RU2113677C1 - Regulated power device to gas-pneumatic weapon - Google Patents

Abstract

FIELD: high-pressure gas-pneumatic weapon. SUBSTANCE: the body accommodates a knock-down gas cylinder consisting of two screwed-on parts, the cylinder cavity is filled with working medium. Located inside is a heating coil insulated from metal body of cylinder by a ceramic insulator. The cylinder has operating, regulating and safety valves. Pressure is controlled by pneumoreleases, pressure regulator, as well as by light and audio annunciators. A dynamic electric generator actuated by repeating depressions of lever kinematically linked with the electric generator serves as a power source. EFFECT: considerably enhanced power of pneumatic weapon. 2 dwg

Description

 The invention relates to high-pressure gas-pneumatic weapons.

 Known sports gas gun for firing bullets, containing a barrel with a box, a piston, a shutter, a trigger, a gas chamber, a gas cut-off mechanism, a handle and an aiming device, characterized in that a roller interacting with the shutter bevel is installed to automatically turn off the valve of the gas cut-off mechanism (ed. St. N 230679, class F 41 B, 1965).

 Also known is a valve device for cutting off compressed gas for a gas cylinder weapon, comprising a housing, a spring-loaded valve with a pusher and a striker with a combat spring, characterized in that in order to improve the accuracy of firing by increasing the stability of the initial velocity of the bullets by stabilizing the size of the cut-off portion of the compressed gas, it is equipped with two-feather spring, the housing is made with a socket for a two-feather spring, the pusher is made with a groove at the end facing the hammer, while one end of the two-spring spring rests on the wall yes housing and the other on the bottom of the groove follower (auth. binding. N 1,774,153, cl. F 41 B 11/00, 11/32, 1990).

 Closest to the claimed object in technical essence is a gas-pneumatic weapon containing a cylinder for liquefied gas, a gas shut-off valve device with a housing, a working valve, a hammer and a combat spring, characterized in that at least a partial zone of the gas pipeline has electric heating controlled by a thermostat and a switch associated with the trigger of the weapon (application of Germany N 3733240, CL F 41 B 11/06, 1988).

 This device, like analogue mechanisms, does not provide a sufficiently high energy of the shot, does not have the ability to flexibly adjust the power of the shot. In the device adopted for the prototype, the new technical solution is only compensation for temperature fluctuations in the gas pipeline and a significant increase in the energy of the shot is not provided. In addition, the equipment of gas chambers (cans) with liquefied gas requires special equipment, which creates certain inconveniences in practical use. The design of the device provides for the use of only a non-renewable power source.

 The aim of the invention is to provide a device that significantly increases the power of gas-pneumatic weapons, providing the ability to control pressure and flexible control of the energy of the shot and at the same time having an easily equipped energy source and an autonomous power source.

 This goal is achieved by the use of a collapsible gas cylinder, consisting of two parts screwed onto each other, one of which 19 is equipped with an electric coil 20 made of refractory metal, isolated from the metal body of the cylinder with a ceramic insulator 21.

 The second part of the gas cylinder 23 is screwed onto the thread on the first part 19 and is additionally fixed with locking screws 33. The gas cylinder can be filled with the working fluid in two ways: through working 3 or control and control valves 22 with liquefied gas, or with disassembling the cylinder and equipping it with evaporated dry matter or liquid. For heating the electric coil 20, dry cells, compact batteries or electrodynamic generators 44, driven by repeated movements of a lever kinematically connected with it, can be used as current sources. When the working fluid is heated by an electric spiral mounted inside the cylinder, there is a sharp increase in gas (steam) pressure in the cylinder, which ensures a high initial velocity of the bullet in gas-pneumatic weapons. To ensure a given pressure in the bore, a pneumatic breaker 39, a pressure regulator 40, and a rheostat 41 are provided that control the amount of current in the circuit from zero to the maximum possible. The control knobs of the rheostat 41 and potentiometer 42, as well as an indicator of the initial velocity of the bullet 43 kinematically connected to the pressure regulator, which allows you to select the required energy of the shot, are displayed on the body of the gas-pneumatic weapon.

 The design of the proposed device provides a double guarantee of safety: firstly, when the pressure in the cylinder rises above the permissible value, the pneumatic breaker 39 disconnects the heated electric coil 20 from the electric power source 44; secondly, if for some reason the pressure in the cylinder approaches a critical value, the safety valve 34 will operate and, preventing the balloon from breaking, part of the gas will be released into the atmosphere. In addition, this energy device has a weapon readiness alarm system, consisting of a potentiometer 42, a light indicator 45 and an audible alarm 46, which are activated when the pressure in the cylinder reaches the value specified by the bullet's initial speed indicator 43. After the alarm system has been activated, arrow about the readiness of the weapon for shooting, the electric spiral is turned off. The alarm system allows you to turn on the indicator light and the audible alarm at the same time, or, at the choice of the arrow, turn on any one device - light or sound.

