HU227243B1 - Gun compensator - Google Patents

Abstract

The compensator includes an attachment unit that is connected to the end of a barrel of a firearm. A longitudinal through hole extends along the longitudinal axis of the compensator. Radial gas discharging openings orthogonal to the longitudinal axis and gas driving openings obliquely formed at an angle, a, relative to the longitudinal axis are connected to the longitudinal through hole for discharging gases and are formed in the cylindrical compensator body. The gas discharging and driving openings are formed symmetrically around a circular curve by an angle, b.

Description

The length of the description is 8 pages (including 3 pages)

HU 227 243 Β1

The present invention relates to a weapon compensator for reducing back and up movement of firearms and increasing the safety of targeting.

In recent years, there has been a marked increase in the demand for firearms that will surely overcome both near and far targets. The problem with the use of firearms due to the physics of the firearm is that the firearm moves back and up significantly when fired. This effect is important for the accuracy of the firearm and the safety of the shot, as well as for the rapid repetition of the shot, as the movement of the barrel of the weapon greatly reduces accuracy. From a repetition point of view, resetting the shot to its original position and finding the target again is a serious problem. This effect also applies to small arms, pistols, precision firearms, as well as military and hunting weapons.

According to the state of the art, various solutions to the above-mentioned problem are used in modern weapons, the common feature of which is to use the effect of the gas discharged from the firearm after the explosion to reduce the "kickback" and displacement of the weapon. For this purpose, a so-called muzzle brake, also known as a compensator, is used at the end of the barrel of the firearm, which utilizes the action of the outgoing gases by means of apertures and surfaces formed thereon. Almost all of the larger arms companies also deal with the development of compensators, including Remington, Sauer, Weatherby, Sako, and, in practice, the weapons they produce are these solutions.

Most conventional arms manufacturers also produce compensators, such as Remington, Sauer, Weatherby, Sako. There are many new companies on the Internet, such as BP Technology at www.bp-tec.com. The effectiveness of damping commercially available compensators, when measured specifically, is up to 35-45% according to the manufacturer's recommendations. The main limiting factor for increasing efficiency is that the outgoing gases are diverted in the wrong direction so that the kinetic energy of the gas is not properly utilized.

Prior art US 2005039370 discloses a weapon compensator. It is a feature of the solution described herein that the expansion joints are provided with relatively narrow gas passage holes in which, however, the exhaust flue gas may be deposited after repeated use, which may impair the efficiency of the expansion joint and may deflect the projectile itself. This solution can only be used for small series shots, as it cannot be used for long periods without gun cleaning due to clogging.

U.S. Pat. No. 4,351,223 discloses pipe-mouth brakes. The solution described herein is characterized by attaching to the barrel of the weapon an attachment with lateral apertures, which is secured by a screw. In this case, the openings only distribute the gases, but their braking effect is not sufficiently used. In the solution, lateral outflow gases reduce weapon recoil but do not sufficiently utilize the braking effect of the gas.

The tube-brake system described in US2003154849 includes a plurality of lateral holes. The holes are formed laterally perpendicular to the barrel of the weapon, so that the gases discharged after the explosion reduce the impact of the weapon, but are not utilized to the extent that the repulsive effect is reduced.

Disadvantages of the known solutions: The disadvantages of the compensator solutions known in the art and used in practice are the following:

- The problem with several types of compensators is that, while reducing recoil, they also increase the standard deviation of the weapon, which is disadvantageous in most applications, but especially in racing.

- Another disadvantage of compensators is that the braking effect is inadequate, ie the recoil weapon bounces on the body and face of the person using the weapon, thereby endangering physical integrity and possibly causing injury. Inadequate braking affects the movement of the gun barrel, which also reduces the accuracy of the shot.

In practical applications of firearms, practical experience has shown, without exception, that insufficient attention has been paid to the use of the energy of the return gases, so that the repulsion of the weapons was considerable, even with the best solutions. At the moment, the best is the muzzle brake used on SAKO TRG and Weatherby guns, but we still see significant improvement in braking performance.

