The invention relates generally to firearms and firearm accessories, and more particular, the invention relates to muzzle devices such as muzzle brakes and compensators. The muzzle device may be permanently fixed or releasably attached to the firearm. The present invention may be used in any type of firearm.
Previous muzzle attachments employ an internal expansion chamber, i.e. a muzzle attachment with interior chambers that are significantly wider than the diameter of the central bore. These interior chambers allow propellant gases to expand within the muzzle attachment before being expelled from apertures on the external surface of the muzzle attachment. This causes the pressure of the propellant gas to lower, thereby reducing the flow rate as it is being redirected from the central bore. The benefits of minimizing recoil and improving accuracy through directed release of high pressure gas is thereby lost.
Prior art muzzle attachments may also have grub screws that may be used to adjust propellant gas release from the external apertures. However, such grub screws may reduce propellant gas release due to the absence of any additional vents within the grub screw structure. Such a loss may reduce the ability to precisely modulate the desired balance of propellant gas expulsion as well as reduce recoil compensation.
The present invention is of a muzzle device that is either permanently fixed or releasably attached to the end of the barrel of a firearm. It is conceivable that the muzzle device may also be used on a canon. The muzzle device may have a configuration that reduces the loss of pressure and flow rate of the propellant gas by employing a central bore having a substantially equal diameter to the bore of the barrel. The muzzle device may have a plurality of apertures that are rearwardly angled from the central bore of the muzzle device to the external surface of the muzzle device. External chamfers may be co-located with the apertures to enable the expelled gas to have directed expansion of the propellant gas such that additional pressure is exerted on the external surface of the muzzle device.
The present invention may further have tunable apertures that allow the expulsion of the propellant gas to be adjustably controlled. The apertures are configured to receive screws which may be screwed into the apertures at varying depths within the tunable apertures. The screws may have a hollowed interior portion that allows expulsion of propellant gas albeit less than when the screw is not inserted within the aperture.
The present invention is further directed to a muzzle device having an external diameter that is about equal to the diameter of the barrel. Approximately equal diameters allow the user to access to other components on the barrel of the firearm to be removed such as the gas block or barrel nut of the firearm. Such removal of these components would not necessitate the need to remove the muzzle device.
The novel features which are characteristic of the invention, both as to structure and method of operation thereof, together with further objects and advantages thereof, will be understood from the following description, considered in connection with the accompanying drawings, in which the preferred embodiment of the invention is illustrated by way of example. It is to be expressly understood, however, that the drawings are for the purpose of illustration and description only, and they are not intended as a definition of the limits of the invention.
The present invention may have an overall cylindrical configuration as shown in the exemplary embodiments in
In other embodiments, the attachment may have an overall hexagonal prism configuration or any other prismatic configurations with any number of expansion faces. The overall width of the hexagonal prism may be equal to near external diameter of the firearm's barrel so as not to impede access to the firearm components and other accessories.
The muzzle device may be composed of any suitable material(s) known to those skilled in the art. In one embodiment, the firearm accessory may be coated with aluminum titanium nitride.
One of the objects of the present invention is to expel the propellant gases in a directional manner through one or more apertures 4 of the muzzle device 2 located along the longitudinal axis of the muzzle device 2. The muzzle device 2 may have a central bore 6 having a smaller diameter than other previously designed muzzle devices known in the art. The smaller diameter may allow the propellant gases to be expelled at a greater pressure and velocity through the one or more apertures 4 than other previously designed muzzle devices having a larger diameter. In some preferred configurations, the diameter of the central bore may be approximately equal to the diameter of the bore of the barrel of the firearm.
The muzzle device 2 may have at least one aperture 4 with a smaller diameter aperture than the diameter of the central bore 6. Such a preferred configuration may further increase the gas pressure and velocity through such an aperture 4. In one exemplary embodiment, the aperture may have a diameter of 3/16 of an inch. The central bore diameter of the device may not be substantially greater than the inner diameter of the central bore of the barrel. The longitudinal axis F of the aperture 4 may be configured at any angle relative to the longitudinal axis E of the central bore: perpendicular or at angles that are forwardly slanted or rearwardly slanted. Another example as shown in
The apertures 4 of the muzzle device 2 may be uniform in diameter of internal opening 10 (i.e. entry point of the propellant gas) and external opening 12, or the openings may vary in diameter, or increase in diameter from one end of the muzzle device to another. In one preferred embodiment, the diameter of internal opening of the aperture is smaller than the external opening of the aperture where the diameter stochastically increases. The walls of the apertures may form cylinder or form an overall frustum or conical shape. The aperture(s) may also have varying diameters or multiple different angles throughout its length.
