RU2185592C2 - Multiple-use pneumatic cartridge - Google Patents

Abstract

FIELD: ammunition used in a standard firearm for transformation of it to a pneumatic one, the "magnum" type inclusive, with employment of a barrel-insert. SUBSTANCE: cartridge represents a hollow body with perforated end faces, positioned in one of which is the bullet location, and in the other positioned is the impact rod of the valve system drive, the body has two directly non-engageable valves-trigger and firing ones, the firing exhaust valve has a device for its opening in the form of a piston of a larger or similar diameter as compared with it, acting on the hydraulic actuator or unbalancing principle, and actuated by the smaller trigger valve. The cartridge constructions are filled up both with compressed gas for attaining the maximum nozzle powers and with liquefied gas for attaining the maximum quantity of shots from a single filling. EFFECT: reduced energy consumption of opening of the valve system. 9 cl, 6 dwg

Description

FIELD OF THE INVENTION
The invention relates to the field of ammunition for pneumatic weapons used for sports and hunting shooting, namely to pneumatic cartridges (cartridges, clips), which allow multiple reloading from a source of compressed gas and can be used for training and hunting shooting from standard firearms with an inset barrel under the caliber of airguns or firing from a specially made for the specified cartridge airguns.

State of the art
Known for the design of a refillable cartridge (UK patent N1601918, class F 42 B 5/02; F 41 B 11/06 priority 1977), comprising an outer casing in which the inner casing is movably housed with a blind and perforated ends and an inner cavity in which a valve with a spring is placed overlying the perforated end. In the front part of the outer casing there is a perforated insert with an end protruding into the inner casing that can interact with the valve of the inner casing. In a cartridge of the indicated design, the internal valve is unbalanced, i.e., it is affected by the spring force and internal pressure of the compressed gas, which presses it against the valve seat with a force equal to the product of the internal gas pressure and the cross-sectional area. For brisk weapons to open such a valve, the striker energy must overcome the clamping force of the valve, the force of the valve spring, as well as the rest mass of the inner casing to move it forward and the friction of the inner casing against the outer. All these efforts (primarily the clamping force of the valve) are very significant in comparison with the energy of the striking arms, which does not allow the cartridge of this design to be used to produce a shot with significant muzzle energy, since such a shot can only be obtained with significant internal pressure and large the cross-sectional area of the compressed gas, which increases the clamping force of the valve and, accordingly, the necessary energy of the striker. The cartridge of this design did not find application due to the impossibility of its use in firearms with standard energy striking to achieve any significant muzzle energy of the weapon.

 Known cartridge reusable (UK patent N 2170300, CL F 42 B 5/02; F 16 K 1/44; F 41 B 11/06 priority 1986) for firing from a combat revolver of caliber 357 using an extra barrel of caliber 4.5 mm for training in shooting using bullets for airguns.

 The cartridge has a cylindrical hollow body with perforated ends, in which a movable system of coupled semi-balanced valves is located in the form of a back valve with a spring that covers the hole of the cartridge end, corresponding to the striker, rigidly connected by a rod (rod) to the front exhaust valve located in the seat of the cartridge end , corresponding to the barrel of the weapon, from the side of the exhaust valve according to the patent, the cartridge has a place for putting on a bullet (in a commercial design, twisting around orets slug entry corresponding barrel cap with space bullet placement) and on the other end side corresponding weapon firing pin, a rod movable valve system located at the site of fire nests capsule holder. The cartridge is charged with compressed air using a hand-held compressor, a bullet is placed in the screw cap, after which the cartridge is inserted into the slot of the revolver drum, when firing the revolver strikes, it strikes the valve stem, disturbing their balance, while the valves are shifted forward, the front valve extends from the seat , opening access of compressed air to the pool for its movement along the barrel.

