1. Field of the Invention
This disclosure relates to firearms in general, and more particularly, to attachments for firearms that can be used to prevent or suppress muzzle flash, muzzle rise, or as an attachment for mounting a firearm accessory, such as a sound suppressor or a blank firing adapter.
2. Related Art
Firearms, such as pistols or rifles, utilize expanding high-pressure gases generated by a burning propellant to expel a projectile from a muzzle end of a barrel of the weapon at a relatively high velocity. When the projectile, or bullet, exits the muzzle of the weapon's barrel, a bright, “muzzle flash” of light and a high-pressure pulse of combustion gases accompany it. The rapid pressurization and subsequent depressurization caused by the high-pressure pulse gives rise to a loud sound known as “muzzle blast,” which, like muzzle flash, can readily indicate to a remote enemy both the location of the weapon and the direction from which it is being fired. In some situations, such as covert military operations, it is desirable to conceal such information from the enemy by suppressing the flash with a “flash hider” attachment and/or eliminating or substantially reducing the amplitude of the muzzle blast with a “sound suppressor” or “silencer.”
In addition to muzzle flash and muzzle blast, the expanding high-pressure gases can also result in a phenomenon referred to as “muzzle rise” or “muzzle climb,” i.e., a tendency of the muzzle of the weapon to rotate upwards relative to the horizon and sideways relative to the vertical after firing, thereby causing the weapon to miss the target aimed at and adversely affecting the accuracy of the weapon, particularly during automatic or rapid fire thereof. To prevent or reduce this undesirable effect, firearm attachments referred to as “muzzle brakes” or “recoil compensators” are often used.
Sound suppressors (also referred to as “noise suppressors” or “silencers”) can be used on firearms to reduce the amplitude of their muzzle blast, and in some cases, muzzle flash. Suppressors operate to reduce muzzle blast by reducing and controlling the energy level of the propellant gases accompanying the projectile as it leaves the muzzle end of the weapon, and are typically located sufficiently forward of the muzzle end of the weapon that they can also operate effectively as a flash hider (e.g., a muzzle flash suppressor). However, for reasons of shooting accuracy, among others, suppressors typically require some mechanism for reliably mounting the suppressor to the muzzle end of the barrel of the firearm in such a way that the internal lumen of the suppressor is precisely aligned coaxially with the bore of the barrel.
Accordingly, a long-felt but as yet unsatisfied need exists in the industry for firearm attachments that can operate effectively not only to reduce or eliminate both muzzle flash and muzzle climb, i.e., as both flash hiders and muzzle brakes, but which can also be used to mount accessories, such as sound suppressors or blank firing adapters, to firearms precisely and reliably.
In accordance with the present disclosure, example embodiments of novel firearm attachments are provided, together with related methods, which operate effectively to reduce or eliminate both muzzle flash and muzzle climb, and which can also be used to mount accessories, such as sound suppressors or blank firing adapters, to firearms precisely and reliably.
In one example embodiment, a firearm attachment includes a base adapted to couple to a muzzle end of a barrel of a firearm; a plurality of longitudinal tines that extend forward from the base; wherein the base includes a plurality of apertures disposed rearward of the tines and that extend from a bore within the base through an outer circumfery of the firearm attachment; wherein the apertures exhibit a first diameter at the bore and a second larger diameter at the outer circumfery; and wherein the apertures are adapted to impart thrust to the firearm attachment in response to combustion gases passed from the bore through the apertures to compensate for muzzle rise associated with the firearm.
In another example embodiment, a method includes providing a firearm attachment comprising: a base coupled to a muzzle end of a barrel of a firearm, a plurality of longitudinal tines that extend forward from the base, wherein the base includes a plurality of apertures disposed rearward of the tines and that extend from a bore within the base through an outer circumfery of the attachment, and wherein the apertures exhibit a first diameter at the bore and a second larger diameter at the outer circumfery; and passing combustion gases of the firearm from the bore through the apertures to impart thrust to the attachment to compensate for muzzle rise associated with the firearm.
The scope of the invention is defined by the claims, which are incorporated into this section by reference. A more complete understanding of the firearm attachments of the present invention will be afforded to those skilled in the art, as well as a realization of additional advantages thereof, by a consideration of the following detailed description of one or more example embodiments thereof. Reference will be made to the appended sheets of drawings, the figures of which will first be described briefly, and within which like reference numerals are used to identify like elements illustrated in one or more of the figures.
