This invention relates in general to firearms, in particular bolt action rifles having interchangeable barrels, and more particularly to a recoil lug designed to allow the user of the firearm to change barrels under field conditions with repeatable accuracy and a minimum number of tools.
Depending upon the type of game being hunted or the conditions in which a hunter is pursuing the game, different caliber ammunition can be required. Consequently to accommodate different caliber ammunition, a hunter must carry a number of different firearms which can be inconvenient. Consequently rifles have been developed with a single action and stock that will accept a variety of different barrels thereby eliminating the need to carry separate firearms. In these instances, interchangeable rifle barrels of different calibers can be conveniently carried by the hunter. The interchangeable rifle barrels have different caliber bores as desired.
As can be appreciated, changing barrels on a firearm must be done precisely and accurately to avoid issues with firearm performance. Prior firearm designs included complicated constructions to provide accuracy and compatibility or the need for complicated or specialized tools to exchange the barrels. One can appreciate that it would be desirable for a hunter in the field to have a rifle design which can provide repeatable accuracy for changing the barrel and can be done with a minimum number of tools. Consequently a need exists for a firearm having a switch barrel recoil lug which can provide the user to change barrels under field conditions with repeatable accuracy and a minimum number of tools.
The present invention is directed to a switch barrel recoil lug for a bolt action rifle having interchangeable barrels which allows the user to change barrels under field conditions with repeatable accuracy and a minimum number of tools. The switch barrel recoil lug of the present invention is positioned between a face of a rifle action and a torque shoulder of the rifle barrel and replaces a standard recoil lug and therefore acts as both a recoil lug and a barrel clamping system. The switch barrel recoil lug of the present invention can include various embodiments, and for example, includes a body portion having a rifle barrel shank bore and a stock flange extending below the rifle action. The body portion is solid having front and back surfaces machined parallel to each other. The stock flange allows the lug to be properly fitted to the rifle stock for optimum accuracy and prevents flexing of the lug under recoil stress when the rifle is fired.
The switch barrel recoil lug has a clamping system which can include a split flange on a top portion of the lug to allow expansion and contraction of the lug around the barrel shank. A single screw extends through a threaded bore in the split top flange on an axis perpendicular to the barrel axis. The barrel shank bore through the recoil lug, through which the barrel passes, is larger in diameter than the diameter of the barrel shank so that the shank can pass through the lug freely when the clamp screw is loose.
The barrel of the rifle is threaded into the rifle action on one end and hand tightened against the face of the recoil lug. Once the barrel is hand tight, the clamp screw is tightened which contracts the sides of the lug against the barrel shank. The clamping force of the lug holds the barrel securely in place and prevents loosening of the barrel from the rifle action. In one configuration, the barrel shank bore hole in the recoil lug can be machined flat or in another embodiment, is machined with a tapered surface that increases in diameter toward the front face of the lug. In this embodiment, the barrel shank is also machined with a matching tapered surface. The tapered bore surface exerts a multidirectional force on the barrel shank when the clamp screws are tightened, forcing the external threads on the barrel shank into more positive contact with the internal threads of the rifle action. The tapered surface also helps with an alignment of the barrel to the rifle action when the recoil lug is clamped thereby providing an increase in repeatability of point of impact when the rifle is fired.
The recoil lug is aligned to the rifle action by the use of index pins or other alignment fasteners. These and other aspects of the present invention will be more clearly understood by reference to the following detailed description and accompanying drawings.
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The switch barrel recoil lug can be aligned to the rifle action 12 by a steel index pin 72 which is press fit into the end 16 of the rifle action. Index pin 72 is received within an index hole 74 extending into the rifle action face 22 of the recoil lug. Although a single index pin positioned at six o'clock as illustrated in the drawings, it is to be understood that multiple pins separated from one another could be incorporated. The index pin serves both to align the lug to the barrel tenon threads of the rifle action, and also to prevent lateral movement of the lug during tightening or loosening of the rifle barrel. As previously indicated, forward movement of the lug is prevented by precisely fitting the stock flange to the rifle stock. Once the recoil lug has been installed onto the rifle action and the barrel is tightened in place the rifle action and lug are bedded into the stock with a bedding compound such as Devcon, Acra-Glas or Marine Tex. Once properly fitted to the rifle action and stock, the clamp portion of the recoil lug can be operated properly with no lateral or forward movement of the recoil lug.
Although the present invention has been described and illustrated with multiple embodiments thereof, it is to be understood that other modifications could be made therein which are within the full intended scope of the invention as hereinafter claimed.
This application claims priority to and the benefit of U.S. Provisional Patent Application No. 62/308,760 filed Mar. 15, 2016, the entire contents thereof are incorporated herein by reference.
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Number | Date | Country | |
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62308760 | Mar 2016 | US |