 To improve the adjustment possibilities and better stabilize the amount of cut-off portion of compressed gas in the socket for the two-spring spring 8, an adjustment screw 38 is provided, the upper end of which abuts against the lower shoulder of the two-spring spring 11 and additionally compresses it when tightening and weakens its compression when unscrewing from the body of the housing 1.

 In FIG. 1 shows an adjustable energy device; in FIG. 2 is an electrical diagram of an adjustable energy device.

 The adjustable energy device for gas-pneumatic weapons includes a housing 1, a seal 2, a working valve 3, spring-loaded with a spring 4, a pusher 5, a hammer 6 with a combat spring 7. In the housing 1 there is a socket 8 in which a two-feather spring 10 is fixed on the transverse pin 9, the lower the shoulder 11 of which rests on the upper part of the adjusting screw 38, and the upper shoulder 12, equipped with an annular bend, is placed in a groove 13 formed in the push rod 5. A collapsible gas cylinder is enclosed in the housing 1, the cavity 14 of which is filled with a working fluid (gas, steam, liquid, dry matter). A gas pipeline 15 connects the cylinder cavity to the barrel channel through the longitudinal grooves 47 of the pusher 5 and valve 3 when the latter is opened under the action of the striker 6. The striker 6 is held on the cocking pad by a sear 17 mounted on the axis 18. The surface 16 restricts the advancement of the striker 6 into the socket 8.

 A collapsible gas cylinder consists of two parts 19 and 23 screwed onto each other. The gaskets 24 ensure the tightness of the cylinder. To prevent depressurization of the cylinder and increase safety, locking screws 33 are provided. An electric spiral 20 made of refractory metal (alloy) is isolated from the metal body of the cylinder by a ceramic insulator 21 pressed into the first part of the cylinder 19. The second screw-on part of the cylinder 23 contains 3 valves: working a valve 3, a spring 4 of which rests on a partition with holes 48, a control valve 22, a safety valve 34. The ball of the control valve 22 is wrung out upward with the front of the metal gas pipeline 37 when the eccentric 36 is rotated with a recess in its upper part 64, which secures it to the protrusion 65 of the pipeline 37. The valve 35 is used to seal the system.

 The gas cylinder 19, 23 is tightly closed in the housing 1 by means of a cover 26 and a seal 25 under the influence of eccentrics 31. In this case, the two protruding parts of the ceramic insulator 21 enter the corresponding holes of the cover 26. On the opposite side, two screws 27 are screwed onto the thread 26, through the axial part of which passes a conductor 29 with an insulator 28. Sealing gaskets 32 guarantee the necessary tightness. The electrical contact of the conductor 29 with the electric coil 20 is provided by the flexible contacts 30. The switches 49 and 50 serve respectively to connect the electric heating system and the control-signal system (Fig. 2). The rheostat 41 allows you to adjust the amount of current flowing through the electric coil 20.

 The bellows-type pneumatic isolator 39 communicates with the gas cylinder by means of a gas pipe 37. The lever 51, made of insulating material, is fixed with its movable end in the upper part of the pneumatic-bellows bellows 39. The lever 51 interacts with the fixed support 52, raising and lowering the conductive rod 53, fixed on the other end of the lever 51. A flexible conductor 66 is connected to the conductive rod 53, having electrical communication with a power source 44, which may be in the form of dry cells, compact batteries or electric a hydrodynamic generator. A current-collecting contact 54 is mounted on the conductive rod 53, sliding along the conductive bus 55. Another current-collecting contact 56 slides on the opposite side of the conductive bus 55 when moving along the guide 63 of the pressure regulator 40 with a pointer to the initial velocity of the bullet 43 attached to it. Arrow of the pointer to the initial velocity of the bullet 43 has the ability to navigate on the installation scale 57, graduated in m / s. An insulator 58 is installed at the end of the conductive rod 53, which acts on the electrical contacts 59 and closes them when the pressure in the gas cylinder increases. Potentiometer 42 controls the amount of current passing through the alarm system, represented by a light indicator 45, an audible alarm 46, switches 60 and 61, flexible conductors 62.

