly 28 may include a single dynamic gas spring assembly, in which the gas spring assembly 28 includes only one dynamic seal to seal the gas within the compression cylinder 42, or may alternatively include a double dynamic gas spring, in which the gas spring includes two dynamic seals to seal the gas within the compression cylinder 42. It should be appreciated that the gas spring assembly may, but not necessarily, include other components, that are not described in detail herein, depending on the type of gas spring utilized.
Referring to
Movement of the piston 44 from the uncompressed position into the compressed position releasably couples the first end 50 of the latch assembly 26 and the trigger assembly 24, and further releasably couples the second end 52 of the latch assembly 26 and the piston 44. Actuation of the trigger assembly 24 from the cocked position to the uncocked position de-couples the trigger assembly 24 from the latch assembly 26 and de-couples the latch assembly 26 from the piston 44. De-coupling the trigger assembly 24 from the latch assembly 26, and de-coupling the latch assembly 26 from the piston 44 permits the compressed air within the compression cylinder 42 to decompress the gas spring assembly 28, which moves the piston 44 along the longitudinal axis 46, thereby compressing the air within the compression chamber, which in turn propels the projectile out of the barrel 30.
Referring to
The interior surface 54 of the piston 44 defines a recess 60 adjacent the receiving end 56 of the piston 44. The recess 60 is configured for mechanically interlocking with the locking portion 58 of the latch assembly 26 when the piston 44 is in the compressed position. The mechanical interlocking engagement between the recess 60 and the locking portion 58 of the latch assembly 26 couples the latch assembly 26 and the piston 44.
The recess 60 includes a first edge 62 and a second edge 64. The second edge 64 is spaced from the first edge 62 along the longitudinal axis 46. The first edge 62 is disposed nearer the latch assembly 26 than the second edge 64. The first edge 62 defines a first diameter 66, and the second edge 64 defines a second diameter 68 less than the first diameter 66 of the first edge 62.
The trigger assembly 24 defines a bore 70. The bore 70 is generally concentric with and extends along the longitudinal axis 46. The latch assembly 26 is at least partially disposed within the bore 70 in-line with the gas spring assembly, along the longitudinal axis 46. Referring also to
The locking portion 58 of the latch assembly 26 includes an expandable member 76. The expandable member 76 is supported on a radially outer surface of the locking portion 58 of the latch assembly 26, i.e., on a radially outer surface of the pair of posts 74. The radially outer surface may include a concave surface or the like for supporting the expandable member 76. The expandable member 76 is configured for expanding radially outward away from the longitudinal axis 46 into interlocking engagement with the recess 60 of the piston 44. The expandable member 76 expands radially outward in response to axial movement of the piston 44 along the longitudinal axis 46 from the uncompressed position into the compressed position. Accordingly, movement of the piston 44 causes the expandable member 76 to expand radially outward and engage the recess 60 of the piston 44, which thereby couples the latch assembly 26 and the piston 44 together. As best shown in
One of the latch assembly 26 and the piston 44 includes a wedge surface 78. The wedge surface 78 is configured for directing the expandable member 76 radially outward, into engagement with the recess 60 of the piston 44. Axial movement of the piston 44 moves the expandable member 76 up the wedge surface 78, which causes the expandable member 76 to expand radially outward away from the longitudinal axis 46.
As shown, the latch assembly 26 includes a bushing 80. The bushing 80 defines the wedge surface. The bushing 80 is concentric with and slideably disposed over the barrel portion 72 of the latch assembly 26. Movement of the piston 44 along the longitudinal axis 46 from the uncompressed position into the compressed position moves the expandable member 76 along the longitudinal axis 46 and across the wedge surface to expand the expandable member 76 into the recess 60.
The bushing 80 includes a frustoconical outer surface, which defines the wedge surface 78. The expandable member 76 is at least partially disposed radially outside the frustoconical outer surface relative to the longitudinal axis 46. The bushing 80 defines a slot 82, through which the pair of posts 74 of the locking portion 58 extends radially outward from the longitudinal axis 46. The pair of posts 74 of the locking portion 58 are moveable within the slot 82 along the longitudinal axis 46, to permit the expandable member 76 to move along the wedge surface 78 of the bushing 80.
