RU68671U1 - CARTRIDGE FOR REMOTE ELECTRIC SHOCK DEVICE - Google Patents

Abstract

The utility model relates to the field of electric means of destruction of objects. The housing (1) of the cartridge is made integral of the external (2) and internal (3) blocks placed therein. On the external unit (2) there is a docking unit (4) with an electroshock device (5). In the internal block (3), guide channels (9) are made, each of which is formed by the output channel (10) and the working channel (11) having a larger diameter. Throwing shells (12) are placed in the output channels (10), and spark gaps (14) and pistons (15) equipped with O-rings (16), made with a variable diameter, are placed in the working channels (11). Electrical contacts (6) are placed on the external unit (2), which form, with working electrodes (6), an electroshock device (5), projectile shells (12), arresters (14) and a connecting conductor (21), the first primary open circuit. The second primary electrically open electric circuit is formed by ejected flexible current conductors located in the cavities (8) of the indoor unit (3), working electrodes (7), electrical contacts (6) and projectile shells (12). This design of the cartridge provides an increase in its operational efficiency. 13 s.p. f-ly, 6 ill.

Description

The utility model relates to the field of electric means of destruction of objects and can be used in electric shock devices of remote action.

A cartridge for a remote electroshock device is known, which is triggered by the generation of high voltage pulses by an electroshock device, and comprising a housing equipped with a docking unit with an electroshock device and made in the form of a single unit with cavities for ejected flexible conductors and guide channels with throwing shells made of electrically conductive material placed in them and arresters, with each projectile inserted into the cartridge, ejected flexible conductors of a given length are attached to the corresponding projectile in its rear part, and to the front of each of the projectiles attached element of fixation on the target - clothing or skin of a biological object, made mainly in the form of a harpoon needle (US 5786546 A, F42B 5/03, 1998) .

Such a cartridge is inconvenient in operation, since it has the undesirable effect of the appearance of a loud sharp sound when it is triggered, as well as insufficiently small dimensions and weight associated with

including the presence of cartridges and a design feature of the case, which do not allow minimizing the dimensions of the cartridge.

Other cartridges for electroshock devices are also known (while electroshock devices can be operated both independently for contact destruction, and together with a cartridge for remote target destruction), operating on the same principle and differing in their design (for example, US 5654867 A, H05C 1 / 04.1997; US 6636412 B2, B64D 1/04, 2003).

Of the known devices, the closest to the proposed one is a cartridge for a remote electroshock device, comprising a housing with a docking assembly with an electroshock device, equipped with electrical contacts arranged to contact the corresponding working electrode of the electroshock device, two arresters located in the guide channels made in the housing from its front side igniting electrodes of which are interconnected by means of a connecting conductor, and two with an appropriate electrical contact and made of an electrically conductive material of a projectile, at the front end of each of which a fixing element is fixed on the target, and an ejected flexible current lead placed in one of two cavities made in the housing and connected to the corresponding electrical contact is attached to their rear part (US 2005/0262994 A1, F41F 5/00, 2005). In this cartridge, its housing is made in the form of a single unit, the guide channels have a constant diameter along their length, and the arresters in the form of pyrotechnic charges are placed directly behind the corresponding projectile.

Such a cartridge also does not have a high operational efficiency due to the inevitable occurrence when using a cartridge of loud sound accompanying the departure of projectile shells,

the possibility of the release of triggered pyrotechnic charges from the guide channels of the cartridge, as well as due to restrictions in the implementation of its design with minimum dimensions and weight. Therefore, such a cartridge together with an electroshock device is inconvenient in operation.

The problem solved by the utility model is to create a cartridge devoid of the disadvantages of the prototype. The technical result provided by the utility model is to increase the operational efficiency of the cartridge for a remote electroshock device by eliminating the appearance of loud sound when the arrears are triggered, preventing them from escaping from the cartridge, and also by reducing the size and weight of the cartridge.

