This invention relates to barrels for firearms.
During operation of semiautomatic pistols using the short recoil system, the breech end of the barrel drops downwardly toward the frame after the barrel unlocks from the slide as the slide and barrel move relatively to the frame in recoil as a round is fired. This drop of the barrel's breech end causes the longitudinal axis of the barrel to have an angular orientation with respect to the direction of motion of the slide. The drop of the breech end also causes the now spent cartridge casing in the chamber to move downwardly relatively to the slide, on which the extractor is mounted. Under certain conditions the drop could be great enough to allow the rim of the spent casing to drop below the controlling surface of the extractor, causing a failure to extract as the barrel's breech end separates from the breech block mounted on the slide. This type of malfunction is particularly difficult to clear. There is an opportunity therefore, to increase the reliability of semiautomatic pistols operating on the short recoil system by controlling the breech end drop of the barrel, or the angular orientation of the barrel's longitudinal axis with respect to the direction of motion of the slide.
The invention concerns a barrel for a firearm. In one example embodiment, the barrel comprises a tube having a breech end and a muzzle end oppositely disposed. The tube defines a longitudinal axis extending lengthwise along and positioned coaxially within the tube. A chamber comprises the breech end of the tube and an arresting means underlies the chamber. A first cam follower is positioned on the tube between the breech end and the muzzle end. The first cam follower comprises a projection extending outwardly from the tube in a direction angularly offset about the longitudinal axis from the arresting means.
In a particular example, the first cam follower is offset about the longitudinal axis about 180° from the arresting means. Further by way of example, the first cam follower comprises a first surface of the projection oriented angularly with respect to the longitudinal axis, the first surface facing the muzzle end. In a specific example, the first surface has an orientation angle from about 10° to about 20° relative to the longitudinal axis. In a particular example, the first surface has an orientation angle of about 15° relative to the longitudinal axis.
In another example embodiment, the first cam follower further comprises a second surface of the projection contiguous with the first surface and positioned between the first surface and the breech end. In this example the second surface is substantially parallel to the longitudinal axis.
By way of further example, the first cam follower comprises a surface of the projection oriented substantially parallel to the longitudinal axis. Another example embodiment further comprises a second cam follower positioned on the tube and underlying the muzzle end. The second cam follower comprises a projection extending outwardly from the tube by way of example.
In an example embodiment, the second cam follower is substantially aligned with the arresting means lengthwise along the tube. Further to an example, the second cam follower comprises a first surface of the projection oriented angularly relative to the longitudinal axis, the first surface facing the breech end. In a particular example the first surface has an orientation angle from about 5° to about 15° relative to the longitudinal axis. In a specific example, the first surface has an orientation angle of about 10° relative to the longitudinal axis.
By way of further example, the second cam follower further comprises a second surface of the projection contiguous with the first surface and positioned between the first surface and the muzzle end. In a specific example, the second surface is oriented substantially parallel to the longitudinal axis.
Specifically, by way of example, the arresting means comprises a locking cam, or the arresting means comprises a pivoting link.
The invention also encompasses a firearm. By way of example, the firearm comprises a frame, a slide mounted on the frame and reciprocably movable relative thereto along a slide axis, the slide having an inner surface defining a central space. In this example a first is cam positioned on the inner surface of the slide. A barrel is mounted on the frame and positioned within the central space. In this example the barrel comprises a tube having a breech end and a muzzle end oppositely disposed. The tube defines a longitudinal axis extending lengthwise along and positioned coaxially within the tube in this example. Further by way of example, a chamber comprising the breech end of the tube and an arresting means underlies the chamber. A first cam follower is positioned on the tube between the breech end and the muzzle end in this example. The first cam follower comprises a projection extending outwardly from the tube in a direction angularly offset from the arresting means about the longitudinal axis so as to align with the first cam. In this example the first cam follower engages the first cam upon sliding motion of the slide relatively to the barrel. Engagement between the first cam follower and the first cam determines an orientation angle between the longitudinal axis of the barrel and the slide axis during operation of the firearm.
In this example embodiment the first cam comprises a recess in the inner surface of the slide. The recess has a ramp surface oriented angularly with respect to the slide axis. The ramp surface faces the first cam follower. Further in this example, a run surface is on the inner surface of the slide. The run surface is contiguous with the ramp surface and positioned between the recess and the muzzle end.
In a particular example, the run surface is oriented substantially parallel to the slide axis. In a specific example, the ramp surface has an orientation angle relative to the slide axis from about 10° to about 20°. Particularly by way of example, the ramp surface has an orientation angle of about 15° relative to the slide axis.
By way of further example, the first cam comprises a recess in the inner surface of the slide and a run surface on the inner surface of the slide. In this example the run surface is positioned between the recess and the muzzle end. By way of further example the run surface is oriented substantially parallel to the slide axis. In a particular example embodiment the first cam follower is offset about the longitudinal axis about 180° from the arresting means. By way of example, the first cam follower comprises a first surface of the projection oriented angularly with respect to the longitudinal axis, the first surface facing the muzzle end. In a particular example, the first surface has an orientation angle from about 10° to about 20° relative to the longitudinal axis. By way of a specific example embodiment, the first surface has an orientation angle of about 15° relative to the longitudinal axis.