In operation, as the piston 44 moves from the uncompressed position into the compressed position, the first edge 62 of the recess 60 passes over the expandable member 76 disposed over the wedge surface of the busing. The piston 44 continues to pass over the expandable member 76 until the second edge 64 of the recess 60 contacts the expandable member 76. The second edge 64 of the recess 60 engages the expandable member 76 and moves the latch assembly 26, including the barrel portion 72, the locking portion 58 and the expandable member 76, along the longitudinal axis 46 and up the wedge surface 78 of the bushing 80. As the expandable member 76 moves up the wedge surface 78 of the bushing 80, the expandable member 76 expands radially outward into the recess 60. Additionally, movement of the barrel portion 72 along the longitudinal axis 46 engages the sear 40 on the trigger assembly 24, causing the trigger assembly 24 to move from the uncocked position into the cocked position with the sear 40 of the trigger assembly 24 coupled to the barrel portion 72 of the latch assembly 26. Once the expandable member 76 expands to a diameter greater than the interior diameter of the first edge 62 of the recess 60, the latch assembly 26 and the piston 44 are coupled together. Accordingly, the sear 40 on the trigger assembly 24 prevents the movement of the latch assembly 26, and the latch assembly 26 prevents movement of the piston 44. Once the trigger assembly 24 is actuated, the latch assembly 26 moves along the longitudinal axis 46 toward the gas spring assembly 28, which permits the expandable member 76 to move down the wedge surface of the bushing 80 and contract radially inward toward the longitudinal axis 46. Once the expandable member 76 is contracted to a diameter less than the interior diameter of the first edge 62 of the recess 60, the piston 44 de-couples from the latch assembly 26 and rapidly moves along the longitudinal axis 46 to compress the air within the compression chamber.
Referring to
In operation, as the piston 44 moves from the uncompressed position into the compressed position, the first edge 62 of the recess 60 passes over the expandable member 92, i.e., the annular outer portion 100 of the e-shaped spring clip, which is disposed over the wedge surface 90 of the bushing 88. The piston 44 continues to pass over the expandable member 92 until the second edge 64 of the recess 60 contacts the expandable member 92. The second edge 64 of the recess 60 engages the expandable member 92 and moves the latch assembly 84, including the barrel portion 86, and the expandable member 92, along the longitudinal axis and up the wedge surface 90 of the bushing 88. As the expandable member 92 moves up the wedge surface 90 of the bushing 88, the annular outer portion 100 of the expandable member 92 expands radially outward into the recess 60. Additionally, movement of the barrel portion 86 along the longitudinal axis engages the sear 40 on the trigger assembly 24, causing the trigger assembly 24 to move from the uncocked position into the cocked position with the sear 40 of the trigger assembly 24 coupled to the barrel portion 86 of the latch assembly 84. Once the expandable member 92 expands to a diameter greater than the first diameter 66 of the first edge 62 of the recess 60, the latch assembly 84 and the piston 44 are coupled together. Accordingly, the sear 40 of the trigger assembly 24 prevents the movement of the latch assembly 84, and the latch assembly 84 prevents movement of the piston 44. Once the trigger assembly 24 is actuated, the latch assembly 84 moves along the longitudinal axis toward the gas spring assembly 28, which permits the expandable member 92 to move down the wedge surface 90 of the bushing 88 and contract radially inward toward the longitudinal axis. Once the expandable member 92 is contracted to a diameter less than the first diameter 66 of the first edge 62 of the recess 60, the piston 44 de-couples from the latch assembly 84 and rapidly moves along the longitudinal axis to compress the air within the compression chamber.
Referring to
The third alternative embodiment of the latch assembly 102 includes an expandable member 104. The expandable member 104 includes an annular C-shaped spring clip disposed about the bushing 88. The third alternative embodiment of the latch assembly 102 further includes a pin 106 extending through the elongated cross slot 96 of the bushing 88 and into interlocking engagement with the cross bore 94 of the barrel portion 86. The annular C-shaped spring clip is disposed between the trigger assembly 24 and the pin 106, with the pin 106 extending outside the outer surface of the bushing 88 to abut and engage the annular C-shaped spring clip. Accordingly, the pin 106 prevents the annular C-shaped spring clip from sliding down and off the wedge surface of the bushing 88, as well as pushes against the annular C-shaped spring clip to ensure that the barrel portion 86 moves with the annular C-shaped spring clip in response to the movement of the piston from the uncompressed position into the compressed position.
