The present teachings relate to a bolt action system for a firearm. In particular, the present teachings relate to a rimfire bolt action that can facilitate the precise positioning of the bolt and firing pin within the receiver in order to improve accuracy and ease of use of the firearm.
There are a variety of known designs of bolt actions for rifles. A design objective of bolt actions is the precise alignment of a bolt face to a cartridge chamber to properly position the firing pin to strike the primer of a cartridge. To achieve precise and repeatable firing results during competition shooting, it is desirable to accurately secure the bolt mechanism in its proper position and keep it relatively immovable with respect to the cartridge and barrel during movement of the firing pin and the striking of the cartridge primer.
Moreover, due to the nature of high-powered rifles, the bolt mechanism is subjected to enormous stress as gas pressure caused by cartridge firing rapidly builds and expels the projectile from the barrel. In order to achieve precise accuracy during firing, it is critical that the axis of the bolt and the firing pin remain parallel with the axis of the bore of the firearm barrel while also providing a perpendicular surface to accept a cartridge head.
In competition shooting, rimfire cartridges are often used with a bolt action rifle. The forces generated by a rimfire cartridge are much less than a center fire cartridge. A rimfire cartridge, when fired, is traveling about a third of the speed of a center fire cartridge which means the bullet is in the barrel a longer period of time when compared to a center fire. The resulting lag time in the barrel exposes the bullet to vibrations created during the firing process and these vibrations affect the bullet's trajectory. It has been proven through extensive testing that a front lock-up bolt design generally used with center fire ammunition accentuates the vibrations experienced by rimfire cartridges due to the close proximity of the lugs to the case rim and the lag time, and is therefore considered detrimental to accuracy.
In addition, known rear lock-up bolt receivers distribute bolt pressure over a maximum of two contact points at the rear of the receiver. This results in the bolt assembly flexing and moving during the firing of a round. Such movement of the bolt assembly also prevents consistent positioning of the components of the bolt action thereby jeopardizing accurate, repeatable performance by the shooting competitor.
Bolt action rifles that fire rimfire cartridges incorporate an offset firing pin. A center fire cartridge has a replaceable primer located in the center of the cartridge and when struck by the centrally located firing pin, the primer creates a flash that ignites the gun powder. In contrast, a rimfire cartridge's primer is part of the case. More specifically, there is a fold of brass material at the rim of the rimfire cartridge that has a chemical compound applied to the area inside the case prior to the gun powder and bullet being installed in the cartridge. The firing pin of a rimfire bolt action assembly is offset and strikes the rimfire cartridge on the outer edge of the case. Due to the firing pin being off center, the bolt will experience a force that is shifted to one side and the bolt will move away from the force if not supported properly.
Accordingly, there exists a need for a rear lock-up rimfire bolt action assembly that can evenly distribute the forward pressure the bolt assembly places on a chambered round and will not allow the bolt assembly to move or flex within the action body during the firing of the round.
The present teachings provide a bolt action assembly including a receiver body having a front aperture capable of receiving a firearm barrel and a rear aperture. A lug groove is formed in the vicinity of the rear aperture of the receiver body. The bolt action assembly further includes a bolt assembly having a bolt handle and three rear locking lugs arranged on a rear portion of the bolt assembly. The bolt assembly is configured to be arranged in the receiver body such that the three rear locking lugs are capable of being rotated within the lug groove when the bolt handle is rotated.
The present teachings also provide a rear lock-up bolt action assembly including a receiver body having a lug groove formed in the vicinity of a rear portion of the receiver body. The lug groove defines a rear shoulder surface. The rear lock-up bolt action assembly further includes a bolt assembly including a bolt handle and at least three rear locking lugs arranged on a rear portion of the bolt assembly. Each of the at least three rear locking lugs defines a rear seating surface. The bolt assembly is configured to be supported in the receiver body such that when a round is fired the rear seating surfaces of each of the three rear locking lugs are forced to mate with the rear shoulder surface of the lug groove thereby evenly distributing a bolt pressure.
The present teachings still further provide a rear lock-up rimfire bolt action assembly including a receiver body including a lug groove formed in the vicinity of a rear portion of the receiver body. The rear lock-up rimfire bolt action assembly further includes a bolt assembly including an offset firing pin, a bolt handle, and at least three rear locking lugs arranged on a rear portion of the bolt assembly. The bolt assembly is configured to be supported in the receiver body such that when a rimfire cartridge is fired, the three rear locking lugs are forced to mate with the lug groove thereby evenly distributing a bolt pressure on the receiver body.