By way of example, the first cam follower further comprises a second surface of the projection contiguous with the first surface and positioned between the first surface and the breech end, the second surface being substantially parallel to the longitudinal axis. In an example embodiment the first cam follower comprises a surface of the projection oriented substantially parallel to the longitudinal axis. Generally by way of example, the orientation angle between the longitudinal axis of the barrel and the slide axis does not exceed 2° during operation of the firearm.
Another example embodiment further comprises a second cam mounted on the inner surface of the slide, the second cam being positioned proximate to the muzzle end of the tube. In this example a second cam follower is positioned on the tube and underlies the muzzle end. The second cam follower comprises a projection extending outwardly from the tube and aligned with the second cam. In this example, upon motion of the slide relative to the barrel, the second cam follower engages the second cam. The first and second cams and cam followers cooperate in this example to determine the orientation angle between the longitudinal axis of the barrel and the slide axis during operation of the firearm.
By way of example the second cam comprises a surface oriented substantially parallel to the slide axis. Further by example, the second cam follower is substantially aligned with the arresting means. In another example, the second cam follower comprises a first surface of the projection oriented angularly relative to the longitudinal axis, the first surface facing the breech end. In a specific example the first surface has an orientation angle from about 5° to about 15° relative to the longitudinal axis. Particularly by way of example, the first surface has an orientation angle of about 10° relative to the longitudinal axis.
In another example embodiment the second cam follower further comprises a second surface of the projection contiguous with the first surface and positioned between the first surface and the muzzle end, the second surface being substantially parallel to the longitudinal axis. In a specific example the arresting means comprises a locking cam or a pivoting link.
A first cam follower 28 is positioned on tube 12 between the breech end 16 and the muzzle end 14. Cam follower 28 comprises a projection 28a extending outwardly from tube 12 in a direction indicated by arrow 30 that is angularly offset about the longitudinal axis 18 from arresting means 22. In this example the cam follower 28 is offset 180° from the arresting means 22, i.e., the projection direction 30 is angularly opposite to the arresting means 22. First cam follower 28 comprises a first surface 32 of the projection 28afacing the muzzle end 14 of barrel 10 and oriented angularly with respect to the longitudinal axis 18. Orientation angles 34 from about 10° about 20° are feasible, with an orientation angle of 15° being advantageous. The first cam follower 28 further comprises a second surface 36, contiguous with the first surface 32, the second surface 36 being oriented substantially parallel with longitudinal axis 18 and positioned between the first surface 32 and the breech end 16 of barrel 10. While it is advantageous for the first cam follower 28 to include angularly oriented surface 32, it is also feasible to dispense with this surface so that the first cam follower comprises only the second surface 36 oriented substantially parallel to longitudinal axis 18 as shown in
Barrel 10 may further include a second cam follower 38 positioned underlying the muzzle end 14 of tube 12. Second cam follower 38 is substantially aligned with arresting means 22 lengthwise along tube 12 and comprises a projection 38aextending outwardly therefrom. In this example the second cam follower 38 comprises a first surface 40 of the projection facing the breech end 16 of tube 12 and oriented angularly with respect to the tube's longitudinal axis 18. Orientation angles 41 from about 5° to about 15° are feasible, with an orientation angle of 10° being advantageous. The second cam follower 38 further comprises a second surface 42 of the projection 38a, contiguous with the first surface 40, the second surface 42 being oriented substantially parallel with longitudinal axis 18 and positioned between the first surface 40 and the muzzle end 14 of barrel 10.
Pistol 44 may also comprise a second cam 66 mounted on the inner surface 52 of slide 48 and positioned proximate to the muzzle end 14 of barrel 10 for engagement with the second cam follower 38 during operation of the pistol 44. In this example the second cam 66 comprises a surface 68 oriented substantially parallel to the slide axis 50. Second cam 66 is aligned with the second cam follower 38 to permit the two cams and cam followers to cooperate with one another and control the angle between the longitudinal axis 18 of barrel 10 and the slide axis 50 during operation of the pistol 44.
As shown in
In a specific example firearm having a barrel with cams as disclosed herein, wherein the orientation angle 34 of the first surface 32 of the cam follower (or the orientation angle 62 of the ramp surface 60) is about 15°, it is expected that the angle 78 between the barrel longitudinal axis 18 and the slide axis 50 will be reduced from 2.45° to 1.47° at the point in the operation cycle where a round is being chambered, and, at the point in the operation cycle where a round is being ejected, the angle 78 is expected to be reduced from 2.47° to 1.12°. While the desired orientation angle 78 will vary depending upon the particular firearm, it is expected that orientation angles no greater than 2° will be advantageous for many applications.
Additional practical embodiments of the barrel 10 and slide 48 are shown in
Using cam followers on the barrel and cams on the slide to control the angle of orientation of the barrel during operation it is expected that pistols operating on the short recoil system will operate with greater reliability. In particular, smaller barrel orientation angles are expected to be advantageous with respect to ammunition feeding.
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Number | Date | Country | |
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20160138882 A1 | May 2016 | US |