The object of the present invention has been to provide a solution for significantly reducing back and up movement of the firearms, further increasing the safety of the targeting and providing a quick successive accurate shot.

In the process of the present invention, it has been discovered that when blasting gases are deflected at the end of the weapon not only laterally but also backwards at an appropriate angle, length, and diameter, the outgoing gases move the weapon against kickback using the rocket principle. Apertures in the right direction also compensate for the upward movement of the barrel of the weapon by the action of the gases, which greatly increases the accuracy and safety of the target and the rate at which it repeats, thereby achieving the target.

Accordingly, the invention relates to a weapon compensator having a connector 2 attached to the end of a firearm barrel

EN 227 243 át1, and has a longitudinal through hole located along the longitudinal axis of the compensator and openings for gas outflow connected to the longitudinal through hole. The solution is characterized in that the gas outlet openings radially formed perpendicular to the longitudinal axis in the cylindrical body of the compensator and the gas deflection openings in the axial direction are formed, and the gas outlet openings and the one in the open space they are arranged asymmetrically along an arc.

In a preferred embodiment of the compensator according to the invention, the angle of the obliquely formed gas deflection apertures is = 25-35 °, preferably 30 °.

In another preferred embodiment of the compensator according to the invention, the number of gas outlets and obliquely formed gas deflection apertures is one to three, preferably five, and the lower surface of the compensator is closed and the angle β is 40 ° to 120 °. °, preferably 60 °.

In a further preferred embodiment of the compensator according to the invention, the gas outlet openings (5) are arranged in a row, along a circular arc, at the end closest to the threaded connection portion (4) of the compensator (1).

In a further preferred embodiment of the compensator according to the invention, the obliquely formed gas deflection apertures (6) are located at two ends, preferably four rows, along four circular arcs close to the outlet of the compensator (1).

In a further preferred embodiment of the compensator according to the invention, depending on the field of application, it is made of a special plastic, for example kevlar or metal, optionally high tensile steel, titanium, aluminum-titanium alloy.

The present invention will now be described with reference to the accompanying drawings in which:

Figure 1 is a longitudinal sectional view of the invention.

Figure 2 is a longitudinal perspective view of an embodiment of the present invention.

Figure 3 is an axial view of the embodiment of the present invention from the threaded connection portion in Figure D-D of Figure 1.

Figure 4 is a cross-sectional view of the solution of the present invention in section A-A of Figure 2.

Figure 5 is a cross-sectional view of the embodiment of the invention in section B-B of Figure 2.

Fig. 1 is a longitudinal sectional view of the cylindrical body of the compensator 1 according to the invention with a through hole 3 in the center and a threaded connection part 4 at one end of the body 2. At the other end of the body 2, an outlet opening 7 is provided, optionally with a funnel-shaped chamfer. In the cylindrical body 2 there are formed gas outlet openings 5 perpendicular to the through hole 3, as well as oblique angled gas outlet openings 6. By means of a threaded connector 4 formed at one end of the body 2, the compensator according to the invention is connected to the end of the barrel of the weapon. This threaded configuration ensures, on the one hand, that the axis of the gun barrel and the compensator's inner cavity are completely in one axis. The thread further ensures that the positions of the openings of the compensator at the end of the barrel of the weapon are fixed and stable relative to the structure of the weapon.

When the weapon is fired, the gas flowing behind the ammunition first reaches the perpendicularly shaped gas outlet 5 of the compensator 1 and flows therefrom around the end of the weapon to form a circular gas cloud of asymmetric structure. This is because the gas outlet openings 5 are formed perpendicular to the compensator shaft 1 so that there is no opening below, so that the gases flowing out of the gas outlet openings 5 push the end of the gun barrel down.

