RU2602867C2 - Pneumatic arms of self-defense, blade and cast elements - Google Patents

Abstract

FIELD: weapons and ammunition.

SUBSTANCE: invention relates to pneumatic arms of self-defense. Pneumatic arms of self-defense consists of durable handle. Handle contains two gas charging cavities, rear plugs of cavities with filling valves, trigger element with preventer, as well as blade. Trigger element interacts with propellant element, which is hydraulically extra-balanced towards exit from said handle. Single trigger element interacts simultaneously with two cast elements. Blade is made in form of elongated flat knife or dagger, pointed at front with cutting edges and shank. At beginning of blade plane at least one elongated through hole is made. Cast element consists of elongated cylindrical case with penetrating tip. Cast element has inner charging gas chamber, and on its rear generatrix of the cylindrical surface holes are made. In another version, near rear end of cast element circular ledge is made with diameter larger than cylindrical case.

EFFECT: higher efficiency of arms of self-defense is achieved.

11 cl, 9 dwg

Description

FIELD OF THE INVENTION

The invention relates to pneumatic self-defense weapons, shooting knives, portable shooting devices.

State of the art

Known shooting knives that use compressed energy to shoot gas, such as a pneumatic shooting knife, described in the magazine "Master Gun", 27/28 for 1998

In a knife of this design, the piston located in the cavity of the handle has a small piston cavity filled with compressed air, pumped from the outside of the knife by a compressor, or using a cylinder of compressed gas through a charging check valve. The piston interacts with a missile projectile, which is a short arrow. An arrow inserted into the end of the knife handle is fixed in the knife handle using a lever system with a combat stop. Then, air from the compressor is pumped into the piston cavity.

When fired by pressing the thumb on the shutter button, which is part of a system of levers that reduce the pulling force, the combat cock will unlock, releasing the arrow, and the gas compressed in the piston cavity, expanding, will throw the arrow at the target. The knife of this design can be used both on land and under water.

The disadvantage of a knife of this design is the insignificant charging pressure of the compressed gas to fill the piston cavity before firing.

The possible maximum pressure of the compressed gas is limited by the gear ratios of the lever system with a combat stop. When the pressure of compressed gas is increased to increase the “muzzle energy”, the descent force increases so much that the efforts of the thumb are simply not enough to remove the arrow from the combat platoon and, accordingly, firing the shot. With a piston diameter of about 20 mm indicated on the scale of the picture (“Master Gun” 27/28 for 1998), the force acting through the piston on the trigger system will be about 785 kg, at a charging pressure of 250 atm. Overcoming such efforts with the muscular effort of the thumb, even through a system of levers, is physically impossible.

The disadvantage of the knife is also unnatural for the production of a shot, the position of the knife with the blade towards the user. Even with the pneumatic method of throwing, the recoil during firing due to the considerable weight of the boom (even at its insignificant speed) can reach such a value that when firing, the knife (for example, under water, due to “water lubrication”) cannot be held by hand, and the knife a shot with some speed attached recoil will hit the user himself with the sharp end of the blade. In addition, such an unnatural position of the knife during firing increases the time it takes to move the knife from the “cold weapon” position to the “throwing pneumatic weapon” position, which can lead to a fall or even loss of the knife (for example, under water), and when there is not enough time ( to transfer from one position to another) to the inability to have time to fire a shot. A disadvantage of a knife of a similar design is also the inability to fire a second shot in the case of, for example, a miss or a fight with a group of opponents.

The main disadvantage of a knife of this design, therefore, is the low throwing energy of the striking arrow, the inability to fire a second shot, the danger of being used in an unnatural position for a shot, and the inconvenience of moving the knife from the "cold weapon" position to the "throwing air weapon" position.

As a prototype of the selected shooting device according to the patent of the Russian Federation No. 2420701.