Additional features and advantages of various embodiments will be set forth, in part, in the description that follows, and will, in part, be apparent from the description, or may be learned by the practice of various embodiments. The objectives and other advantages of various embodiments will be realized and attained by means of the elements and combinations particularly pointed out in the description herein.
a shows an end view of the rear portion of the bolt action assembly of the present teachings with the bolt handle in the fully open position;
b shows an cross-sectional view of the rear portion of the bolt action assembly of the present teachings with the bolt handle in the fully open position;
a shows an end view of the rear portion of the bolt action assembly of the present teachings with the bolt handle in the closed position; and
b shows a cross-sectional end view of the rear portion of the bolt action assembly of the present teachings taken through line 9B-9B of
It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory only, and are intended to provide an explanation of various embodiments of the present teachings.
Referring to
As will be discussed in more detail below, the receiver body 200 further includes a lug groove 210 that is located in the vicinity of the rear aperture 204 and is adapted to be engaged by three locking lugs 322, 324, 326 located on a rear portion of the bolt assembly 300. The lug groove 210 of the receiver body 200 and the complementary-shaped rear locking lugs 322, 324, 326 of the bolt assembly 300 permit a rear portion of the bolt assembly 300 to be securely held within the receiver body 200 and in a concentric manner with respect to the firearm barrel 400 thereby allowing accurate and repeatable firing of the firearm. The rearward location of the locking lugs 322, 324, 326 and of the lug groove 210 form a rear lock-up arrangement for the bolt action assembly 100 of the present teachings.
Now referring to
As best shown in
Referring to
Referring to
The firing spring 360 can be arranged within a bore 350 formed in the firing pin slide 340. In an assembled condition of the bolt assembly 300, the firing spring 360 is held via a pin 370 within the firing pin slide 340 in a manner that resiliently forces the cocking piece 342 against the bolt handle 320 (which in turn is forced against the bolt body 310) thereby forcing the cocking lobes 346, 348 into engagement with the cam surfaces 336 of the bolt handle 320.
Referring to
Referring to
Prior to inserting the bolt assembly 300 into the receiver body 200, the bolt handle 320 must be in the fully open position. When the bolt handle 320 is in the fully open position, the firing pin spring 360 is in a compressed state. After the bolt assembly 300 is fully inserted into the rear portion of the receiver body 200, the bolt action assembly 100 of the present teachings can be cocked.
Cocking the bolt action assembly 100 involves rotating the bolt handle 320 through an angular movement, X°, from a fully open position shown in
As the bolt handle 320 is rotated from the fully open position to the fully closed position, the locking lugs 322, 324, 326 are also rotated within the lug groove 210 of the receiver body 200 into a position where the back seating surface 334 of each locking lug 322, 324, 326 is engaged and supported by the corresponding rear shoulder surface 214 of the lug groove 210.
During use, as the bolt handle 320 is rotated from the fully closed position to the fully open position, the cocking lobes 346, 348 of the cocking piece 342 are forced into engagement with the moving cam surfaces 336 of the bolt handle 320 which cocks the cocking piece 342 while the firing spring 360 is compressed.
By incorporating three locking lugs 322, 324, 326, the angular movement, X°, required to cycle the bolt handle 320 to cock the bolt action assembly 100 is reduced. For example, the angle of movement of the bolt handle 320 can be from about 40° to about 50°, and most preferably about 45°. The reduced amount of radial movement required to work the bolt action assembly 100 of the present teachings achieves a reduced overall cycling time of the action.
Pulling the trigger by the shooting competitor results in the release of the sear and in turn, releases the firing spring 360, which drives the offset firing pin 349 out of a hole in the bolt face and into the primer in the outer edge of the base of the rimfire cartridge. This impact detonates the primer which ignites the powder and discharges the round. Once the firing pin slide 340 has been released, it can remain uncocked until the bolt handle 320 is cycled again. To cycle the bolt action assembly 100, for example, the bolt handle 320 is rotated from the closed to the open position, the bolt assembly 300 is slid rearward until it engages a bolt stop (during this rearward movement the spent casing is ejected from the action), a new cartridge is inserted into the bolt action assembly 100, and the bolt assembly 300 is pushed forward (which inserts the new cartridge into the chamber of the barrel) until the bolt assembly 300 stops, at which time the bolt handle 320 is rotated from the open position to the closed position. The bolt action assembly 100 is then in a cocked and ready-to-fire position.