This is achieved by the fact that in the cartridge for a remote electroshock device, comprising a housing with a docking unit with an electroshock device, equipped with electrical contacts arranged to contact the corresponding working electrode of the electroshock device, two spark arrears arranged in the guide channels made in the housing from its front side the electrodes of which are interconnected by means of a connecting conductor, and two connected to the corresponding electrocontact m and made of electrically conductive material projectile shells, on the front end of each of which a fixing element is fixed on the target, and an ejected flexible current lead is attached to their rear part, placed in one of two cavities made in the housing and connected to the corresponding electrical contact, the housing is made of composite external and internal blocks located in it, while the docking unit with the stun device is located on the external block, the cavities and guide channels are made in the internal block, each The first of guide channels

formed by coaxial output channel and working channel with a diameter exceeding the diameter of the output channel, projectiles and arresters are located in the output and working channels, respectively, in each of the working channels in front of the arrester on the same longitudinal axis there is a piston equipped with a sealing ring made of an electrically conductive material in contact with its front surface with the rear end of the projectile, and the rear with the arrester, each of the pistons is made with a variable along the longitudinal axis the diameter of the guide channel so that the largest diameter of its rear part corresponds to the diameter of the working channel, and the smallest diameter of its front part is selected from the condition that it can freely enter the output channel until it is densely blocked by its piston, the distance between the rear surface of each piston and the connecting conductor is selected from conditions for the possibility of a spark discharge between them at a given voltage on the working electrodes of the stun device, and the size of the air gap Single between the centers of the front ends of selected projectiles exceeding twice the value of said distance. The electrical connection of projectiles with electrical contacts can be made by means of additional easily destructible conductors placed on the outer surface of the indoor unit. Such a connection can be made by means of through holes perpendicular to the output channels in the inner block between each of the projectile shells and a part of the corresponding electrical contact located on the inner surface of the outer block, the length of the through holes being selected so that a spark discharge can occur in them. Such a connection can also be made by means of intermediate conductors installed in the through holes perpendicular to the output channels between each of the throwing

shells and part of the corresponding electrical contact located on the inner surface of the external unit. Each of the arresters located in the corresponding working channel can be fixed in it by means of a threaded connection or by means of a wedge connection, while the arresters and the corresponding parts of the working channels are made wedge-shaped. Each of the ejected flexible conductors placed in the corresponding cavity of the indoor unit can be stacked in it in the form of a multilayer coil, while the turns of each subsequent winding layer are located obliquely with respect to the turns of the previous layer. Each of the pistons can be made conical or in the form of two coaxial cylinders of different diameters, while the o-ring is placed on the piston part of a smaller diameter. The connecting conductor can be placed at the rear end of the indoor unit. The cartridge can be equipped with an easily destructible membrane made of a dielectric material located on the inner block from its front side with the overlapping output channels. A thin information sticker made of dielectric material can be placed on the outdoor unit and the front side of the indoor unit, part of which is located above the openings of the output channels, while a perforation is made in it that intersects the centers of these openings.

The above technical result is provided by the entire combination of essential features.

Figure 1 shows the appearance of the cartridge (without electrical contacts). Figure 2 shows the external block of the cartridge housing with electrical contacts. Figure 3 shows the internal block of the cartridge with electrical contacts. 4 shows a sectional view of an indoor unit. Figure 5 shows the inner block of the cartridge in the context of the operation of the arresters. Figure 6 shows an embodiment of a spark gap.

The cartridge in an advantageous structural embodiment is as follows. It contains a housing 1 made integral of the external 2 and the internal 3 blocks placed therein. Blocks 2, 3 are made of non-conductive material, for example, polystyrene. The indoor unit 3 is tightly inserted into the external unit 2, in addition, additional mutual fixation of the blocks 2, 3 can be carried out using adhesive bonding. On the external unit 2 there is a docking unit 4 with an electroshock device 5 (in figure 2 it is shown schematically). This node can be made, for example, in the form of a conical or cylindrical tip, the longitudinal axis of which coincides with the longitudinal axis of the external unit 2, with fixing protrusions on the stun device 5 (not shown in the drawings). The housing 1 is equipped with electrical contacts 6, for example, in the form of electrically conductive strips arranged to contact with the corresponding working electrode 7 of the stun device 5 (Fig. 4). In the indoor unit there are two cavities 8 and two, having a predominantly cylindrical shape, of the guide channel 9. Each of the guide channels 9 is formed by a coaxial output channel 10 and the working channel 11, while the diameter of the working channels 11 exceeds the diameter of the output channels 10 and is, for example, 5 mm and 8 mm, respectively. The guide channels 9 can be located both parallel and at a small angle to one another with an angle of divergence, for example, two angular degrees. Ejected flexible current conductors (not shown in the drawings) are made in cavities 8, made mainly of insulated copper wire, for example, 4.5 m long and 0.45 mm in diameter. Their laying in the cavities 8 is carried out, for example, in the form of a multilayer coil with the winding of the turns of each subsequent layer mainly inclined to the turns of the previous layer. In front of the indoor unit 3, in each of the cavities 8 and in each of the output channels 10, mainly