 To reduce heat transfer in the cylinder and in the gas pipeline, thermal insulation 67 is used. The gas pipeline is equipped with a heating device 68 and a thermostat 69.

 A collapsible gas cylinder is charged with liquefied gas through the valves: worker 3 or control and adjustment 22 (Fig. 1). The cylinder can also be filled with dry substance (for example, dry ice) or some easily evaporated liquid, for which it must be disassembled, refilled, and then reassembled and secured with the locking screws 33. The cylinder is then inserted into the housing 1, closed by a cover 26, which is fixed by the eccentrics 31. The pressure regulator 40 (Fig. 2) is set with its pointer 43 to the desired initial velocity of the bullet on the setting scale 57. The power source 44 is inserted into the power socket in the form of an electric element or is small dimensional battery. It is also possible to use a built-in electrodynamic generator, similar to that used in electric flashlights. The switch 50 closes the circuit of the alarm system. In this case, to turn on the audible warning device, contact 60 is closed, and the switch 61 remains open. To turn on the indicator light, on the contrary, close the contact 61, and the switch 60 remains open. Simultaneous activation of the indicator light 60 and the buzzer 46 occurs when the contacts 60 and 61 are open. The pneumatic isolator 39 is connected to the gas cylinder using a metal pipe 37, for which the eccentric 36 (Fig. 1) rotates around its axis until its recess 64 is fixed on the protrusion 65 of the pipeline 37. In this case, the upper part of the metal pipeline 37 presses the shut-off ball in the control and control valve 22, abutting against the gasket 35. The cylinder is electrically heated after e elektrospirali switching switch 49 (FIG. 2). In this case, the magnitude of the glow of the electric coil 20 can be regulated by the rheostat 41. After turning on the electric spiral 20, the switch 49 causes a rapid increase in pressure in the cylinder, which is perceived by the pneumatic breaker 39, the upper part of which is connected to the lever 51 and the conductive rod 53 fixed in it. As a result, the lever 51 rises up , and the conductive rod, to which the flexible conductor 66 is connected, the current collector contact 54 and the insulator 58, is lowered until it contacts 59. With the closure of the contacts 59, heating of the electrospi ali virtually ceases, since the electric resistance elektrospirali much more resistance electric alarm system which is actuated by informing arrow readiness for firing weapons. To produce the shot, the sear 17 (Fig. 1) goes down, releasing the hammer 6, which vigorously strikes the pusher 5, which acts on the working valve 3. The working valve 3, under the influence of a shock pulse, goes into the cylinder, while a portion of the compressed gas through the longitudinal grooves 47 and the gas pipeline 15 enters the breech of the barrel and, expanding, pushes the bullet with a high initial speed. After the shot, the working valve 3 returns to its original position, tightly pressing against the seal 2, preventing leakage of compressed gas from the cylinder. The stability of the supply and the amount of cut-off portion of compressed gas can be controlled to a certain extent by changing the pressure of the two-feather spring 10 on the pusher 5 using the adjusting screw 38. After the shot, the pressure in the gas cylinder and, therefore, in the pneumatic cutter 39 (Fig. 2) decreases slightly, mobile part of the pneumatic breaker 39 together with the lever 51 moves back, and the insulator 58 at the end of the conductive rod 53 moves away from the contacts 59, opening them. In this case, the alarm system is turned off, and the heating of the electric coil 20 is resumed until the pressure in the cylinder, set by the pressure regulator 40, is reached. The above cycles can be repeated until the working medium remains in the gas cylinder in the form of a liquid, gas, or dry substance.

At the end of the shooting, it is necessary to turn off the electric coil switch 49, and turn the eccentric 36 (Fig. 1) by 90 ^o , as a result of which the metal gas pipeline will disconnect from the gas cylinder.

Claims (1)

 An adjustable energy device for gas-pneumatic weapons, containing a cylinder for liquefied gas, a gas shut-off valve device with a housing, a working valve, a hammer and an operating spring, and a gas electric heating system with a heating coil, a power source, conductors, an adjustment thermostat, and a switch connected to the weapon trigger characterized in that the gas cylinder is made collapsible, consisting of two parts screwed onto the thread, additionally secured with locking screws, with inside the heating coil, insulated from the metal body of the cylinder with a ceramic insulator and designed to heat liquefied gas or other substances having a working, control and regulation and safety valve, while the pressure in the cylinder and gas pipe, in addition to the valves, is regulated by a pneumatic isolator, pressure regulator, potentiometer , rheostat, switches, as well as light and sound signaling devices, and the power source is a dynamic electric generator driven by toryayuschimisya pressing arm kinematically connected to an electric generator.

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