Not applicable.
Not applicable.
The present disclosure relates to arrow guns and particularly to arrow guns using compressed gas to propel the arrow, wherein a retention force on the arrow can be adjusted to increase imparted energy from the compressed gas to the arrow. The present disclosure further relates to reducing vibration of an unsupported length of a barrel, wherein the barrel receives compressed gas to act on the arrow.
Compressed gas has been used to propel BBs from a gun for many years. However, the ability to propel an arrow, such as a standard length arrow from a gun by compressed gas has not been well developed. Thus, there exists a need for an improved compressed gas gun capable of projecting an arrow.
The need also exists for a compressed gas gun able to exert a more instantaneous pressure front upon an arrow being propelled to increase the amount of energy imparted to the arrow being propelled.
The present disclosure provides an apparatus for increasing the maximum pressure of compressed gas acting on the arrow.
Propelling an arrow is complicated because the compressed gas must expand and travel through the barrel to contact the arrow, thus a gradually increasing pressure front is exerted upon the arrow. This gradually increasing pressure front causes the arrow to begin moving from the barrel before the maximum pressure exertable by the compressed gas has a chance to act upon the arrow. This gradual increase in pressure significantly reduces the amount of energy able to be transferred to the arrow as the arrow is propelled along the length of the barrel. The reduced pressure results in a significant reduction in muzzle velocities and kinetic energy transferred to the arrow.
The present disclosure provides for a controllable or adjustable retention force on the arrow so that motion of the arrow relative to the barrel is limited during at least a portion of the gradually increasing pressure front of the compressed gas. By increasing the retention force on the arrow, a higher pressure of the compressed gas can act on the arrow. In addition, the present disclosure provides repeatable retention force on the arrow, thus providing subsequent shots with consistent arrow velocity. The present disclosure further provides a damping of barrel vibration, thereby allowing for use of longer barrels and hence greater accuracy and arrow velocity.
In one configuration, an arrow gun using compressed gas to propel an arrow having a hollow portion is provided, wherein the arrow gun includes a receiver; an elongate barrel having a longitudinal axis, the barrel connected to the receiver at a fixed connection, the barrel having an outer diameter sized to be slidably received within the hollow portion of the arrow and terminating at a free end; a damping coupling between the receiver and the barrel, the damping coupling longitudinally spaced along the barrel from the fixed connection to be intermediate the fixed connection and the free end of the barrel; and wherein the barrel has an unsupported length of approximately 12 inches to 36 inches between the damping coupling and the free end.
In a further configuration, an arrow gun using compressed gas to propel an arrow having a hollow portion is provided, wherein the arrow gun includes a barrel sized to be received within the hollow portion of the arrow; a gripping surface having a first configuration exerting a first retention force on the arrow receiving the barrel within the hollow portion and a second configuration exerting a different second retention force on the arrow receiving the barrel within the hollow portion.
Referring to
The stock 40 can include or retain a reservoir 42 of compressed gas, as well as a trigger assembly and a gas valving system as known in the art. Representative reservoirs, trigger assemblies, and valving systems can operably retain compressed gas at a pressure of 2,000 psi to 7,000 psi, wherein the valving system presents the gas to the receiver 50 and hence the barrel 94 at approximately 500 psi to 5,000 psi.
The receiver 50 cooperatively connects the barrel 94 to the stock 40. As seen in
The coupling length 64 has a diameter substantially equal to the outer diameter of the barrel 94, to slideably receiving a length of the barrel. Referring to
The control length 74 defines an internal diameter greater than the diameter of the coupling length 64, wherein the diameter is sized to define a damping annulus 75 between an outer surface of the barrel and an inner surface of the control length.
The damping annulus 75 is sized to retain a damping coupling 78 between the outer surface of the barrel and the inner surface of the control length 74 of the barrel adapter 60. The damping coupling 78 can be a variety of materials selected to reduce vibration of the barrel relative to the barrel adapter 60, the receiver 50 and hence the stock 40. The damping coupling 78 can include resilient materials including elastomers, high durometer plastics as well as metals. The damping coupling 78 can include a plurality of O-rings, or be in the form of a sleeve, or a bushing. Thus, the damping coupling 78 can include a compression ring, an O-ring, elastomers, high durometer plastics, such as well as metals, and can have configurations including a plurality of O-rings, or be in the form of a sleeve, or a bushing. As seen in
In one aspect, the damping coupling 78 is located at a vibrational anti-node of the barrel 94. Thus, depending on the intended length of the barrel 94, the barrel adapter 60 can be configured to locate the damping coupling 78 at the actual or anticipated anti-node, thereby increasing the amount of vibrational energy that is removed from the barrel 94.