The disadvantage of the cartridge of the described design is that the outlet valve of the cartridge and, in particular, in a real commercial design according to the patent in question (Kuno Melcher KG "ME" company) has sealing elements in the form of two separate elastic rings laid in the annular grooves of the piston-valve, this type of seal seals the gap between the cylinder-body of the cartridge and the piston-valve under the action of the elastic properties of the seal material and the pressing force of the compressed gas pressure, while the influence of the pressing pressure sealing material due to its large value (200 kgf / cm ²⁾ affects the increase in friction at the opening is quite large. Because of this, the impact energy of the striker of the weapon to imbalance the system of valves and their opening must be significant. In addition, the valve system in this design is incompletely balanced and semi-balanced, which is necessary to reliably press the rear valve against its elastic seat with compressed air pressure to obtain reliable sealing at the indicated high pressure. The semi-equilibrium of the valve system with an unbalanced clamping force from the action of compressed air pressure towards the closing of the exhaust valve creates an additional counteraction when the energy of the striker is applied. This does not allow the use of large outlet cross sections for obtaining large muzzle powers when fired, because with a large cross section for the exhaust valve, the area of the rear valve must be even larger to ensure sealing imbalance, and the unbalanced force increases in proportion to the increase in the cross section of the rear valve. The muzzle energy of a firearm firing pneumatic cartridges increases in proportion to the increase in pressure of compressed gas in the pneumatic cartridge. However, the pressure above the specified cannot be increased at present due to the lack of a source of its production available to the user (over 200 kgf / cm ² , i.e. the pressure used to refuel scuba diving cylinders) and the inability to open the valves of this design by a brisk firearm with standard energy due to increased unbalanced forces and increased friction in the sealing elements. Muzzle energy can also be increased by increasing the opening passage of the outlet valve and its opening speed, which increases the rate of increase in pressure in the barrel of the weapon, however, the design in question does not allow this path to be performed due to the increase in unbalanced pressing force from the inevitable increase in the area of the open section of the rear valve. The above drawbacks do not allow the use of a cartridge of the design in question for firing a firearm with standard striker energy, with muzzle energy of more than 5-7 J (the indicated maximum muzzle energy is achieved in ME products). According to the patent, the cartridge was intended for firing a bullet of a standard caliber for firearms, however, due to the low developed power, commercial products can only fire a standard caliber pistol with a caliber gun of not more than 4.5 mm, and only in short-barreled weapons.

 Thus, the cartridge of the design in question cannot be used in standard firearms to obtain a pneumatic shot with Magnum energy (enhanced power) with a muzzle energy of at least 20-25 J, especially with energy up to 80 J, as in the best modern models of pneumatic long-barreled weapons , and accordingly, it is impossible to apply for commercial silent hunting with long-barreled firearms and pneumatic weapons.

 The closest analogue to the proposed invention is a pneumatic cartridge refillable, known from patent US 4531458, IPC 7, F 42 B5 / 02, publication 30.07.1985.

 This cartridge contains a cylindrical hollow body with perforated ends, a movable system of two valves that overlap the perforations of the ends, a movable piston dividing the cartridge into two cavities - a small (slotted) between the piston and the end face of the cartridge corresponding to the striker of the weapon, and a large one between the piston and the end face of the cartridge, corresponding to the shell input of the barrel of the weapon, and having a device that provides a controlled passage of gas from one of the mentioned cavities to another, the piston is connected by a rod with a large spring-loaded exhaust valve, metically and centered overlapping a large diameter hole made in the end face of the cartridge corresponding to the projectile input of the gun barrel, in the end face of the cartridge corresponding to the striker of the weapon, a small diameter hole with thrust shoulders is made, into which the shock protrusion of the small-sized release movable valve passes, which has the possibility of movement along the striker of the weapon into the hole made in the movable piston, and in one part seals the hole of small diameter in the end of the cartridge corresponding to the striker of the weapon, and the other part seals the hole made in the movable piston, in the end face of the cartridge corresponding to the projectile input of the barrel of the weapon, a place is made for placing the bullet.

 The disadvantages of this cartridge include the expenditure of high energy impact striker brisk weapons to open the valve system. In addition, the cartridge of the considered design, which completely and once releases compressed gas during firing, cannot be charged once with the standard energy carrier (liquefied carbon dioxide) for producing a large number of shots from a single charge.

 The invention is aimed at solving the problem of obtaining a reusable cartridge for a pneumatic weapon complex: firearms - a detached barrel - a pneumatic cartridge that allows the use of high pressurized gas pressures with a large openable cross-sectional area for striker energies standard for firearms, to increase the muzzle power of pneumatic firearms to the characteristics that ensure the muzzle power of the pneumatic weapon "magnum", i.e. not less than 25 J, and up to 80 J.