In accordance with the present disclosure, example embodiments of novel firearm attachments are provided, together with methods for making and using them, which can operate effectively to reduce or eliminate both muzzle flash and muzzle climb, and which can also be used to mount accessories, such as sound suppressors or blank firing adapters, to firearms in a precise and reliable manner.
As illustrated in
In the particular example embodiment illustrated in
In various embodiments, the circumferential surface of the firearm attachment 100 can be adapted to be inserted into a complementary socket disposed in the suppressor 104, as illustrated in
Two example embodiments of such firearm attachments 200 and 300 are illustrated in
As may be seen from a comparison of the two sets of figures, the two attachments 200 and 300, which are respectively configured to mount to firearms of two different calibers, are similar in configuration, and differ mainly in the dimensions and arrangements of their respective features. In particular, the example attachment 200 is calibrated to mount to a rifle 102 firing a 5.56×45 mm NATO cartridge, whereas, the attachment 300 is adapted to a rifle 102 firing a cartridge corresponding to the larger 7.62×51 mm cartridge previously used by NATO forces. However, as discussed above, it should be understood that the attachments 200 and 300 can also be calibrated and configured to operate with a wide variety of other firearm types and calibers. Accordingly, although the following description is presented in the context of the example attachment 200, the description is, except where specific differences are noted, likewise applicable to the example attachment 300.
The example firearm attachments 200/300 can be seen to include a base 202/302 adapted to be coupled to a muzzle end of the barrel of a firearm, a bore 204/304 that is concentric with a central axis 206/306 of the attachment 200/300, and three substantially longitudinal tines 208/308 extending forwardly from the base 202/302 and arranged circumferentially around the central axis 206/306. The tines 208/308 have generally planar sidewalls 210/310 and the opposing sidewalls 210/310 of adjacent ones of the tines 208/308 define three longitudinal slots 212/312 that extend rearwardly from the front of the attachment 200/300 to the base 202/302, and which are adapted to exhaust combustion gases from the bore 204/304 when a firearm to which the attachment 200/300 is mounted is discharged (e.g., cycled).
The tines 208/308 and at least a front portion of the base 202/302 can be adapted to be inserted into a complementary socket of a firearm sound suppressor 104, and a rear portion of the base 202/302 can comprise, for example, a frusto-conical external surface that defines a plug 226/326 configured to be received in a slide-in engagement with a complementary socket in the suppressor 104. The plug 226/326 can include a tab 228/328 extending therefrom, the tab 228/328 being adapted to be received by a corresponding slot disposed in the interior surface of the socket of the suppressor so as to rotationally align the sound suppressor relative to the firearm. The tab 228/328 can extend longitudinally along the base 202/302 and can be chamfered for a slide-in engagement within a complementary inclined recess disposed in the socket of the suppressor.
While the attachment features described thus far enable the attachments 200 and 300 to operate effectively as both flash hiders and as mechanisms for coupling a sound suppressor to a firearm, it can be desirable in a number of applications for the attachment to operate as a muzzle brake or a recoil compensator. In particular, it is desirable, for reasons of weapon accuracy, to provide firearm attachments with features that enable them to effectively suppress or eliminate muzzle climb or muzzle rise after firing or cycling of the weapon, particularly during rapid or automatic firing of the weapon.
The two example firearm attachments 200 and 300 described herein address the muzzle climb problem in the context of two possible firing scenarios. The first of these relates to a situation in which the shooter is firing a weapon “freestyle,” i.e., without any support of the weapon other than, e.g., a sling. The second relates to a situation in which the shooter is firing a weapon that is supported by, e.g., a so-called “bipod,” i.e., a collapsible support stand forming a V, the apex of which is typically coupled to the forward end portion of the weapon's barrel, and two legs, each having a lower end disposed in contact with a fixed surface, for example, the ground.