grooves are made (not shown in the drawings), in which individual sections of the ejected flexible current conductors are laid. An easily destroyed membrane made of dielectric material (not shown in the drawings) can be placed on the indoor unit 3 from its front side with the overlapping guide channels 9. On the external unit 2 and the front side of the internal unit 3 can be placed made of a dielectric material, mainly paper, a thin information sticker with information about the manufacturer and the technical parameters of the cartridge, part of which is located above the openings of the output channels 10, while perforation intersecting the centers of these holes (not shown in the drawings). In each of the output channels 10 there is a projectile (probe) 12 made of an electrically conductive material, for example, of brass or duralumin, mainly of cylindrical shape. At the front end of each of the projectiles 12, an element 13 is fixed to the target (on clothes or skin of a biological object), made mainly in the form of a harpoon needle. Ejected flexible current leads are attached to the rear of the corresponding projectile 12. In each of the working channels 11 there is a spark gap (baric gap) 14, and in front of it on one longitudinal axis there is a piston 15 provided with a sealing ring 16 in contact with one another in the original cartridge status, as shown in Fig.4. The arresters 14, mainly of cylindrical shape, are fixed in the working channels 11, for example, by means of a threaded connection. They can be fixed by means of a wedge connection, in this case, the arresters 14 and the corresponding parts of the working channels 11 are made wedge-shaped. The number of pistons 15 and, accordingly, the guide channels 9 mainly corresponds to the number of ejected flexible current conductors and is predominantly equal to two, however, it can be

more than it, if part of the projectile 12 has the purpose of non-electroshock effects on the target, and other effects, for example, the effects of irritants. The pistons 15 are made of an electrically conductive material, mainly duralumin or brass, and have a variable diameter so that their largest diameter corresponds to the diameter of the working channels 11, and the smallest diameter is selected from the condition of free entry into the corresponding output channel 10 to a dense overlap with its corresponding piston 15. Each of the pistons 15 can be made, for example, conical, or, as shown in figure 4, figure 5 - in the form of two coaxial cylinders of different diameters, while the o-ring 16 is placed on the part of the piston nya 15 smaller diameter. O-rings 16 are made of non-conductive material, mainly polyethylene or fluoroplastic, and are worn on the front of the corresponding piston 15 with a tight fit. Each of the arresters 14 (Fig.6) contains a casing 17 with a flammable electrode 18 fixed in its rear part and a sample 19 in its front part, in which the working substance 20 is placed, for example, lead trinitroresorcinate in an amount of, for example, 7.5 mg (pyrotechnic charge) selected from the condition of rapid conversion to a gaseous state when it is ignited by the action of a high voltage electric discharge, while the combustion products should not contain electrically conductive particles. The ignition electrodes 18 of the arresters 14 are electrically connected to each other by means of a connecting conductor 21 located, for example, at the rear end of the indoor unit 3. In addition to the ignition electrodes 18, the arresters 14 may contain contact electrodes at their front end (not shown in the drawings). The distance between the rear surface of each of the pistons 15 and the connecting conductor 21 is selected from the condition of the possibility of a spark discharge between them when

given voltage at the working electrodes 7, for example, at a voltage of 50 kV, this distance should not exceed 7 mm. The size of the air gap between the centers of the front ends of the projectile 12 is selected to exceed twice the value of this distance and is, for example, 24 mm The electrical connection of the projectile 12 with the corresponding electrical contact 6 can be organized in various ways. In an advantageous constructive embodiment, this electrical connection is provided by additional easily destructible conductors 22 located on the outer surface of the indoor unit 3 (as shown in FIG. 3) and in contact with the front of the corresponding projectile 12 and the corresponding electrical contact 6. Electrically conductive material and the transverse dimensions of the additional easily destructible conductors 22 are selected from the condition of their quick and easy destruction upon departure of projectiles 12. dynes of other possible embodiments of electrical connection projectile 12 with switch 6 provides for the intermediate electrode 23 set, preferably sealingly, in the through holes 24 of the indoor unit 3, as shown in Figure 4. Another variant of such a connection is due to the presence of such through holes 24 perpendicular to the output channels 10, the length of which is selected from the condition that a spark discharge may occur in them.

