This disclosure relates to air guns, and more particularly to structures for aligning the barrel of a break barrel air rifle.
Air guns are small arms, such as air pistols or rifles, that are commonly used for hunting, recreational shooting, and competitive shooting, such as field target events. Unlike firearms that fire projectiles using chemical or explosive reactions, air guns utilize pressurized air or gas to propel projectiles (e.g., pellets or small balls called “BBs”). For instance, air guns, such as spring-piston air guns, use a mechanical means (e.g., a spring and piston) to compress air within a cylinder. One type of spring-piston air gun is a break barrel air rifle in which the rifle is hinged near its midpoint. The barrel serves as a lever that is operated by the user about the hinge to compress the spring. Upon firing, the spring is released and the air in the compression cylinder is quickly compressed. This compressed air is channeled to the breech and causes the projectile to be propelled from the barrel of the air gun.
One example embodiment of the present disclosure provides a break barrel air gun comprising a barrel block attached to a barrel, the barrel block having two opposed substantially vertical sides, each side including a wedge extending laterally outwardly, and a compression fork pivotally attached to the barrel block, the compression fork including two inclined shelves each having upper surfaces configured to contact lower surfaces of the wedges when the air gun is in a closed configuration. The lower surfaces of the wedges can extend laterally at an angle between 90° and 180° and can be greater than 110° from the vertical sides of the barrel block. The lower surfaces of the wedges and the upper surfaces of the inclined shelves can be planar. The surface area of a wedge that is in contact with an inclined shelf can be greater than 0.25 cm2 and the length of the wedge can be greater than 10 mm. The wedges can be formed on the upper surface of the barrel block and may be integral with the barrel block. The compression fork may be attached to a compression tube so that the compression tube, compression fork, barrel block, and barrel may be in fluid communication with one another. The interaction between the wedges and the inclined shelves can provide horizontal and vertical forces to keep the barrel aligned with the compression tube when the air gun is in the ready to fire position. The wedges can be in contact with the inclined shelves to maintain at least one of horizontal alignment and vertical alignment of the barrel with the compression tube when the air gun is in a ready to fire position. The air gun may further comprise a stock connected to the compression fork and a scope mounted on the compression tube. The wedges can include a triangular cross-sectional shape. The wedges can be one of a continuous plane or a plurality of interrupted co-planar segments. The lower surfaces of the wedges can be curved surfaces configured to contact upper curved surfaces of the inclined shelves. The wedges may include a length to width ratio of greater than 2:1. The barrel block can further include a detent configured to maintain the wedges of the barrel block in contact with the inclined shelves of the compression fork. The compression fork can include a pair of arms on which the inclined shelves are disposed, the inclined shelves extending downwardly toward an inside surface of each arm.
One example embodiment of a method of making the air guns disclosed herein includes joining the barrel block to the compression fork so that the wedges disposed on the barrel block are in contact with inclined shelves disposed on the compression fork, match drilling a pivot pin hole through the compression fork and barrel block, and pivotally securing the compression fork to the barrel block by passing a pivot pin through the pivot pin hole. The method may further comprise pressing the breech face of the barrel block against the corresponding face of the compression fork prior to drilling. The barrel block can be joined with the compression fork so that the barrel block and compression fork are placed together in a firing mode configuration.
The features and advantages described herein are not all-inclusive and, in particular, many additional features and advantages will be apparent to one of ordinary skill in the art in view of the drawings, specification, and claims. Moreover, it should be noted that the language used in the specification has been selected principally for readability and instructional purposes and not to limit the scope of the inventive subject matter.
These and other features of the present embodiments will be understood better by reading the following detailed description, taken together with the figures herein described. The accompanying drawings are not intended to be drawn to scale. For purposes of clarity, not every component may be labeled in every drawing.
In one aspect, a system is described that allows a break barrel air rifle to provide precise and repeatable barrel positioning before each shot. The barrel block of the break barrel air rifle can include two angled wedges that are laterally mounted on opposed vertical surfaces of the barrel block. These wedges provide angled planar surfaces that contact complementary receiving surfaces on the body of the air gun, such as on the compression fork. The wedges can provide flat surfaces that may be neither parallel nor perpendicular to the vertical axis of the air gun. These angled surfaces can reduce unwanted barrel movement in both the horizontal and vertical directions.
To cock and load a break barrel air gun, the barrel of the gun is broken from the air gun body and serves as a lever to provide mechanical advantage for compressing the spring. When the barrel is fully broken, the breech is exposed and a pellet or other projectile can be loaded into the breech. The barrel is then closed and the air gun is ready to shoot. This process is repeated for every shot and the repeatability of the alignment of the barrel in relation to the body of the air gun between shots is important for accurate shooting as even a slight variation in barrel alignment leads to significant inaccuracies. While iron sights can be mounted on the gun barrel, sights such as telescopic sights and laser sights are typically mounted on the body of the air gun, such as on the compression tube. This means that for consistent, accurate shooting, the alignment of the barrel to the compression tube needs to be the same as when the gun was sighted in.