 The problem is solved due to the fact that the pneumatic cartridge is refillable (according to the first embodiment of the invention), containing a cylindrical hollow body with perforated ends, a movable system of two valves that overlap the perforations of the ends, a movable piston dividing the cartridge into two cavities - a small one between the piston and the end cartridge, corresponding to the striker of the weapon, and a large one between the piston and the end face of the cartridge, corresponding to the projectile input of the barrel of the weapon, and having a device providing a controlled passage of ha behind from one of the mentioned cavities to another, the piston is connected by a thrust to a large spring-loaded exhaust valve, hermetically and centered overlapping a large diameter hole made in the end of the cartridge corresponding to the projectile input of the weapon barrel, in the end of the cartridge corresponding to the striker of the weapon, a small diameter hole with resistant shoulders into which the shock protrusion of the trigger movable valve of small diameter passes, which has the ability to move along the striker into the hole made in the movable piston e, and with one part it seals a hole of small diameter in the end face of the cartridge corresponding to the striker of the weapon, and the other part seals the hole made in the movable piston, in the end of the cartridge corresponding to the projectile input of the barrel of the weapon, a place is made for placing a bullet, according to the invention, a cavity made between the end face of the valve of small diameter and the end face of the hole in the movable piston, it is connected to the atmosphere by a channel of small diameter passing directly into the pre-space, and the movable valve of small diameter It is equipped with elastic ring seals and is hydraulically balanced or with hydraulic balance shifted towards the valve opening.

 In preferred embodiments of the invention, a small-diameter channel connecting the cavity between the end face of the small-diameter valve and the end face of the hole in the movable piston with the atmosphere passes through the rod to the outer surface of the exhaust valve directly into the pre-space.

 A device providing a controlled gas passage is made in the form of a nozzle of small diameter passing through a movable piston.

 In a small cavity around a movable valve of small diameter, a cylindrical spring is placed, resting at one end on the end of the cartridge corresponding to the striker of the weapon, and the other end on the end of the moving piston.

 The large exhaust valve has an elastic sealing element located either directly on it or on the inside of the end face of the cartridge, corresponding to the projectile input of the barrel of the weapon.

 The exhaust valve is made in the form of a piston with ring or lip sealing elements entering the hole made in the end face of the cartridge corresponding to the projectile inlet of the weapon barrel.

 The rod is made in the form of a hollow cylinder, which is a communicating part of a large cavity with an outer diameter less than the inner diameter of the cartridge and filled with porous material, the device for controlled gas passage is made in the form of a hollow needle or groove passing along the surface of the rod, and connects the small cavity with a part of the large cavity, adjacent to the exhaust valve and not filled with porous material, which is separated from the filled part of the large cavity by a perforated or mesh partition.

 The location of the bullet made in the end face of the cartridge has an elastic annular gasket with a diameter of the central hole less than the diameter of the bullet.

 According to a second embodiment of the invention, a reusable pneumatic cartridge comprising a cylindrical hollow body with perforated ends, a movable system of two valves overlapping the end perforations, a movable piston located inside the cartridge cavity and dividing it into two cavities — a small slot cavity located between the piston and the cartridge end face corresponding to the striker of the weapon in which the shock rod of the valve of small diameter passes, having the ability to move along the direction of the striker of the weapon into the hole left in the piston, and a large cavity located between the piston and the exhaust valve that covers the hole in the end of the cartridge corresponding to the projectile inlet of the gun barrel, the movable piston is connected by a thrust to the exhaust valve, in the end of the cartridge corresponding to the projectile inlet of the gun barrel, a place is made for placing the bullet , according to the invention, the small-diameter valve is made hydraulically balanced or with hydraulic balance biased towards the valve opening, and with its one end it seals a large cavity the cartridge from the small slot cavity, and at the other end seals the large cavity of the cartridge from the cavity located between the end face of the small-diameter valve opposite the shock rod and the end face of the hole made in the piston and connected to the atmosphere by a channel of small diameter that goes directly into the pre-exit space, the outlet the valve has a diameter equal to the diameter of the piston, the valve stem of small diameter with a small annular gap passes into the hole of small diameter, made in the end face of the cartridge corresponding to the striker , and with a large annular gap passes into the hole made in the piston.