As the gas flowing behind the ammunition reaches the oblique gas deflector openings 6, it flows backward relative to the end of the weapon. The gas thus discharged, by virtue of the reactive principle, exerts a propelling effect on the barrel of the weapon, which propels the rearward movement of the weapon body upon firing. The gas guide apertures 6, arranged in succession in four rows, hold the rearward-moving weapon in four strokes and reduce its rearward movement in four strokes. The position of the gas deflection apertures 6 is also asymmetric with respect to the axis of the weapon, so that as the gas moves the weapon, it also pushes its end downward due to apertures in the upper row and unimproved apertures. Thus, the compensator of the present invention effectively reduces both the upward movement and the rearward stroke of the weapon.

Figure 2 is a longitudinal perspective view of an embodiment of the present invention. As shown in the figure, the outer shape of the compensator 1 according to the invention is preferably cylindrical with a threaded connection portion 4 attached to the barrel of the weapon, with a cut depending on the diameter of the barrel, with an outlet 7 as desired. The degree of trimming is determined by the allowable weight and other parameters of the compensator 1. The outside shows the perpendicularly formed gas outlet apertures 5 and the oblique angled gas deflector apertures 6 which are arranged in a straight line parallel to the longitudinal axis of the compensator 1. The figure shows the intersection plane B-B of the gas outlet openings 5 and the intersection plane A-A of the gas outlet openings 6.

Figure 3 is an axial view of the embodiment of the present invention from the threaded connector portion in D-D view of Figure 1; The figure shows the cylindrical body 2 of the compensator 1, in which the threaded connection part 4 and the through hole 3 are concentricly formed with the body 2. The figure shows the C-C section of the compensator 1 shown in Figure 1.

Figure 4 is a sectional view perpendicular to the axis of the present invention;

HU 227 243 Β1 ben. The figure shows a partially sectional view and a sectional view of the obliquely formed gas deflection apertures 6 which are connected to the longitudinal through hole 3. The inner surface of the gas deflector apertures 6 each forms a funnel-like configuration which forms the stop surface of the return gases. Due to the etching, this support surface provides a colliding support surface when the gases are reversed, because the outgoing gas is already in direct contact with these surfaces. The asymmetrical positioning of the gas deflection openings 6 contributes to the downward displacement effect.

Figure 5 is a cross-sectional view of the embodiment of the invention in section B-B of Figure 2. The figure shows a sectional view of the formed gas outlet openings 5 perpendicular to the axis and also connected to the longitudinal through hole 3. The gas deflection apertures 5 extend radially from the center of the compensator 1 at an angle β to the symmetry axis of the compensator 1. The gas curtain flowing out of the gas deflection apertures 5 moves, pushes down the end of the barrel of the weapon in the opposite way to the kicking of the compensator 1, as described above.

In a preferred embodiment of the present invention, the device dimensions are:

overall length: 80-110 mm, preferably 90 mm, internal hole diameter: 10-13 mm, preferably 13 mm, outer diameter: arbitrary, depending on diameter and length of barrel, or allowable weight of compensator, typical diameter: 20-30 mm, preferably 25 mm.

The size of the rear 4-threaded connection to the pipe mouth: optional, also depends on the pipe diameter.

Positioning of the gas deflection openings: a = tilting backwards between 25-30 degrees, width of the deflection openings 6, 11 mm, diameter mm, positioning of the gas outlets 5: 90 degrees perpendicular to the axis, size of the 5 gas outlets: 4 mm-5 mm diameter.

The specific dimensions depend on the type of weapon, type of ammunition, barrel diameter, barrel length, and the effect desired.

The outer shape design is arbitrary, preferably at the outlet, the body 2 is cut off.

Material: special plastic, eg Kevlar or metal, high tensile steel, titanium, aluminum-titanium alloy, depending on the application.

Weight: 5-20 grams, depending on the application and purpose.

The diameter of the connecting thread at the connecting part 4 is arbitrary, depending on the diameter of the barrel of the weapon, preferably 12-13 mm.