An open end of the receiving recess 63 defines a seating groove 83 for receiving a gripping surface 84. The gripping surface 84 can include a compression ring, an O-ring, elastomers, high durometer plastics, as well as metals, and can have configurations including a plurality of O-rings, or be in the form of a sleeve, or a bushing.
An outside surface of the barrel adapter 60 includes a coupling 86 for selectively engaging a collar 90, wherein the collar can be moved longitudinally relative to the barrel adapter and hence the barrel receiving recess 63.
In one configuration, the coupling 86 on the outside surface of the barrel adapter 60 is a plurality of external threads and a corresponding coupling 92 on the collar 90 is a mating plurality of internal threads. Thus, rotation of the collar 90 relative to the barrel adapter 60 changes the longitudinal position of the collar relative to the barrel adapter.
In a first positioning of the collar 90 relative to the barrel adapter 60, the gripping surface 84 (such as the compression ring) projects into the receiving recess 63 a first amount, and in a second positioning of the collar relative to the barrel adapter, the gripping surface (such as the compression ring) projects into the receiving recess a different second amount.
Depending on the selected coupling between the collar 90 and the barrel adapter 60, the amount of force applied to the gripping surface 84 (such as the compression ring), and hence compression of the gripping surface (compression ring) and amount of the gripping surface (compression ring) projecting into the receiving recess 63 can be varied between at least two positions, and up to a multitude of positions, such as by different threaded engagements. The amount of the gripping surface 84 projecting into the receiving recess 63 determines the amount of the retention force on the arrow 20.
It is also contemplated that the gripping surface 84 can be in the form of a cam or inclined surface that varies its position in response to the positioning of the collar 90. That is, an increased or decreased portion of the cam or inclined surface can be located within the retaining recess.
The barrel adapter 60 also includes a gas passageway 67 fluidly connecting a source of compressed gas to the barrel.
The barrel 94 is elongate and sized to be slidably received within the arrow. In one configuration, the barrel extends along a longitudinal axis and has an outer diameter of approximately 0.25 to 0.5 inches. While a wall thickness of the barrel 94 can be partly determined by desired operating characteristics, a satisfactory barrel wall thickness has been found to include approximately 0.020 inches. The barrel 94 can be formed of a variety of materials including, but not limited to composites, laminates, plastics including elastomers and metal. A satisfactory material includes stainless steel or carbon fiber.
The barrel 94 includes a threaded outer surface 96 adjacent one end 95 of the barrel. The wall thickness of the barrel 94 is partly selected to accommodate the external threads 96 for engaging the barrel adapter 60. The remaining end of the barrel defines a muzzle at a free end 97 of the barrel.
The barrel 94 extends from the receiver 50, such as from the barrel adapter 60, to extend a free length of approximately 12 inches to 36 inches. That is, the barrel is unsupported for a length of approximately 12 inches to 36 inches. In certain configurations, the barrel length is between approximately 20 inches to 31 inches with one configuration having a barrel length of approximately 26 inches.
The term arrow 20 includes an elongate shaft 22 having an arrowhead such as a pointed or penetrating end. The arrow 20 typically includes fletching, however, it is understood the fletching is not required.
At least a portion of the shaft 22 of the arrow 20 is hollow and sized to slideably receive the barrel. As set forth above, for a barrel 94 having an outer diameter of approximately 0.354″, the inner diameter of the hollow shaft 22 is approximately 0.314″. The shaft 22 thus has an open end 23 at a rear end 26 of the arrow. The hollow length of the arrow 20 can be from approximately 25% to 95% of the overall length of the arrow.
The arrow 20 can have a variety of lengths from approximately 12 inches to approximately 36 inches. Depending on the construction of the arrow, the arrow 20 can have a weight from approximately 250 to approximately 450 grains.