 The hydraulic balance of the valve, shifted toward the opening of the valve, is due to the fact that the diameter of the body of the small valve, overlapping the holes of small diameter in the end of the cartridge corresponding to the striker of the weapon, is less than the diameter of the body of the small valve, overlapping the opening of the movable piston.

 The invention is illustrated by figures.

 Figure 1 shows the cartridge according to the first embodiment of the invention in the static position of the elements in a discharged or charged state.

 Figure 2 shows the cartridge according to the first embodiment of the invention at the time of the shot.

 In FIG. 3 shows an embodiment of a cartridge with an ejector magnetic device in a static discharged or charged state.

 In FIG. 4 shows an embodiment of a cartridge with a check valve in the piston.

 Figure 5 shows an embodiment of the cartridge according to the dependent claim 7 of the formula.

 Figure 6 shows the cartridge according to the second embodiment of the invention.

 The cartridge according to claim 1 of the claims (Fig. 1) consists of a cylindrical body 1 with a large diameter hole 2 in the screw end 3, a small diameter 4 hole made in the body end, a small balanced trigger valve 5 with elastic ring seals 6 and shock rod 7. In the housing there is a movable system consisting of a piston 8 with an elastic ring seal 9, a rod 10, an exhaust valve 11 with an elastic seal and a perforated centralizer 12. In the piston 8 there are springs 13 and a control device gas passage 14 (nozzle). At the end 3 there is an elastic bullet-holder gasket 15. The piston 8 divides the cartridge into two cavities, a small 16 and a large 17. A cavity 18 is located in the piston, communicating with the pre-gun space (atmosphere) by the channel 19.

 The cartridge works as follows (figure 1). To charge the cartridge from a source of compressed gas (for example, air), the cartridge is connected to the source by a hole 2, while the gas pressure 11 is squeezed from the saddle of the end face 3, compressing through the rod 10 and piston 8 of the spring 13, and the compressed gas enters through the perforations in the centralizer 12 in a large cavity 17 rounds. Next, the gas through the nozzle 14 enters the small cavity 16. Also, the compressed gas through the channel 19 enters the cavity 18 and presses the valve 5 to the hole 4, sealing it, and the further shoulders of the hole 4 prevent its further movement. After the gas supply to the cartridge ends, valve 11 is pressed against the end face 3 due to the force of the springs 13 and the pressure difference generated from the difference between the areas of the valve 11 and the valve 5 and the pressure in the cavity 16 of the cartridge and the atmosphere, reliably sealing the hole 2. After charging the cartridge with compressed gas, a bullet 20 is placed in the bullet holder, erzhivaemaya in the pad by the resilience of the gasket material.

 When fired (Fig. 2), the following processes occur. The striker of the weapon 21 strikes the shock rod 7, spending its energy only to overcome friction in the seals of the valve 5, the valve 5 advances along the stroke of the striker, moves into the hole made in the piston 8, while the air in the cavity 18 is displaced through the channel 19 into the pre-gun space and further along the leaks between the bullet and the grooves of the gasket in the barrel. The opening 4 opens and the compressed gas from the cavity 16 enters the near-side space and then through the leaks of the weapon shutter mirror into the atmosphere, while the compressed gas from the cavity 17 through the nozzle 14 enters the cavity 16, but due to the difference in the area of gas passage through the opening 4 (large passage area) and nozzles 14 (small passage area), the pressure in the cavity 16 becomes much lower than the pressure in the cavity 17. Due to the pressure difference in the cavities 16 and 17 and the difference in the effective area of the piston 8 and the area of the valve 11, the piston 8 moves to end side of the core whisker with great force (up to hundreds of kilograms), through the pressing rod 10 from the valve seat 11 and thus ensuring the free passage of the compressed gas to the bullet 20 to move it down the barrel weapon. After the bullet begins to move along the bore, the compressed gas enters the channel 19 and cavity 18, forcing valve 5 to move towards the striker, while valve 5 closes hole 4, the residual pressure in cavity 17 and cavity 16 is leveled through nozzle 14, and the valve 11 closes the hole 2 under the action of the force of the springs 13 and the above-mentioned difference in the areas of the valve 5 and valve 11. This process occurs in a very short period of time, and although the multiple inertial processes of the device allow the valve 11 to remain in open position, in the cartridge after the shot, the residual gas pressure is maintained.