In a preferred embodiment of the present invention, a rotary body having a suitable outer and inner diameter can be mounted on the mouth of the firearm barrel. Mounted directly in front of the mouth of the barrel, so-called cross holes are provided where, when the projectile leaves the mouth, some of the projectile firing gas forms a "gas-curtain", blowing radially. Most of the additional gas flowing forward in the direction of the tube axis is discharged sideways in collision with the surfaces of the expander, which is milled at an appropriate angle. (With a 28mm outer diameter and a 13mm inner diameter, the deflector faces are 1500mm ^2. ) The force resulting from the reversal of the high-pressure shotgun gas flowing out of the barrel thus pushes the barrel forward and downward. As a result, it reduces the so-called kickback of the weapon by about 55%. At least as big an advantage for shooters is the fact that the weapon shifts off target after the shot. The latter is confirmed by the scattering images obtained by rapid repetition or continuous shooting. A further function of the gas curtain formed by the gas exiting through the perpendicularly formed gas outlet openings 5 is that the gas exiting reduces the acoustic and gas load on the shooter.

Advantageous features of the solution: the gas outlet openings 5 are arranged asymmetrically perpendicular to the axis. The gas deflection openings 6 are inclined obliquely at an angle of u = 25-35 °, preferably 30 °. The gas deflection openings 6 have the same diameter and this results in a continuously decreasing shell thickness. This is important so that the outgoing gas touches the largest part of the inside of the compensator, which makes the most of the reactive principle.

It is important for the design of the funnel-shaped outlet 7 that its length is larger than the size of the projectile, which prevents the harmful turbulence of the outgoing gases.

Advantages and uses of the invention:

advantageous for all applications where high precision is important. such as sport shooting, precision, sniper and hunting weapons, and military small arms. The experience gained during development and pre-testing largely confirms the significant increase in efficiency and targeting accuracy. It is expected that with the full development of the prototype this can be further enhanced. Shooting exercises have shown that the present invention reduces both the physical strain of the shooters and improves their spray pattern, thus increasing the accuracy of the hit.

Further possibilities for expansion of the expansion joint: the mass problems of the expansion joints made of steel can be eliminated in one fell swoop by the use of high-strength heat-resistant plastics, such as kevlar, which also involves the testing of variants made under different fluid conditions. Compliant plastic can be developed into low-weight expansion joints with enormous baffles, expanding their applicability; they can be used with both small and large caliber weapons with good efficiency.

Claims (6)

PATENT CLAIMS A weapon compensator having a connection portion connected to the end of a firearm barrel and a longitudinal through hole arranged along the longitudinal axis of the compensator, and openings connected to the longitudinal through hole for gas outflow, characterized in that the cylindrical body (2) gas outlet openings (5) connected to a through hole (3) and radially formed perpendicular to the longitudinal axis, and gas deflection openings (6) axially inclined at an angle, and gas outlets (5) and obliquely formed gas deflection openings (6) are arranged asymmetrically along an arc at an angle. Compensator according to Claim 1, characterized in that the angularly formed gas deflection openings (6) have an angle α = 25-35 °, preferably 30 °. Compensator according to Claim 1 or 2, characterized in that the number of gas outlet openings (5) and obliquely formed gas deflection openings (6) is three to six, preferably five, and that the compensator (6) is arranged along the arc. 1) its lower surface is closed and the angle β is 40 ° to 120 °, preferably 60 °. 4. Compensator according to any one of claims 1 to 3, characterized in that the gas outlet openings (5) are arranged in a row, along a circular arc, at the end closest to the threaded connection portion (4) of the compensator (1). 5. Compensator according to any one of claims 1 to 4, characterized in that the obliquely formed gas deflection apertures (6) are provided at two to six, preferably four rows, along four circular arcs near the outlet of the compensator (1). 6. Compensator according to any one of claims 1 to 3, characterized in that it is made of a special plastic, for example Kevlar or metal, optionally a high-tensile steel, titanium, aluminum-titanium alloy, depending on the field of application.