The present disclosure generally relates to firearms accessories, and more particularly to an inertial decoupler for a firearm sound suppressor.
A suppressor mounted on a barrel of a pistol can cause the pistol to not cycle properly after being fired. The mass of the suppressor can increase the effective mass of the barrel such that the barrel does not move properly to cycle the pistol. To overcome this side effect, suppressors mounted on pistols often include an inertial decoupling device called a Nielsen device, booster, or linear inertial decoupler or damper (LID). Such devices temporarily “decouple” the mass of the suppressor from the barrel when the pistol is fired. Accordingly, the pistol is permitted to cycle properly notwithstanding the mass of the suppressor mounted on the barrel.
In one aspect, an inertial decoupler for connecting a firearm sound suppressor to a firearm comprises a housing having a housing proximal end and a housing distal end. The housing is sized and shaped to permit a projectile fired from the firearm to pass the housing from the housing proximal end to the housing distal end when the inertial decoupler is connected to the firearm. A spring is supported by the housing. A piston is supported by the housing and includes a piston proximal end and a piston distal end. The piston defines a piston passage configured to permit a projectile fired from the firearm to pass from the piston proximal end to the piston distal end along a projectile axis along the piston passage when the inertial decoupler is connected to the firearm. The piston is biased distally by the spring toward an at-rest position of the piston with respect to the housing. The piston defines a first spring engagement surface against which the spring bears to bias the piston toward the at-rest position. The piston is movable proximally with respect to the housing away from the at-rest position to deflect the spring responsive to firing of the firearm for temporarily decoupling the firearm sound suppressor from the firearm. A spring retainer defines a second spring engagement surface against which the spring bears to bias the piston distally with respect to the housing. The spring retainer is configurable in a first preset position with respect to the piston and a second preset position with respect to the piston to change a distance between the first and second spring engagement surfaces when the piston is in the at-rest position. When the spring retainer is in the first preset position and the piston is in the at-rest position, the spring has a first spring preload. When the spring retainer is in the second preset position and the piston is in the at-rest position, the spring has a second spring preload different than the first spring preload.
In another aspect, an inertial decoupler for connecting a firearm sound suppressor to a firearm. The inertial decoupler comprises a housing having a housing proximal end and a housing distal end. The housing is sized and shaped to permit a projectile fired from the firearm to pass the housing from the housing proximal end to the housing distal end when the inertial decoupler is connected to the firearm. A spring is supported by the housing. The inertial decoupler includes a piston supported by the housing. The piston includes a piston proximal end and a piston distal end. The piston defines a piston passage configured to permit a projectile fired from the firearm to pass from the piston proximal end to the piston distal end along a projectile axis along the piston passage when the inertial decoupler is connected to the firearm. The piston is biased distally by the spring toward an at-rest position of the piston with respect to the housing, the piston defining a first spring engagement surface against which the spring bears to bias the piston toward the at-rest position. The piston is movable proximally with respect to the housing away from the at-rest position to deflect the spring responsive to firing of the firearm for temporarily decoupling the firearm sound suppressor from the firearm. A stop is configured to engage the piston to limit piston travel with respect to the housing away from the at-rest position. The stop is configurable in first and second positions. The stop in the first position permits a first maximum distance of piston travel proximally from the at-rest position. The stop in the second position permits a second maximum distance of piston travel proximally from the at-rest position. The second maximum distance of piston travel is different than the first maximum distance of piston travel.
In yet another aspect, a method of adjusting an inertial decoupler for a firearm sound suppressor comprises selecting a specific firearm for use with the inertial decoupler, and changing a decoupling performance characteristic of the inertial decoupler to provide a decoupling performance of the inertial decoupler for the specific firearm.
Other objects and features of the present disclosure will be in part apparent and in part pointed out herein.
Corresponding reference characters indicate corresponding parts throughout the drawings.