Referring to
As seen in the
To reduce the required adjustments of the collar 90 relative to the barrel adapter 60, it has been found advantageous to form the bushing 30 from a relatively rigid material such as steel, aluminum or a rigid polymer.
Thus, an arrow 20 for the arrow gun 10 for propelling the arrow by a compressed gas is provided, wherein the arrow has an elongate hollow shaft 22 extending along a length of the arrow; and a bushing 30 coupled to the shaft to define a portion of the outside surface of the shaft along at least a portion of the length of the arrow, the bushing 30 having a greater wear resistance than an adjacent portion of the shaft. The bushing 30 can define an outer surface of the arrow, and in select configurations, define a maximum diameter of the shaft. That is, the bushing 30 has a diameter greater than a shaft diameter.
In construction, the external threads 96 of the barrel 90 are engaged with the internal threads 66 of the barrel adapter 60. This connection fixedly seats or connects the barrel 20 to the barrel adapter 60.
The damping coupling 78 is the located within the control length 64 of the receiving recess 63 to extend in the damping annulus 75 between the barrel adapter 60 and the outside surface of the barrel 20. As seen in
The gripping surface 84 is then located in the seating groove 83 and the collar 90 engaged with the barrel adapter 60. As the collar 90 is longitudinally displaced relative to the barrel adapter 60, the axial force on the gripping surface 84 is changed and hence the amount of the gripping surface that projects into the control length 74 of the receiving recess 63 is changed.
As the gripping surface 84 is the surface that contacts the arrow 20, such as on the bushing 30, to resist movement of the arrow relative to the barrel adapter 60, the amount of retention force on the arrow can be varied and controlled by controlling the retention force imparted by the gripping surface through the amount of the gripping surface projecting into the retaining recess, which is set by the compression on the gripping surface applied by the collar 90 and the barrel adapter 60.
In one configuration, the bushing 30 of the arrow 20 defines a reproducible diameter against which the gripping surface 84 contacts and thus in conjunction with the gripping surface provides a reproducible and consistent retention force on the arrow. Thus, for each arrow 20 charged on the barrel 94, the constant sizing of the outer diameter of the bushing 30 in combination with the preset retention force from the gripping surface 84, the performance of the propelled arrow is within 10% for multiple shots.
The adjustment of the collar 90 relative to the barrel adapter 60 can be set during the manufacture of the gun 10, or can be subsequently set or adjusted, depending on intended operation of the gun.
In one configuration, the arrow 20 is configured to slideably receive the barrel 94, the arrow has a relatively small diameter, typically less than 0.5 inches and depending upon the material of the shaft can be 5/16″, 11/32″, and 23/64″ for wooden shafts; 5/16″ for carbon shafts with many options in larger and smaller diameters; aluminum shafts typically having a diameter of approximately 11/32″, 21/64″, 5/16″ and 9/32″ and fiberglass shafts having a diameter in the range of 5/16″ or ¼″.
To accommodate these dimensions, the barrel 94 must by sized to be received with the longitudinal recess of the shaft 22. Thus, the barrel 20 has a smaller diameter which tends to increase vibration as the unsupported length increases. However, as the barrel length increases, the accuracy of the gun 10 increases. Therefore, it is desirable to increase the length of the barrel 20.
The damping coupling 78 is selected to inhibit vibration of the unsupported length of the barrel 20 relative to the barrel adapter 60. By reducing the vibration (movement of the barrel 20 relative to the barrel adapter 60), the accuracy of the gun can 10 be increased.
An advantage of the small bore barrel 20 is that compressed gas entering the barrel at the barrel adapter 60 acts on the arrow, sooner than the compressed gas would in a larger bore barrel.
The arrow weight, retention force from the gripping surface (via the coupler) and pressure of the compressed gas (motive gas pressure) are selected to provide a 350 grain arrow with a velocity of approximately 450 feet per second (fps) to 500 fps.
While the invention has been described in connection with several presently preferred embodiments thereof, those skilled in the art will appreciate that many modifications and changes may be made without departing from the true spirit and scope of the invention which accordingly is intended to be defined solely by the appended claims.
Number | Date | Country | |
---|---|---|---|
Parent | 15943040 | Apr 2018 | US |
Child | 16565211 | US | |
Parent | 14801047 | Jul 2015 | US |
Child | 15943040 | US |