The firing of the cartridge subjects the bolt assembly 300 to enormous stress as gas pressure builds rapidly and expels the round from the barrel. The three rear locking lugs 322, 324, 326 of the bolt action assembly 100 of the present teachings operate to evenly distribute the bolt pressure over three large contact points at the rear portion of the receiver body 200. More particularly, the rear seating surfaces 334 of each of the three locking lugs 322, 324, 326 are forced to mate with the rear shoulder surface 214 of the lug groove 210 when the bolt assembly 300 is subjected to the high pressures created from the firing of a round. By evenly distributing the bolt pressure, the locking lugs 322, 324, 326 prevent longitudinal play as well as preventing whipping or flexing of the bolt assembly 300 within the receiver body 200. This will stop the bolt assembly 300 from moving up, down, or side-to-side in any way during the firing of a round.
Moreover, due to the firing pin slide 340 including an offset firing pin 349, the bolt assembly 300 will also experience a force that is shifted to one side if not supported properly. The three rear locking lugs 322, 324, 326 of the bolt action assembly 100 of the present teachings also operate to securely lock the bolt assembly 300 to the rear portion of the receiver body 200 thereby securely centering the bolt assembly 300 within the receiver body 200.
The three rear locking lugs 322, 324, 326 of the bolt action assembly 100 operate to lock the bolt assembly 300 into a position concentrically within the receiver body 200 and concentrically with a firearm barrel 400. This allows the axis of the bolt assembly 300 and of the firing pin slide 340 to remain parallel with the longitudinal axis of the central bore of the firearm barrel 400. Securely positioning the bolt assembly 300 also critically provides a perpendicular surface to evenly distribute the pressure of the bolt assembly 300 on the chambered round.
The movement of the bolt assembly 300 during the firing of a round is detrimental to the accuracy of the fired round and any movement of the bolt assembly 300 will affect its trajectory. The bolt action assembly 100 of the present teachings operates to evenly distribute the pressure the bolt assembly 300 experiences during the firing of the round and to reduce any vibrations and movement of the bolt assembly 300 within the receiver body 200. This allows consistent positioning of the components of the bolt action assembly 100 resulting in accurate, repeatable firing performance by the shooting competitor.
The components of the bolt action assembly 100 of the present teachings can be manufactured using both conventional and CNC type machine shop equipment. For example, the receiver body 200 can be manufactured from Type 416R stainless steel. For example, the bolt handle 320 can be manufactured from 4140HT alloy steel. The components of the bolt action assembly 100 of the present teachings can be machined to precise tolerances to assure proper alignment and fit with the mating pieces. Surfaces can be smooth with substantially no inclusions, blemishes, or scratches.
Those skilled in the art can appreciate from the foregoing description that the present teachings can be implemented in a variety of forms. Therefore, while these teachings have been described in connection with particular embodiments and examples thereof, the true scope of the present teachings should not be so limited. Various changes and modifications may be made without departing from the scope of the teachings herein.
The present application claims the benefit from earlier filed U.S. Provisional Patent Application No. 61/973,774, filed Apr. 1, 2014, which is incorporated herein in its entirety by reference.
Number | Name | Date | Kind |
---|---|---|---|
1331154 | Johnson | Feb 1920 | A |
1344991 | Cunningham | Jun 1920 | A |
1545045 | Dute | Jul 1925 | A |
1631242 | Burton | Jun 1927 | A |
2214071 | Swebilius | Sep 1940 | A |
2424264 | Yorks | Jul 1947 | A |
2490922 | Rutherford et al. | Dec 1949 | A |
3330061 | Koon, Jr. | Jul 1967 | A |
3494216 | Haskins | Feb 1970 | A |
3745686 | Koon, Jr. | Jul 1973 | A |
3979849 | Haskins | Sep 1976 | A |
5228887 | Mayer | Jul 1993 | A |
5410834 | Benton et al. | May 1995 | A |
6000161 | Aalto | Dec 1999 | A |
6508025 | Du Plessis | Jan 2003 | B1 |
7975417 | Duplessis et al. | Jul 2011 | B2 |
8302340 | Irwin | Nov 2012 | B1 |
8683726 | Genton | Apr 2014 | B1 |
20150020423 | Withey | Jan 2015 | A1 |
Number | Date | Country |
---|---|---|
778083 | Jul 1957 | GB |
Number | Date | Country | |
---|---|---|---|
61973774 | Apr 2014 | US |