Referring to
Referring to
The sound suppressor 14 includes a suppressor housing 16 defining an interior that houses a plurality of baffles 18 (e.g., at least two baffles). The sound suppressor has a proximal end connected to the inertial decoupler 12 and a distal end opposite the proximal end that is closed by an end cap 20 threaded to the housing 16. The suppressor housing 16 is internally threaded at its proximal end for forming a threaded connection 22 with the inertial decoupler 12. The sound suppressor 14 defines a projectile passage along which a projectile fired from a firearm can pass down a projectile axis PA when the suppressor is mounted on the firearm. The suppressor housing 16, baffles 18, and end cap 20 form a tortuous gas flow path to reduce sound emitted after the firearm is fired. It will be appreciated that the sound suppressor 14 is shown by way of example without limitation. Other types and configurations of sound suppressors (e.g., different types and numbers of baffles (e.g., one baffle) and/or housings, etc.) can be used without departing from the scope of the present disclosure.
The inertial decoupler 12 includes a housing 30, a piston 32, a spring 34, and a spring retainer 36. The piston 32 is connectable to the firearm and is biased distally by the spring 34 to an at-rest position in the housing 30 (e.g.,
Referring now also to
In the illustrated embodiment, the spring 34 is a compression spring. The spring includes a wire coil having opposite proximal and distal ends. The spring 34 is received over the piston 32 and is located in an interstitial space between the piston and the housing 30. Desirably, in the at-rest position of the piston 32, the spring 34 is in engagement with the spring retainer 36 and piston 32 such that the spring is deflected and exerts a biasing force maintaining the piston in the at-rest position. As explained in further detail below, the deflection of the spring 34 when the piston 32 is in the at-rest position (the spring preload) can be adjusted, which may change the spring force the piston needs to overcome to move proximally, away from the at-rest position.
The piston 32 has a head 32A at its distal end that is wider than a neck 32B extending proximally from the head to the proximal end of the piston. (See
The spring retainer 36 includes a collar 40 (broadly, “adjustment body”) and a cap 42 connected to the collar by a threaded connection 44. The cap includes an annular proximal wall and an inner sleeve 42A and outer sleeve 42B extending distally from the proximal wall. The spring 34 is received in the cap 42 between the inner and outer sleeves 42A, 42B. The outer sleeve 42B has a male thread for forming the threaded connection 44 with a female thread of the collar 40. The cap 42 defines a spring engagement surface 42C against which the proximal end of the spring 34 bears to bias the piston 32 distally with respect to the housing 30 and spring retainer 36. The inner sleeve 42A extends distally from the spring engagement surface 42C and terminates in a rim 42D facing distally. The rim 42D can be referred to broadly as a stop located to engage the shoulder 32F of the piston 32 to limit proximal travel of the piston from the at-rest position. Responsive to the firearm being fired, the piston 32 moves proximally from the at-rest position such that the suppressor 14 is temporarily “decoupled” from the firearm, until the shoulder 32F engages the stop 42D. Desirably, the distance PT1 between the shoulder 32F and the stop 42D when the piston 32 is in the at-rest position allows for sufficient piston travel to permit the firearm to cycle properly. This distance PT1 can be adjusted, as explained in further detail below.
The collar 40 includes a tubular collar body that extends from the cap 42 to the suppressor housing 16. The proximal end of the collar 40 has an internal thread configured to make the threaded connection with the cap 42. The distal end of the collar 40 overlies the outer surface of the suppressor housing 16, terminates in a rim 40A, and is slidably engaged with the outer surface of the suppressor housing. A seal in the form of an O-ring 50 seated in an annular groove in the suppressor housing 16 is provided to resist entry of contaminants into the inertial decoupler 12 between the collar 40 and the suppressor housing.