The firing device consists of a metal handle containing two gas charging cavities, charging valves contained in the rear plugs of the charging cavities, trigger elements interacting with the throwing elements, and the throwing elements are hydraulically balanced or rebalanced towards the throwing from the handle of the throwing element. The main disadvantages of a firing device or firing knife are:

1. The inability to make two shots in a row without changing the orientation of the handle in the hand. For firing two shots, you must first press the trigger on one side of the handle of the weapon, and then, turning it 180 °, press the trigger on the other side of the handle of the weapon. In this case, you must first remove the two trigger elements from their own fuses. Such an operation, with sufficient skill, can be performed with one hand, but with a gloved hand and underwater, it is extremely difficult to make such an operation quickly and without dropping the weapon from the hand when turning over. In addition, such an operation involving removing from two fuses and turning over takes a lot of time, therefore, if necessary, two shots with a short interval between them cannot be made in principle.

2. Small volumes of the charging cavity, due to the fact that the internal volume of the missile elements is not used in any way. In this case, the external dimensions of the handle of the weapon for any caliber of the missile elements cannot be more than the ergonomic norm of sizes convenient for holding by the human hand. At the same time, the muzzle energy with a constant volume of the handle (i.e., the acceleration part of the missile elements) of the proposed weapon depends only on the maximum gas pressure at the end of the acceleration section and the cross-sectional area of the missile element on the acceleration section. If you do not use the internal volume of the missile element, a contradiction arises, namely, with an increase in the caliber of the missile element (i.e. its cross-sectional area) with a constant size of the handle of the weapon, the volume of the charging cavity decreases (that is, the internal volume between the diameter of the charging cavity and the diameter of the missile element) . As a result, the maximum gas pressure at the end of the acceleration section does not increase, which is necessary to increase the energy of the shot, but rather decreases, so increasing the caliber does not increase the muzzle energy, and with a certain ratio of the diameter of the charging cavity and the diameter of the missile element begins to decrease it. An increase in the initial charge pressure is impossible both because of the constant strength of the wall of the charge cavity, and from the lack of relatively free technical access to pressures above 300-350 atm. The caliber of the prototype is only 6 mm.

3. The inability to obtain an accurate (heap) shot with a missile element in a weapon with a blade installed (option shooting knife). When fired, the missile element, while moving along the blade, maintains a rectilinear movement only until the missile element completely leaves the guide channels of the handle. As soon as the end of the missile element exits the guide channel, the gas exiting the channel creates a pressure gradient in the wall layer between the blade of the knife and the missile element and the atmosphere and the missile element. The pressure in the wall layer acts on the posterior end of the missile element, deflecting it towards the atmosphere. The missile element always starts flying toward the target at an angle and with the possibility of further increasing this angle, which ultimately leads to the missile element entering the target with a side surface, and not with a pointed tip.

A similar in appearance design of the blade of the proposed weapon has a blade of a shooting knife according to the patent of the Russian Federation No. 2246678. However, the holes in the muzzle of the blade, made in this patent, are needed only for visual control of weapons “charged - not charged” and for the expiration of gas bubbles when fired in water away from the line of sight of the target, that is, they are not related to the achieved goal of the invention.

US Pat. No. 7,331,108 describes a knife for underwater swimmers intended for dynamic pressurization of underwater targets, which has a liquefied carbon dioxide cylinder in its handle, an exhaust valve controlled by the thumb of a hand, and a blade (blade) with a channel along its length almost to the end of the blade. The disadvantage of this knife is that the maximum boost pressure during the evaporation of carbon dioxide at normal temperature does not exceed 60 atm, which accordingly makes it impossible to exert a dynamic pressure impact on the target above the specified value. The knife according to US patent No. 7331108 has only one charge of gas for dynamic pressurization and generally has no shooting function, that is, it is not a firing weapon.

Disclosure of invention

The aim of the invention is to eliminate the disadvantages of the prototype, the creation of pneumatic weapons of self-defense, easily controlled with one hand, increased to 8 mm caliber and muzzle energy and stabilized in flight rotation of the throwing elements, which have a large accuracy of hit with both the blade removed and the attached blade, with a double protection of a shot in the version with a rotary blade, for use, for example, in explosive areas where the use of firearms is unacceptable, or use under water to a shooting knife divers, frogmen, is applied to lesions of various purposes, such as to destroy dangerous marine fish and animals in shooting mode, and the dynamic boost mode.