The muzzle device 2 may have one or more supplementary apertures 14 which may be used to increase the expulsion of gas and/or have additional functions. For instance, there may be a higher concentration of apertures including a supplementary aperture on any region of the device which would maximize the venting surface area for such a region. Additional apertures located at a region on the muzzle device may reduce the pressure. In one embodiment, the additional apertures near the distal end 16 may be used to further reduce the recoil impulse before the projectile exits the muzzle device 2. These supplementary apertures may be extending generally rearwardly, forwardly, or perpendicularly relative to the central bore. Supplementary apertures may be configured to have a smaller diameter than the central bore of the muzzle device.
In one embodiment, the supplementary aperture may have a dual function. In one embodiment, the supplementary aperture 14 may serve as a slot 26 for an installation tool 18 for attaching the muzzle device 2 to a firearm. An exemplary embodiment in
In an alternate embodiment, an installation tool may have at least one shaft that is screwed into an aperture of the muzzle device. The installation tool shaft and the aperture of the muzzle device would have compatible threading to allow shaft and aperture to interface and create a sufficiently stable contact so that the installation tool may be used to attach the muzzle device to the end of the barrel.
Another exemplary embodiment in
In another preferred embodiment, the front end of the muzzle device may have additional distal vents at the distal end the muzzle device in combination with having four supplementary apertures at the proximal end. See
A preferred embodiment includes apertures or supplementary apertures may be threaded within the internal walls. Threading may be used to insert screws such as a grub screw. The screws may be used to modify the nature of how the propellant gas is expelled based on the depth in which the screws are located within the apertures and the number of screws inserted into the apertures of the muzzle device. The screws may allow venting by having a hollowed interior portion. The use of inserted vented screws allows the apertures to bleed propellant gases at a slower overall flow rate thus restricting the flow that the aperture without the insertion of the screw. The dimensions of the hollow interior portions within the vented screws may vary which further provide an additional level of fine tuning of recoil characteristics. The hollowed portions 32 of the vented screw 30 may have any three-dimensional shape such as a hexagonal prism as shown in
In one preferred embodiment, supplementary apertures 14 may be configured perpendicular to the central bore 6 and allow for the insertion of vented screws 30. In one preferred example, a set of four supplementary apertures 14 and four vented screws 30 may be located near the proximal end 8 of the muzzle device 2. The supplemental apertures 14 may be spaced equally from each other such that four apertures forms a cross configuration. The user may then insert the vented screws 30 and adjust the depth for fine tuning the directional flow of the propellant gas. Supplementary apertures used in combination with the vented screws may vary in the number, spacing, and the aperture diameter and screw configuration.
The hollow interior portion of the vented screw may be also used to insert an installation tool shaft through one or more alighted vented screws. In the alternate, the vented screws may have threading on the walls of the hollow interior portion that may interface with the threading on the shaft of an installation tool. Once the installation tool shaft is inserted into the center opening of the vented screw, the installation tool may be used to screw on or aid in the attachment of the muzzle device to the end of the barrel.
Any of the apertures or supplementary apertures of the muzzle device may have external chamfered portions located at the external end of the aperture. The external chamfered portion 34 may be configured to be concave. The external chamfered portions may extend to any partial depth of the external surface of the muzzle device. The external chamfered portions may be configured to control the expansion of the propellant gas as it is expelled through the aperture. In one exemplary embodiment, the relative position of the aperture 4 within the external chamfered portion 34 may enable the gas to expand in a directional manner. Further to this embodiment, a concave chamfered region 34 may generally have a contour akin to a portion of an ellipsoid. The aperture 4 may be located at the forward portion of each external chamfered region 34 such that the longitudinal axis of the aperture extends rearwardly from the central bore 6 to external chamfered region 34. In other embodiments, the aperture may be located at any location in the external chamfered region. The concave region may have a contour or perimeter shape such as any three-dimensional polygon. The external chamfered portions may be configured as grooves or valleys etched into the surface of the contour. In one embodiment, the external chamfered portions 34 are made with a standardized 15/32 inch 118° drill bit.
The apertures 4 of the present invention may be in any pattern. In one embodiment, the ports may be positioned in rows along the longitudinal axis of the muzzle device. The apertures may be positioned in an alternating pattern. In other embodiments, the apertures may be denser in certain regions than others or may form any intricate pattern. For example, there may be more apertures, i.e. apertures 4 and distal vents 44, at the distal end 16 of the muzzle device 2 as shown in
The proximal end of the muzzle device may have an attachment mechanism when used as an accessory to the firearm. This attachment mechanism may employ the use of a chamfer which may be used as a quick detach (“QD”) recess 36 as shown in
The distal end of the muzzle device may have a portion that also allows for attachment of accessory components. The distal end may have an indexing chamfer for QD attachments, threading or any other means of attachment known in the art. Such attachments may include suppressors, flash suppressors, linear brake, blast diffuser, blast redirector, mechanical counter-recoil systems, or any other attachment known to one skilled in the art.
The muzzle device may be constructed by standardized tooling or any other methods known to those skilled in the art.
While the specification describes particular embodiments of the present invention, those of ordinary skill can devise variations of the present invention without departing from the inventive concept.
Number | Date | Country | |
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62571139 | Oct 2017 | US |