 The use of the indicated design of the cartridge makes it possible, using the principle of hydraulic reinforcement, by opening the balanced valve 5 of small diameter with insignificant energy of the striker to open the valve 11 of large diameter with a sufficiently large stroke, providing large muzzle energies.

To slow the closing of the valve 11 during firing and to ensure almost complete emptying of the cartridge to further increase the muzzle energy, ejector and magnetic devices are used (Fig. 3). The cartridge with ejectors and a magnetic device has a hollow needle 22 fixed in the piston 8, passing into the guide nozzle 23, fixed in the centralizer 12, an elongated nozzle 24 of the channel 19, permanent magnets 25 made of ceramic with high magnetic force, one of which is fixed in the valve 5, and the other at the end of the piston bore 8. A cartridge of this design is charged with compressed air in the usual way, and the multi-pole permanent magnets 25 pulled to each other are disconnected by the force arising from the entry of compressed gas into the cavity 18, and The valve 5 is closed to close the hole 4 when charging, as indicated in the previous design. When fired, the following processes occur. Under the action of the impact, the striker valve 5 moves into the bore of the piston 8 and opens the hole 4, the valve 11 opens, while the compressed gas, leaving the barrel of the weapon from the cavity 17, passes through perforations in the centralizer 12 and through the nozzle 23, creating a pressure due to the pressure in the flow, which is perceived by the needle 22, while the air flow through the needle 22 into the cavity 16 is reduced, which increases the closing time of the valve 11. Simultaneously with this process, when the valve 11 is opened, the nozzle 24 is drawn inside the hole 2 into the cartridge, however, the cut with the pla remains inside the hole 2. The high-speed air flow exiting into the barrel of the weapon creates a vacuum in the nozzle 24, which is transmitted through the channel 19 to the cavity 18 of the valve 5, forcing it to slow its closing, which also slows the closing of the valve 11. At the same time, upon impact, the striker arms, valve 5 advances along the impact of the striker and interacts with its magnet with a magnet located at the end of the piston bore 8, the magnets are attracted to each other, preventing valve 5 from closing and increasing valve closing time 11. All of these devices properties, both collectively and individually, slow down the closing speed of valve 11, providing the greatest possible time of the pressure of the compressed gas on the bullet and, accordingly, increasing the muzzle energy of the weapon. When using these devices, the residual pressure of the compressed gas in the cartridge after the shot, as shown, the experiments do not exceed several atmospheres at a charging pressure of 200 kgf / cm ² .

 The cartridge (Fig. 4) can be charged with compressed gas not from the front, but from the rear through the opening 4. In this case, the following processes occur during charging. For loading, a snap is used, consisting of a rod 26 passing through the thrust hole 19 and through the cavity 18 to the valve 5 and loaded with a spring 27, developing a force greater than the force equal to the product of the charging pressure by the area of the valve 5. The compressed gas pressure presses the valve 5 by compressing through the rod 26, the spring 27, the compressed gas enters the cavity 16 and, squeezing the annular valve 28 with the spring 29 from the holes 30, passes into the cavity 17. When the pressure is stopped, the valve 5 closes the hole 5 under the action of the spring 27, the snap is removed from atron, after which a bullet is placed in the gasket 15. When firing the gun strikes, the valve 5 moves inside the cartridge, the opening 4 opens, the compressed gas from the cavity 16 enters the atmosphere, while the compressed gas from the cavity 17 cannot enter the cavity 16 due to the closed valve 28. The valve 11, compressing the spring 31, opens, giving compressed air access to the pool. This design provides a large time open state of the valve 11 when fired due to the lack of flow of compressed gas from the cavity 17 into the cavity 16.

 The cartridge (Fig. 5) has a liquefied carbon dioxide loading design for producing many shots from a single charge. In the cartridge is a hollow cylinder 32, which is a modification of the rod 10, freely moving inside the cartridge case. Inside the cylinder is filled with porous material 33 (for example, felt), the cavity 16 is connected to the cavity 17 by a hollow needle 34. The cavity 18 of the valve 5 is connected to the atmosphere by a channel 19 passing in the rod 32.