The essence of the invention lies in the fact that in the device of a pneumatic weapon of self-defense, consisting of a predominantly strong metal handle containing two gas charging cavities, rear plugs of charging cavities with filling valves, a trigger with a fuse interacting with a missile element hydraulically rebalanced to the side their exit from the aforementioned handle, the handle may have a removable, permanently fixed or rotatable blade, a single trigger interacts simultaneously continuously with the two meta active or active-reactive elements, and their release from pereuravnoveshennogo able to produce at a time when the angular displacement of a single trigger body.

An additional feature is that the blade rotates in the handle relative to its axis and is equipped with a position lock.

An additional feature is that the trigger interacts with the missile elements through the rollers.

The blade of an air defense weapon in the form of an oblong flattened blade of a knife or dagger, pointed at the front, has cutting edges and a shank with at least one oblong through hole made at the beginning of the blade plane, communicating one side of the blade with the other side of the blade.

An additional feature is that the pneumatic weapon blade has recesses for fixation at the beginning of the blade plane and on the tail of the blade.

A missile element of a pneumatic weapon of self-defense, consisting of an elongated cylindrical body with a penetrating tip, has an internal charging gas cavity, and holes are made on its rear generatrix of the cylindrical surface, communicating an internal charging gas cavity of a missile element with a gas charging cavity of the handle of a pneumatic weapon of self-defense.

An additional feature is that in the missile active-reactive element of a pneumatic weapon of self-defense, the holes are nozzles that are inclined backward at an angle to the axial line of the missile element or rejected simultaneously tangentially or tangentially.

An additional feature is that the missile element of a pneumatic weapon of self-defense has at least one annular elastic seal.

An additional feature is that on the penetrating tip of the missile element of the pneumatic weapon of self-defense a hole is made perpendicular to the axis of the missile element.

The self-defense pneumatic weapon throwable element, consisting of an elongated cylindrical body with a penetrating tip, has an annular protrusion with a diameter larger than the cylindrical body near the rear end of the throwing element, a through hole is made along the axis of the entire body, and the penetrating tip is a flat cut at an angle to body axis.

An additional feature is that an annular elastic shock absorber is put on the cylindrical body of the projectile element in front of the annular protrusion.

Brief Description of the Drawings

Figure 1. General view of the weapon on the one hand.

Figure 2. General view of weapons on the other hand.

Figure 3. A cut of a weapon before a shot in the middle of the hull.

Figure 4. A cut of the weapon at the time of the shot in the middle of the hull.

Figure 5. Arms device with the image of the handle removed.

6. Weapons with a constant blade.

7. Weapons with a device of dynamic pressurization of the target until the moment of boost.

Fig. 8. Weapons with a device of dynamic pressurization of the target at the time of pressurization.

Fig.9. A cut of a weapon with a dynamic pressurization device in the middle of the hull.

Figure 1. The weapon consists of a handle 1, in which a blade 2 is rotated on its shank with a through gas outlet 3, and on the side surface of the housing 1 there is a trigger lever 4 with a movable fuse 5. At the rear end of the handle, plugs 6 with filling valves are installed.

A missile element is shown next to the weapon.

Figure 2. In the handle 1 there is a latch 7 with an internal spring for fixing the rotary blade 2 in the desired position.

Figure 3. Inside the handle 1 are the throwing elements 8, the sear rollers 9 and the trigger lever 4. The throwing element 8, which is actually an arrow, consists of a metal hollow body 10, a tip 11 which is hermetically welded or soldered to it, and an annular seal 12. In another design weapons and missile element seal is not installed on the missile element, but in the body of the handle 1 of the weapon. Holes 13 are made in the rear part of the housing 10, the axial lines of which can be located both perpendicular to the axial line of the missile element, and are inclined at an angle to the axial line of the missile element, and are inclined at an angle to the axial line of the missile element and simultaneously deflected tangentially or simply directed tangentially.

Figure 4. Charging cavities 14 between the inner generatrix of the charging cavities of the handle and the outer generatrix of the housing 10, as well as the inner cavity of the housing 10 through the holes 13 are filled with compressed gas through the filling valves of the plugs 6 with annular check valves.

In preparation for shooting, the blade 2 is removed from the latch 7 (see Figure 2) by pulling the outer ledge of the latch with an internal return spring with the thumb holding the weapon, then the blade 2 is rotated 90 ° relative to the normal position of the blade relative to the handle of any type of knife. Then the latch 7 is released, and its locking protrusion, depending on the design of the latch, rises into the locking recess of the blade or blade shank.