Horizontal deviation of the barrel (side to side) is typically controlled by the insertion of shims or spring washers at the barrel pivot pin between the barrel block and the fork that extends from the compression tube. Manufacturing tolerances dictate that there is a range of clearance distances between the barrel block and the fork, and the width of the barrel block is typically smaller than the width of the opening in the fork by at least a few thousandths of an inch. This amount of clearance is enough to allow for some side to side movement of the barrel, even with the pivot pin installed. The use of one or more shims can reduce this clearance and as a result, reduces the amount of side to side play. Shims or spring washers however can increase the friction between the barrel block and the fork, resulting in a more difficult cocking procedure. The shims also wear over time, resulting in an increasing amount of play as the number of shooting cycles increases.
Vertical alignment of the barrel is typically defined by the point where the rearward facing surface of the barrel block is stopped by the complementary surface on the interior of the fork. In theory, this involves broad surface to surface contact but in practice, again due primarily to manufacturing tolerances, typically results in one or two points of contact between the surfaces. At these points of contact, surface wear results from each cycle of the air gun and the vertical alignment of the barrel is altered, resulting in an increasing amount of error between the expected and the actual vertical alignment of the barrel in relation to the compression tube.
General Overview
Wedges 144A and 144B interact with compression fork 160 to fix and stabilize the alignment of the barrel 110. Different views of compression fork 160 are provided in
Example Air Gun Application
Manufacturing Process
Barrel block 140 and compression fork 160 are pivotally connected using barrel pivot pin 172 along with any associated bushings to reduce wear and friction. To receive the barrel pivot pin 172, holes are drilled through both compression fork 160 and barrel block 140. Traditionally, the barrel block 140 and compression fork 160 are drilled separately with hole tolerances designed to allow for variations in part dimensions. Shims, which must be selected individually for each air gun, have been used help to eliminate side to side movement by reducing or eliminating and space between the fork 160 and barrel block 140 at the pivot point.
In one set of embodiments, the compression fork 160 and barrel block 140 are match drilled at the same time. Prior to any hole being drilled for the barrel pivot pin 172, the barrel block 140 and compression fork 160 are placed together in the firing mode configuration. Lower surfaces 150 of wedges 144A and 144B are in full contact with inclined shelves 244A and 244B of compression fork 160. At the same time, barrel block 140 is pushed into compression fork 160 so that the two surfaces are in contact, or close to contact, and are in an optimal configuration for firing. This position is the preferred position for the barrel block 140 in relation to the compression fork 160 and the barrel pivot pin 172 is used to fix them in position. With the wedges 144 and shelves 244 in contact, and the rear surface of barrel block 140 in contact (or close) with rear wall 250 of compression fork 160, the components are clamped together and the barrel pivot pin hole is match drilled through both the fork 160 and barrel block 140 in a single step. The hole is drilled in the barrel block 140 at region 152 which protrudes several thousandths of an inch to provide clearance between the barrel block 140 and the compression fork 160 when the barrel 110 is pivoted. Match drilling removes the need for the tolerances in the pivot pin holes that would normally be required when the fork 160 and barrel block 140 are drilled separately. This process also eliminates the needs for shims between the compression fork 160 and barrel block 140 because the horizontal support provided by the wedge/shelf interface means that the barrel block 140 and compression fork 160 do not need to rub against each other at the pivot point. Any lateral sliding or rotation is prevented by the interaction of the wedges 144 and shelves 244. Vertical play is also decreased because the barrel pivot pin 172 and bushing fit precisely into the pivot pin hole, effectively eliminating any vertical movement at that point. Friction and wear between the outer surfaces of the barrel block 140 and the inner surfaces of the compression fork 160 are reduced or eliminated because they no longer need to be in contact to provide steady positioning of the barrel 110. This reduction in wear results in greater accuracy and less frequent adjustment of sighting devices.
The foregoing description of the embodiments of the present disclosure has been presented for the purposes of illustration and description. It is not intended to be exhaustive or to limit the present disclosure to the precise form disclosed. Many modifications and variations are possible in light of this disclosure. It is intended that the scope of the present disclosure be limited not by this detailed description, but rather by the claims appended hereto.
This application claims the benefit of U.S. Provisional Patent Application No. 62/466,187, filed on Mar. 2, 2017, which is herein incorporated by reference in its entirety.
Number | Date | Country | |
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62466187 | Mar 2017 | US |