The spring retainer 36 is configurable in several preset positions with respect to the housing 30 and piston 32 to change a distance S1 between the spring engagement surfaces 32E, 42C, and the distance PT1 between the piston shoulder 32F and the stop 42D, when the piston 32 is in the at-rest position. In the illustrated embodiment, the spring retainer 36 is movable to four preset positions. As shown in
The inertial decoupler 12 includes retaining structure configured to selectively retain the spring retainer 36 in the first preset position and the second preset position. The retaining structure includes first connection structure and second connection structure configured to engage the first connection structure to retain the spring retainer in the preset positions. In the illustrated embodiment, the collar 40 includes the first connection structure, which includes three lugs 60, two of which may be seen in
The lug tracks 62 include a plurality of lug seats 64-67 to which the lugs 60 are movable to change the position of the spring retainer 36 with respect to the housing 30 and piston 32. In each of the preset positions, each lug 60 is engaged with an associated lug seat 64-67 in its respective lug track 62. The lugs 60 move conjointly along their respective lug tracks 62 to change among the preset positions of the spring retainer 36. Each lug seat 64-67 is defined by a slot extending along the outer surface of the housing 30 and generally parallel with the projectile axis PA. The slots each include opposite side walls 64A, 64B, 65A, 65B, 66A, 66B, 67A, 67B and a proximal wall 64C, 65C, 66C, 67C against which the lugs 60 bear in in opposition of the spring bias when the lugs are engaged with the seats 64-67. The side walls 64A, 64B, 65A, 65B, 66A, 66B, 67A, 67B obstruct the lugs 60 to limit rotation of the spring retainer 36 about the projectile axis PA with respect to the housing 30 when the lugs 60 are engaged with the lug seats 64-67. The lugs 60 are maintained in engagement with the seats 64-67 by the spring 34 biasing the spring retainer 36 proximally. The spring retainer 36 can be referred to as “locked” in a preset position when the lugs 60 are engaged with a set of the seats 64-67 and the spring 34 is biasing the lugs to maintain them in the seats.
To change the preset position of the spring retainer 36, a user can disengage all of the lugs 60 conjointly from a set of lug seats 64-67 by grasping the suppressor housing 16 with one hand, grasping the spring retainer with another hand, and pushing the spring retainer to deflect the spring 34. This “unlocks” the spring retainer 36 and permits the spring retainer to be rotated about the projectile axis PA to relocate the lugs 60 to a different set of lug seats 64-67. It will be appreciated that the lug track 62 is stepped such that, depending on the lug seats 64-67 to which the lugs 60 are to be moved, the user may need to use a combination of rotation and axial movement (either proximally or distally) of the spring retainer 36. When the lugs 60 are located in axial alignment with the desired set of lug seats 64-67, the user can permit the spring 34 to push the spring retainer 36 proximally to engage the lugs with the lug seats (slide proximally into the slots defining the lug seats), thus locking the spring retainer in that preset position of the spring retainer.
An example sequence of moving the spring retainer 36 to reposition the lugs 60 from a first lug seat 64 to a second lug seat 65 is shown in
A comparison of
It will be appreciated that other types of retaining structure (e.g., other than lugs and lug tracks or lug seats, etc.) could be used without departing from the scope of the present disclosure. For example, the retaining structure could include a male thread and a female thread forming a threaded connection. In such an example, the preset positions of the spring retainer can be preset by indicators (e.g., on the suppressor housing, inertial decoupler housing, spring retainer, etc.) indicating positions to which the spring retainer can be moved with respect to other structure. A reference such as an edge (or other portion) of, or an indicator on, a structure (e.g., suppressor housing, inertial decoupler housing, spring retainer, etc.) could be used in conjunction with the preset position indicators to indicate to a user when the spring retainer is in the respective preset positions. For example, clocking marks could be provided on the inertial decoupler housing and/or the suppressor housing, and a reference mark on the spring retainer could be used in reference to the clocking marks to locate the spring retainer in preset positions. Accordingly, the indicators would define the preset positions of the spring retainer. It will be appreciated that in the embodiment disclosed herein, the connection structure 60, 62 and the indicators 54A-54D define the preset positions of the spring retainer 36, and in other embodiments connection structure or indicators could define the preset positions of the spring retainer. In some embodiments, the preset positions of the spring retainer could be defined by connection structure, and indicators indicating the preset positions could be omitted.
In a method of using the assembly, a firearm is selected for use with the assembly. For example, a specific pistol may be selected. Based on the characteristics of the pistol, the user may adjust an inertial decoupling characteristic (e.g., spring preload and/or permitted piston travel distance) to provide an inertial decoupling performance for the specific pistol. To adjust the inertial decoupler, the user could reference instructions explaining the spring preloads and/or permitted piston travel associated with the different indicators 52A-52D and labels 54A-54D, and select a preset position of the spring retainer 36 based on the desired spring preload and/or permitted piston travel. For example, the user may manipulate the spring retainer to disengage the lugs from the lug seats 64 and move them to the lug seats 66.