When turning the blade, the barrel channels 15 are open.

In this case, the blade performs the function of a second fuse, since when an attempt is made to shoot (for example, through negligence) before the barrel channels 15 closed by the blade are opened, a shot is impossible. With the thumb of the holding hand, the sliding fuse 5 (see FIG. 1) moves downward, after which the trigger of the trigger 4 is turned 90 ° to the right or left relative to its axis with the thumb. After the lever is turned, its recess 16 is opposite one or the other roller-sear 9. Under the action of the force of hydraulic rebalancing of the throwing element at its exit from the handle, the tip 11 presses the sear-roller 9 into the recess 16, after which the throwing element begins to move the exit from the barrel channel 15 and further from the handle 1. Turning the trigger lever in any direction around its axis by 180º produces a second shot.

Compressed gas from the internal volume of the body 10 of the missile element flows through the openings 13 in the variant “openings directed perpendicular to the axis of the missile element” into the charging cavity 14 of the handle as the missile element moves forward and the pressure in the charging cavity decreases due to the increase in volume when the missile element is pulled out handles. When the residual pressure gas flows out of the internal volume of the housing 10 through the openings 13 in the variant “openings inclined backward at an angle to the center line of the throwing element”, when the throwing element is out of the handle, the reaction force acts on the throwing element, increasing its initial speed. Holes 13 inclined backward at an angle to the center line of the missile element act as jet nozzles when the missile element moves inside the handle when it is released by the trigger.

The missile element in this embodiment is an active-reactive projectile.

When the holes 13 are tilted backward at an angle to the axial line of the missile element and simultaneously tangentially deflected, the outflow of gas from the internal volume of the housing 10 causes the missile element to rotate around its axis already when it moves inside the handle 1, then the rotational movement increases due to the residual pressure in the cavity housing 10 and after its departure from the handle. In this embodiment, the inclination of the holes 13 missile element is an active turbojet projectile.

With the location of the holes just 13 tangentially missile element is an active projectile with stabilization by rotation, carried out in a reactive manner.

In any of the above combinations of the orientation of the holes 13 relative to the axis of the missile element, the internal volume of the housing of the missile element is used as an additional source of compressed gas when the missile element moves inside the handle compared to the missile element that does not have an internal volume filled with compressed gas before firing.

Figure 5. When deleting the image of the handle, throwing elements 8 are visible, one of the two rollers-whispered 9, the protrusion 17 of the retainer 7, with which it enters the reciprocal recess of the blade 2, and the spring 18 of the retainer 7, as well as the pin 19, which enters the blade shaft and gives it the opportunity rotation by 90º without the possibility of exiting the handle when the blade is pulled out, for example, from a target when a blade is inserted into it or when the blade performs chores.

6. Blade 20 is permanently fixed in the handle 1 without the possibility of changing its position by the user, and its fastening can be both one-piece (press-fit, soldering, etc.), and detachable (pin, screw, etc.), for example, for changing broken blade.

The blade contains grooves 21 along which the shot element passes during firing, and gas vents 22. The holes in the blade are necessary so that the compressed throwing gas that leaves after the throwing element expands immediately after leaving the barrel channel 15 to the other side of the blade, without creating a pressure gradient under the end of the outgoing missile element and without deviating it from the direction of movement given by the barrel channel. In the version of the weapon with a rotatable rotary blade (Figure 1), the hole 3 performs the same function for both missile elements. The experiments proved the full practical effectiveness of these vents. In the execution of the blade with grooves, the use of throwable elements with an elongated tip 11, protruding from the barrel holes 15 to the outside. The elongated tip makes it possible to visually quickly determine if the weapon is loaded or not, and in addition to remove the throwing elements in the case of, for example, pressure leaks from the charging cavities without removing the plugs from the handle 6. In the case of a weapon with a rotary blade, the throwing elements can also be removed in such a case from the handle without removing the plugs 6 with a special hook, which enters a special hole for extraction in the tip of the missile element.

7. The weapon with a dynamic pressurization device has a blade 20 with grooves, a missile element 23 with a travel stop 24 in the form of an annular protrusion, and an annular elastic shock absorber 25, for example, made of rubber. Along the entire missile element along its axis there is a through hole 26 extending from the rear end of the missile element to the cut-off part 27.