 A spring 35 is located in the cavity 18. When the cartridge is loaded in a vertical position with the valve 11 upward, the liquefied gas opens the valve 11, compressing the spring 35, enters the fighting cavity 17 and then into the cylinder cavity 32 through perforations in the centralizer 12, soaking up with porous material 33. Some amount liquid gas enters the needle 34 and, when gasified, fills the cavity 16. When firing the guns, opens the valve 5, which compresses the spring 35, and, opening the hole 4 and then the valve 11, releases part of the gasified from the liquid in porous material 33, gas from the fighting cavity 17 into the bore. After the shot, the spring 35, acting simultaneously on the valves 5 and 11, closes them, the liquid gas absorbed into the porous material 33, intensively evaporating, re-fills the cavities 16 and 17, after which the cartridge can be recharged by the bullet for the next shot. The cartridge can fire a large number of shots while at least some liquid gas is stored in the porous material 33. The use of the previously described devices that increase the closing time of the valve 11 when fired is inappropriate in this design, since when using them the muzzle energy does not increase, and the number of shots per charge is reduced.

 The cartridge according to the second embodiment of the invention (Fig.6) consists of a housing 1 with an opening 2, an end 3 with an opening 4, a balanced valve 5 of small diameter with annular sealing elements 6 and a permanent magnet 7, a piston 8 with annular sealing elements 9, rod 10, in the end hole of which the magnet 11 is fixed and the hole 12 is made, passing into the nozzle 13, of the exhaust valve 14 with ring sealing elements, of the annular elastic valve element 15 with holes 16 in the rod 10. There is a perforated protrusion 17 on the rod 17. Between a cavity 18 is located at the end of the valve 5 and the magnet 11, and the piston cavity 8 communicates with the cartridge cavity 19 through the holes 20. Between the end 3 and the piston 8 there is a slot cavity 21, and an opening 22 is located at the end of the piston through which the valve stem 5 passes. An annular elastic element 24 is fixed in the hole 23 of the end face of the housing, holding the bullet 25.

 The cartridge (Fig. 6) works as follows. Charging with compressed gas is performed through the hole 23 with the retracted snap-in system for charging the valve system all the way to the side, the compressed gas, passing through the nozzle 13 into the hole 12, passes into the holes 16 and, expanding the elastic element 15, fills the cavity 19 of the cartridge. At the same time, compressed gas passing through the hole 12 into the cavity 18 acts on the end face of the valve 5, forcing it to reliably seal the hole in the piston 8, through which the valve stem 5 passes. After the gas supply ceases, the elastic element 15 narrows and is pressed against the holes 16, sealing the cavity 19 from the atmosphere. Bullet 25 is inserted into element 24. When fired, the following processes occur. The gun head strikes the stem of a fully balanced valve 5, expending energy only to overcome the friction of the valve movement, which, moving into the cavity 18, opens the hole 22, while the magnet 7 is attracted to the magnet 11. The compressed gas enters the cavity 21, disrupting the balance of the piston system 8 and the exhaust valve 14. The valve 14 opens a passage for compressed gas from the cavity 19 to the pool 25, which begins to move along the barrel of the weapon. When the valve is fully open, the forward movement of which is limited by the perforated protrusion 17, the nozzle 13 enters the hole 23, forming an ejector, while the pressure in the channel 12 and cavity 18 is reduced, thereby slowing down together with the separation force of the magnets 7 and 11 from each other the closing moment the valve 5 of the hole 22. The cavity 21 of the volume increasing when the piston 8 is advanced forward continues to be filled with compressed gas from the cavity 19, thereby increasing the speed of opening of the valve 14 and, accordingly, the rate of increase in pressure in the barrel of the weapon.

 This cartridge design allows, using the principle of hydraulic balancing of balanced large-diameter valves, to open a large bore of the exhaust valve at high pressure and at high speed by opening the small-diameter valve with insignificant energy of the striker.