It will be appreciated that different suppressors, pistols, and ammunitions function differently, and a single spring without adjustment may not allow all pistols to function for a given suppressor/pistol/ammunition system. By adjusting the preload of the spring and/or permitted piston travel (amount the pistol barrel moves before it encounters the mass of the suppressor) the adjustable decoupler can be customized to meet user preferences (e.g., feel) and/or to match a suppressor to the requirements of a particular pistol (e.g., based on recoil characteristics, such as unlocking distance of a locked breech, needed to cycle the pistol). The user can adjust the settings on the decoupler to increase/decrease the preload of the spring and/or the permitted travel distance of the piston relative to the suppressor. The decoupler is universal in that it is usable with various suppressors (suppressors having different masses) and with various pistols (having different recoil characteristics).
In testing of a prototype of the illustrated decoupler and suppressor assembly, it was found that adjustment in permitted piston travel distance is particularly useful. This is because some pistols unlock at different positions as the pistol recoils. The unlocking distance of a locked breech pistol is relevant to adjustment of the decoupler. It is desirable to adjust the decoupler to permit piston travel greater than the unlocking distance.
It will be apparent that modifications and variations are possible without departing from the scope of the appended claims. As various changes could be made in the above constructions and methods without departing from the scope of the invention, it is intended that all matter contained in the above description and shown in the accompanying drawings shall be interpreted as illustrative and not in a limiting sense.
The present application is a continuation application which claims priority to U.S. patent application Ser. No. 16/596,577 filed Oct. 8, 2019, which claims priority to U.S. Patent Application No. 62/743,398, filed Oct. 9, 2018, the entirety of which is hereby incorporated by reference.
Number | Name | Date | Kind |
---|---|---|---|
2191484 | Hughes | Feb 1940 | A |
2759286 | Moore | Aug 1956 | A |
2847788 | Twigg | Aug 1958 | A |
2883782 | Schroeder | Apr 1959 | A |
2894348 | Cutts | Jul 1959 | A |
3156061 | Evans | Nov 1964 | A |
3797155 | Smith | Mar 1974 | A |
3867778 | Preda | Feb 1975 | A |
4384507 | Finn | May 1983 | A |
4972760 | McDonnell | Nov 1990 | A |
5279200 | Rose | Jan 1994 | A |
5559302 | Latka | Sep 1996 | A |
5814757 | Buss | Sep 1998 | A |
7493845 | Mantas | Feb 2009 | B2 |
7588122 | Brittingham | Sep 2009 | B2 |
8186261 | McNeill et al. | May 2012 | B2 |
8272306 | Smith | Sep 2012 | B1 |
8387299 | Brittingham | Mar 2013 | B1 |
8857306 | Edsall | Oct 2014 | B1 |
8910558 | Kent | Dec 2014 | B2 |
9631888 | Young | Apr 2017 | B2 |
9739560 | Salvador | Aug 2017 | B1 |
9921021 | Graham, II | Mar 2018 | B1 |
9958227 | Whitson | May 2018 | B2 |
10048033 | Lee | Aug 2018 | B1 |
10184744 | Young | Jan 2019 | B2 |
10184745 | Fulton | Jan 2019 | B1 |
10281228 | Marfione | May 2019 | B1 |
10605558 | Marfione | Mar 2020 | B1 |
10619962 | Hatfield | Apr 2020 | B1 |
20090050403 | Brittingham | Feb 2009 | A1 |
20110088540 | Brittingham | Apr 2011 | A1 |
20150253098 | Russell | Sep 2015 | A1 |
20170205176 | Whitson | Jul 2017 | A1 |
20170307322 | Davis | Oct 2017 | A1 |
20170336165 | Wirth | Nov 2017 | A1 |
20180106569 | Smith | Apr 2018 | A1 |
20180120045 | Rost | May 2018 | A1 |
20180292164 | Thompson | Oct 2018 | A1 |
20190353446 | Kras | Nov 2019 | A1 |
20200248980 | Bragais | Aug 2020 | A1 |
Entry |
---|
Operational Manual for Sound Suppressor Model Trinity (9mm), Manufactured by Gemtech, Sep. 16, 2006, 16 pages. |
Number | Date | Country | |
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20210270558 A1 | Sep 2021 | US |
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62743398 | Oct 2018 | US |
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Parent | 16596577 | Oct 2019 | US |
Child | 17181457 | US |