Fig. 8. Weapons with a device of dynamic pressurization at the moment of pressurization, that is, the kind of shot at point-blank range. The lever of the trigger 4 after removal from the fuse rotates 90 ° from the safety position. In this case, the missile element 23 with great effort (about 100 kg at a charging pressure of 200 atm) begins to move forward from the handle, but, after a certain distance, abuts with its travel stop 24 through the shock absorber 25, which absorbs the impact pulse, in the front end of the charging cavity 14 ( see Figure 2). In this case, the compressed gas does not have time to exit through the hole 26 due to the significant hydraulic resistance of the hole. The exit of gas from the charging cavity 14 begins actually only after the missile element 23 makes a rapid (up to 100 m / s or more) limited forward travel. When using weapons in the dynamic boost mode, the blade 20 sticks into the target, and then quickly turn the lever 4. In this case, the missile element with great force enters the target (usually a predatory fish, shark, etc.), a dynamic blow of compressed gas is inflated from the inside Moreover, both the rupture of the internal organs of the predator and the increase in buoyancy occur, which tends to raise the predator up from the underwater swimmer.

The proposed weapon allows for dynamic pressurization, limited only by easily available means of compressing gases (350 atm) and to use at the request of the user both dynamic pressurization and shooting. The end of the missile element 23 can reach the end of the blade even in an unextended state. Accordingly, when the blade is inserted into the target on the handle, the extended throwing element will reach a depth exceeding the length of the blade, thereby further exacerbating the damaging effect with dynamic boost of the target.

Fig.9. A through hole 26 is shown along the axis of the missile element 23.

Claims (11)

1. Pneumatic weapon of self-defense, consisting of a durable handle containing two gas charging cavities, rear plugs of charging cavities with filling valves, a trigger with a fuse, interacting with a missile element hydraulically balanced towards their exit from the handle, characterized in that the handle can have a removable, permanently fixed or rotary blade, a single trigger organ interacts simultaneously with two tagged active or active-reactive elements and, as their release from pereuravnoveshennogo able to produce at a time when the angular displacement of a single trigger body. 2. Pneumatic self-defense weapon according to claim 1, characterized in that the blade rotates in the handle relative to its axis and is equipped with a position lock. 3. Pneumatic self-defense weapon according to claim 1, characterized in that the trigger interacts with the missile elements through the rollers. 4. Blade of a pneumatic weapon of self-defense in the form of an oblong flattened blade of a knife or dagger, pointed at the front, having cutting edges, a shank, characterized in that at least one oblong through hole is made at the beginning of the plane of the blade, communicating one side of the blade with the other side of the blade. 5. The blade of an air defense weapon according to claim 4, characterized in that it has recesses for fixation at the beginning of the blade plane and on the tail of the blade. 6. A missile element of a pneumatic weapon of self-defense, consisting of an elongated cylindrical body with a penetrating tip, characterized in that the missile element has an internal charging gas cavity, and openings are made on its rear generatrix of the cylindrical surface, communicating the internal charging gas cavity of the missile element with a gas charging cavity handguns of air defense weapons. 7. A missile element of a pneumatic weapon of self-defense according to claim 6, characterized in that the holes in the active-reactive missile element are nozzles that are inclined backward at an angle to the axial line of the missile element, or deflected simultaneously tangentially or tangentially. 8. A missile element of a pneumatic weapon of self-defense according to claim 6, characterized in that at least one annular elastic seal is located on it. 9. A missile element of a pneumatic weapon of self-defense according to claim 6, characterized in that a hole is made on its penetrating tip perpendicular to the axis of the missile element. 10. A missile element of a pneumatic weapon of self-defense, consisting of an elongated cylindrical body with a penetrating tip, characterized in that an annular protrusion is made near the rear end of the missile element with a diameter larger than the cylindrical body, a through hole is made along the axis of the entire body, and the penetrating tip represents self flat cut at an angle to the axis of the housing. 11. The missile element of a pneumatic weapon of self-defense according to claim 10, characterized in that an annular elastic shock absorber is put on the cylindrical body of the missile element in front of the annular protrusion.

Images