Referring to
The compression cylinder 110 of the second alternative embodiment of the gas spring assembly 108 defines a wedge surface 112. The wedge surface 112 is configured for directing the expandable member 76 radially outward, into engagement with the recess 60 of the piston 44. Axial movement of the piston 44 moves the expandable member 76 up the wedge surface 112, which causes the expandable member 76 to expand radially outward away from the longitudinal axis.
The compression cylinder 110 includes a frustoconically shaped end portion 114, which defines the wedge surface 112. The expandable member 76 is at least partially disposed radially outside the frustoconical end portion 114 relative to the longitudinal axis. The frustoconically shaped end portion 114 of the compression cylinder 110 defines a compression cylinder slot, through which the pair of posts 74 of the locking portion 58 extends radially outward from the longitudinal axis. The pair of posts 74 of the locking portion 58 are moveable within the compression cylinder slot along the longitudinal axis, to permit the expandable member 76 to move along the wedge surface 112 of the bushing 80.
Additionally,
Referring to
Referring to
The urethane spring includes a durometer providing a spring ratio greater than a force required to compress the gas spring assembly 28. Accordingly, the durometer of the urethane spring 142 may vary depending upon the power of the gas spring assembly 28. The urethane spring may include a metal ring 148 disposed within the annular lip 146 portion of the urethane spring 142 to stiffen the annular lip 146 portion.
In operation, the first edge 62 of the recess 60 passes over the annular lip 146 until the annular lip 146 contacts and engages the second edge 64 of the recess 60. Continued movement of the piston 44 compresses the urethane spring, causing the annular lip 146 of the urethane spring 142 to bulge outward until an outer diameter 150 of the annular lip 146 is greater than the first diameter 66 of the first edge 62, thereby coupling the urethane bushing to the piston 44.
Referring to
The compression cylinder 156 includes a peg 160 extending along the longitudinal axis toward the latch assembly 152. The peg 160 includes a shaft portion 162 extending to a distal bulbous portion 164. The shaft portion 162 defines a shaft thickness 166 and the bulbous portion 164 defines an end thickness 168. The end thickness 168 of the bulbous portion 164 is greater than the shaft thickness 166 of the shaft portion 162.
As shown in
The sixth alternative embodiment of the latch assembly 152 includes a barrel portion 170 and a locking portion 172. The barrel portion 170 includes a first arm portion 174 and a second arm portion 176. The first arm portion 174 and the second arm portion 176 define a barrel slot 178 therebetween extending along the longitudinal axis. The barrel slot 178 is disposed between the first arm portion 174 and the second arm portion 176. The locking portion 172 includes a first post 180 and a second post 182 with the first post 180 extending radially outward from the first arm portion 174 away from the longitudinal axis and the second post 182 extending radially outward from the second arm portion 176 away form the longitudinal axis and away form the first post 180.
The barrel slot 178 includes a first section 184 defining a first width 186 and a second section 188 defining a second width 190. The second width 190 of the slot is larger than the first width 186 of the slot. The bulbous portion 164 of the peg 160 is disposed within the second width 190 of the slot when the piston 44 is in the uncompressed position. Movement of the piston 44 from the uncompressed position into the compressed position moves the latch assembly 152 along the longitudinal axis, which causes the bulbous portion 164 to move within the slot. More specifically, the bulbous portion 164 moves into the first width 186 of the barrel slot 178 as the piston 44 moves the barrel portion 170 and the locking portion 172 of the latch assembly 152 along the longitudinal axis. As the bulbous portion 164 moves into the first width 186 of the barrel slot 178, the bulbous portion 164 wedges the first arm portion 174 and the second arm portion 176 radially outward away from each other until the first arm portion 174 and the second arm portion 176 define a distance therebetween that is greater than the interior diameter of the first edge 62 of the recess 60. Once the distance between the first arm portion 174 and the second arm portion 176 is greater than the first diameter 66 of the first edge 62 of the recess 60, the latch assembly 152 and the gas spring assembly 154 are coupled together.
While the best modes for carrying out the invention have been described in detail, those familiar with the art to which this invention relates will recognize various alternative designs and embodiments for practicing the invention within the scope of the appended claims.