In the first scenario, the muzzle of the weapon has a tendency, after firing, to rotate upwards relative to the horizontal, and either to the right or to the left relative to the shooter, depending on whether the shooter is right-handed or left-handed, respectively. In the second scenario, the muzzle tends only to rise vertically, since contact of the legs of the bipod support with the ground effectively prevent the muzzle from pulling right or left, and accordingly, the chirality of the shooter becomes relatively unimportant. The first example firearm attachment 200 of
More particularly, the base 202 of the first example attachment 200 includes a plurality of first apertures 230 that are disposed rearward of the longitudinal tines 208 and slots 212, and that extend into the bore 204 from an upper surface of the outer circumfery of the attachment 200, as well as a plurality of second apertures 232 that are disposed rearward of the longitudinal tines 208 and slots 212, and that extend into the bore 204 from a right or a left side surface of the outer circumfery of the attachment 200.
As illustrated in, e.g., the enlarged partial cross-sectional view of
As those of some skill will recognize, the configuration of the top and side surface apertures 230 and 232 providing a nozzle substantially similar to that of a rocket nozzle, in which the bore 204 of the attachment 200 corresponds to a “combustion chamber” of the nozzle, the cylindrical section 234 to a “throat” of the nozzle, and the frusto-conical section 236 to a “bell” or expansion section of the nozzle. Thus, in operation, the high-temperature, high-pressure gases generated by a burning propellant during the firing of an associated firearm enter the bore 204, accelerate to sonic velocities as they pass through the constriction of the throat, or cylindrical section 234 of the nozzle, then expand rapidly through the bell, or frusto-conical section 236 of the nozzle, causing the gases to accelerate to supersonic velocities and to cool, or drop substantially in temperature.
The acceleration of the combustion gases through the apertures 230 and 232 results in a thrust being imparted to the attachment 200, and hence, to the muzzle end of the barrel of the firearm to which it is attached, that is in a direction opposite to that of the flow of the gases through the apertures. Accordingly, the first apertures 230 disposed on the upper surface of the attachment 200 serve to compensate for (e.g., offset or eliminate) the tendency of the muzzle to climb or rise after firing, whereas, the second apertures 232 disposed on either the right or left side surface of the attachment 200 serve to offset or eliminate the tendency of the muzzle to pull to the right or to the left, respectively, after firing. Thus, as above, if the shooter is right-handed, then the second apertures 232 should be disposed on the right side of the attachment 200 to compensate for a right-hand pull, and if the shooter is left-handed, should be disposed on the left side of the attachment 200, to compensate for a left-hand pull. The particular example attachment 200 of
In addition to the foregoing, the rapid expansion and accompanying cooling of the gasses in the apertures 230 and 232 results in a substantial reduction in any further combustion of the gases, and hence, muzzle flash exhibited at the outlets of the first and second apertures 230 and 232. Thus, experiments have shown that in embodiments incorporating the “muzzle braking” apertures 230/330 and/or 232, the addition of the apertures to the attachments 200 or 300 result in virtually no increase in the amount of visible muzzle flash during the firing of weapons to which the attachments 200 or 300 are coupled.
In the particular first example attachment 200 illustrated, the cylindrical sections 234 of the first and second apertures 230 and 232 have a diameter of about 0.062 inches, and their frusto-conical sections 236 subtend (e.g., taper) an angle α of about 40 degrees (see
The upper or first apertures 230 of the attachment 200 are distributed in an arc about the outer circumfery of the attachment 200. For example, apertures 230 are disposed symmetrically with respect to a sagittal plane of the attachment 200, i.e., to a vertical plane passing through the central axis 206 of the attachment 200. Further, the first apertures 230 are disposed in two circumferential rows of three evenly distributed apertures 230 each, e.g., are also disposed symmetrically with respect to a transverse plane passing perpendicularly through the attachment 200 and the central axis 206 thereof.
In the particular example attachment 200 illustrated, the side, or second apertures 232 are also distributed in an arc about the outer circumfery of the attachment 200. For example, apertures 232 are disposed symmetrically with respect to a coronal plane of the attachment, i.e., a horizontal plane passing through the central axis 206 of the attachment 200, and like the first apertures 230, can also be disposed in two rows of three evenly distributed apertures 232 each, e.g., such that they are likewise disposed symmetrical to a transverse plane passing perpendicularly through the central axis 206 of the attachment 200. However, as above, the number and arrangement of the first and/or the second apertures 230 and/or 232 can vary as appropriate for different applications.
