Patent ID: 9347727
Filing Date: 2016-05-24
CPC Classification: F41A

Claim Text:
1. A suppressor for use with a firearm, the suppressor adapted to be secured to a distal end of a barrel of the firearm, coaxial with a bore axis of the firearm, the suppressor comprising: a) An outer can of a cylindrical shape having a proximal can end, which proximal can end is adjacent to the distal end of said barrel, a distal can end opposed to said proximal can end, an interior can diameter, an interior can surface, and a central axis which is coaxial with the bore axis; b) Wherein said proximal can end includes an inlet aperture located about the central axis, whereby there are means by which the proximal can end is secured to the barrel; c) Wherein the suppressor further comprises a central chamber configured along the central axis, which is defined by an interior of a plurality of unported K-baffles; d) Wherein said plurality of unported k-baffles are comprised of a series of frustoconical segments, and an annular ring segments arranged alternatingly and coaxially with each other and with the central axis; e) Wherein each of said frustoconical segments has a large diameter end and a small diameter end, the large diameter end being partially closed by a thin annular ring which extends from the outer diameter of said large diameter end to an interior annular circle which is coaxial with said central axis; f) Wherein a first frustoconical segment is oriented on the central axis so that its small diameter end is proximal to the inlet aperture, and is separated from the inlet aperture by an offset distance along the central axis; g) whereby the small diameter end of each subsequent frustoconical segment is in communication with the interior annular circle of the annular ring of the preceding frustoconical segment, such that the series of frustoconical segments form an uninterrupted central structure which defines a central chamber gas flow path, and is of a length sufficient that said central chamber gas flow path extends substantially to the distal can end; h) wherein the frustoconical segment which is substantially located at the distal can end seats and seals against a circular end cap, which circular end cap includes a central circular outlet which is coaxial with said central axis and provides an exit for the central chamber gas flow path; i) Wherein the large diameter ends of the frustoconical segments are of a smaller diameter than the interior can diameter; j) Wherein the unported K-baffles has an exterior of the unported K-baffles, which, in combination with the interior can surface substantially defines a bypass chamber; k) A series of an bypass baffles within the bypass chamber, oriented perpendicular with respect to the central axis, whereby the exterior of the unported K-baffles, the interior can surface, and the bypass baffles define a bypass flow path, where the bypass flow path has a minimum bypass flow cross sectional area; l) Wherein the inlet aperture is in fluid communication with both the central chamber and the bypass chamber, for the length of the offset distance; m) Whereby there is no fluid communication between the central chamber and the bypass chamber beyond the offset distance or along the length of the unported K-baffles; n) A circular end cap which may be mated with the distal can end which includes a central circular outlet disposed about the central axis which is in close communication with the distal K-baffle end and which central outlet provides an exit for the central chamber flow path; o) Wherein the circular end cap is further comprised of a series of perforations, which surround the central circular outlet, which provide outlets for the bypass flow path, and where the aggregate area of the perforations defines a bypass exit cross sectional flow area; p) Wherein the minimum ratio of the minimum bypass flow cross sectional area to the bypass exit cross sectional flow area is 2:1.