Claims (9)

 1. Pneumatic cartridge reusable, containing a cylindrical hollow body with perforated ends, a movable system of two valves that overlap the perforations of the ends, a movable piston dividing the cartridge into two cavities - a small between the piston and the end face of the cartridge corresponding to the striker of the weapon, and a large between the piston and the end cartridge corresponding to the projectile input of the barrel of the weapon, and having a device that provides a controlled passage of gas from one of the mentioned cavity to another, the piston is connected by a thrust with a large suppressed exhaust valve, hermetically and centered overlapping a large diameter hole made in the end face of the cartridge corresponding to the projectile input of the barrel of the weapon, in the end face of the cartridge corresponding to the striker of the weapon, a small diameter hole with persistent shoulders is made, into which the shock protrusion of the small-sized release movable valve passes, which has the ability to move along the striker into the hole made in the movable piston, and in one part seals the hole of small diameter in the end face of the cartridge a, corresponding to the striker of the weapon, and the other part seals the hole made in the movable piston, at the end of the cartridge corresponding to the projectile input of the barrel of the weapon, a place is made for placing a bullet, characterized in that the cavity made between the end of the valve of small diameter and the end of the hole in the movable the piston is connected to the atmosphere by a channel of small diameter passing directly into the pre-muzzle space, and the movable valve of small diameter is equipped with elastic ring seals and is made hydraulically new or with hydraulic balance, shifted towards the valve opening.  2. The reusable pneumatic cartridge according to claim 1, characterized in that the small-diameter channel connecting the cavity between the end face of the small-diameter valve and the end face of the hole in the movable piston with the atmosphere passes through the rod to the outer surface of the exhaust valve directly into the pre-gun space.  3. The reusable pneumatic cartridge according to claim 1, characterized in that the device providing a controlled gas passage is made in the form of a small nozzle passing through a movable piston.  4. A reusable pneumatic cartridge according to claim 1, characterized in that a cylindrical spring is placed in a small cavity around a small-diameter movable valve, resting on one end of the cartridge corresponding to the striker of the weapon and the other on the end of the movable piston.  5. The reusable pneumatic cartridge according to claim 1, characterized in that the large exhaust valve has an elastic sealing element located either directly on it or on the inside of the cartridge end face corresponding to the projectile input of the weapon barrel.  6. The reusable pneumatic cartridge according to claim 1, characterized in that the exhaust valve is made in the form of a piston with ring or lip sealing elements entering a hole made in the end face of the cartridge corresponding to the projectile input of the weapon barrel.  7. The reusable pneumatic cartridge according to claim 1, characterized in that the thrust is made in the form of a hollow cylinder, which is a communicating part of a large cavity with an outer diameter less than the inner diameter of the cartridge and filled with porous material, the device for controlled gas passage is made in the form of a hollow needle or groove passing along the surface of the thrust and connects the small cavity with a part of the large cavity adjacent to the exhaust valve and not filled with porous material, which is separated from the filled part of the pain perforated or mesh septum.  8. The reusable pneumatic cartridge according to claim 1, characterized in that the bullet location made at the end of the cartridge has an elastic annular gasket with a diameter of the central hole less than the diameter of the bullet.  9. A reusable pneumatic cartridge containing a cylindrical hollow body with perforated ends, a movable system of two valves overlapping the end perforations, a movable piston located inside the cartridge cavity and dividing it into two cavities - a small slot cavity located between the piston and the cartridge end face corresponding to the striker of the weapon, in which the shock rod of the valve of small diameter passes, having the ability to move along the direction of the striker of the weapon into the hole made in the piston, and a large cavity, located between the piston and the exhaust valve that covers the hole in the end of the cartridge corresponding to the projectile inlet of the weapon barrel, the movable piston is connected by a rod to the exhaust valve, in the end of the cartridge corresponding to the projectile input of the weapon barrel, a place is made for accommodating the bullet, characterized in that the valve is small in diameter made hydraulically balanced or with hydraulic balance, shifted towards the opening, the valve and at one end seals the large cavity of the cartridge from a small slotted strip tee, and the other end seals the large cavity of the cartridge from the cavity located between the end face of the small-diameter valve, opposite the shock rod, and the end face of the hole made in the piston, and connected to the atmosphere by a small-diameter channel that goes directly into the pre-space, the exhaust valve has a diameter equal to the diameter of the piston, the valve stem of small diameter with a small annular gap passes into the hole of small diameter made in the end of the cartridge corresponding to the striker of the weapon, and with a large annular gap passes into the hole made in the piston.

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