In various embodiments, any of apertures 230/232 may be distributed (e.g., positioned) in an arc that comprises only a portion of the outer circumfery of the attachment 200 (e.g., less than one half of the outer circumfery) to impart thrust to attachment 200 in one or more desired directions. For example, by orienting attachment 200 in a manner such that apertures 230/232 are pointing upward and to the right (e.g., see
Similarly, by orienting attachment 200 in a manner such that apertures 230/232 are pointing upward and to the left (e.g., an approximately 90 degree counterclockwise rotation in relation to
In some embodiments, smaller arc distributions may be used (e.g., less than one third, less than one quarter, or other portions of the outer circumfery) to impart thrust in fewer and/or more specific directions (e.g., to selectively compensate for muzzle rise or muzzle pull).
In various embodiments, any of the arc distributions discussed in relation to apertures 230/232 may be used with any of the various apertures (e.g., apertures 230, 232, 330, 410, 425, 430, 450, 470) and/or attachments (e.g., attachments 100, 200, 300, 400, 420, 440, 460) of the present disclosure as desired to impart thrust to compensate for muzzle rise and/or muzzle pull.
In some embodiments, one or more of the first and/or the second apertures 230 and/or 232 can be disposed concentrically with respect to an axis 238 that is tilted forwardly at an acute angle γ relative to the central axis 206 of the attachment 200. As those of some skill will understand, this slight forward-tilt arrangement of the apertures 230 and/or 232 will result in a relatively small reduction of the forces available to react muzzle climb or right/left pull, but will also result in an advantageous and significant reduction in the amount of muzzle blast, debris, and particulate reaching the ears and faces of the shooter and persons disposed on either side of the shooter during weapon firing, as compared to embodiments in which the apertures 230 and/or 232 extend strictly in a radial direction. In the particular example attachment 200 illustrated, the acute angle γ is about 85 degrees, but as above, can vary.
The features of the second example firearm attachment 300 are similar to those of the first example attachment 200 above, except that, as discussed above, the second attachment 300 is directed to embodiments in which the weapons to which they are attached are equipped with bipods, which have the effect of substantially eliminating right/left movement of the weapons' muzzles during firing. Accordingly, in the second example embodiment 300, side or second apertures are omitted, and the muzzle brake apertures 330 are confined to a plurality of upper apertures 330 that are disposed rearward of the longitudinal tines 308 and slots 312, and that extend into the bore 304 from an upper surface of the outer circumfery of the attachment 300.
The configuration of the apertures 330 can be substantially similar to those of the first embodiment, except that in the second embodiment, which as above, can be directed to a larger caliber weapon, the diameter of the cylindrical sections 334 can be larger, e.g., 0.093 inches, to accommodate this difference, and this would result in the apertures 330 having correspondingly larger frusto-conical segments 336 (see
The apertures 330 of the second example attachment 300, like the first apertures 230 of the first example attachment 200 above, are distributed in an arc about the outer circumfery of the attachment 300. For example, apertures 330 are disposed symmetrically with respect to a sagittal plane of the attachment 300, and can comprise two circumferential rows of the apertures 330. However, in the particular example attachment illustrated in
A final difference between the first example firearm attachment 200 and the second example attachment 300 can relate to the optional forward tilt of one or more of the apertures 330. Thus, as illustrated in
Although particular aperture shapes and distributions have been discussed, others may be used. For example,
Accordingly, it will be understood that a wide variety of different shapes, distributions, and types of apertures are contemplated, any portions of which may be used in combination as desired for particular implementations.
Indeed, as those of some skill in this art will appreciate, and depending on the particular application at hand, many modifications, substitutions and variations can be made in and to the materials, apparatus, configurations and methods of use and production of the firearm attachments of the present disclosure without departing from the spirit and scope of the invention. In light of this, the scope of the present invention should not be limited to those of the particular embodiments illustrated and described herein, as they are merely by way of some examples thereof, but rather, should be fully commensurate with that of the claims appended hereafter and their functional equivalents.
This application claims priority to and the benefit of U.S. Provisional Patent Application No. 62/104,326 filed Jan. 16, 2015 and entitled “FIREARM ATTACHMENT” which is hereby incorporated by reference in its entirety.
Number | Date | Country | |
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62104326 | Jan 2015 | US |