The device operates as follows. In the initial state, the cartridge is connected to the stun device 5 using the docking station 4. In this case, the working electrodes 7 of the stun device 5 are in contact with the contacts 6, which are through the intermediate electrodes 23, or through additional conductors 22, or by discharge in the through holes 24 when the stun is turned on devices 5 are in contact with projectiles 12, pistons 15 and

arrester 14, and form through the connecting conductor 21 primary open electrical circuit of the arrester 14 (circuit A). The second primary open electric circuit of remote target destruction (circuit B) is formed by ejected flexible conductors that are electrically in contact with the working electrodes 7 via electrical contacts 6 and attached to the projectile 12. In this case, the size of the air gap between the centers of the front ends of the projectile is greater than the sum of the gaps between the rear surfaces pistons 15 and flammable electrodes 18. This gap is selected from the condition of the possibility of a spark discharge for a given electric voltage between the working electrodes 7 of the stun device 5. When the stun device 5 is turned on, high working voltage arises on its working electrodes 7, which leads to the closure of circuit A and the simultaneous occurrence of electric spark discharges between the rear surfaces of the pistons 15 and the ignition electrodes 18. Chain B it remains open. Due to the occurrence of spark discharges, the working substance 20 of the arresters 14 is ignited and the gases generated and expanding in the samples 19 give accelerated movement to the pistons 15 in the direction of the projectile shells 12. Projectile projectiles 12 begin to accelerate toward the target and fly out of the output channels 10, entraining the ejected flexible conductors that are wound from laying in the respective cavities 8. Moreover, in the case of a constructive option with additional easily destructible conductors 22 and thin information ion sticker, they are all destroyed in the field of departure of the projectile 12 and do not interfere with the movement of the latter. The same applies to the membranes that overlap the guide channels 9 (if installed), which prevent projectiles 12 from falling out of the cartridge in running condition

stun device 5 with external mechanical stress. Pistons 15 enter the outlet channels 10, from which the projectiles 12 have already taken off, while the o-rings 16 are bent into the surfaces delimiting the channels 10 and 11, providing a cut-off of the gases that remain in the working channels 11. Thanks to the cut-off of the gases, the projectiles 12 do not escape It is accompanied by loud noises, and gases and other products of combustion of the working substance 20 do not enter the environment. Due to the projectiles 12 and the pistons 15 moving forward, the spark discharges cease and the electric circuit A I arresters 14 is broken. Throwing projectiles hit a target with a finite internal electrical resistance, circuit B is washed out, delivering high electrical voltage to the target and ensuring its temporary electric shock. The design features of the cartridge make it impossible to simultaneously close the electrical circuits A and B, which could lead to the failure of the device. If the projectiles 12 do not hit the target, then the electric circuit B does not close and the electric shock device 5 operates in idle mode, without causing its failure. When you disconnect the stun device 5, the electric circuit B opens and the cartridge can be disconnected from the stun device 5.

Implementation example. A cartridge with an equipped spark gap having a mass of 0.6 g is mounted on an electroshock device 5 generating a pulse electric voltage of 60 kV. It has overall dimensions of 65 × 45 × 14 mm and a mass of 25 g. The emission length of the ejected flexible conductors with a diameter of 0.45 mm is 4.5 m. The diameter of the output channels 10 is 5 mm, the diameter of the working channels is 11-8 mm, the distance between the axes guide channels 9-24 mm. At

the operation of the cartridge does not produce loud noises and there is no emission of exhaust particles of the working substance 20 into the atmosphere.

Cartridge for remote electroshock device, made in accordance with the utility model, has higher operational efficiency compared to known similar ones.

Claims (14)

1. A cartridge for a remote electroshock device, comprising a housing with a docking assembly with an electroshock device, equipped with electrical contacts arranged to contact the corresponding working electrode of the electroshock device, two arrears arranged in the guide channels made in the housing on its front side, the ignition electrodes of which are connected between by means of a connecting conductor, and two connected to the corresponding electrical contact and made of electric conductive material of a missile projectile, on the front end of each of which a fixing element is fixed on the target, and an ejected flexible current lead is attached to their rear part, located in one of two cavities made in the housing and connected to the corresponding electrical contact, characterized in that the housing is made of composite the external and internal blocks located in it, while the docking unit with the stun device is located on the external block, the cavities and guide channels are made in the internal block, each of the guide channels is formed by a coaxial output channel and a working channel with a diameter exceeding the diameter of the output channel, projectiles and arresters are located in the output and working channels, respectively, in each of the working channels in front of the spark gap there is a sealing ring equipped with a sealing ring made of electrically conductive material a piston in contact with its front surface with the rear end of the projectile, and the rear with the arrester, each of the pistons is made with changes diameter along the longitudinal axis of the guide channel so that the largest diameter of its rear part corresponds to the diameter of the working channel, and the smallest diameter of its front part is selected from the condition that it can freely enter the output channel until it is densely overlapped by its piston, the distance between the rear surface of each piston and the connecting conductor is selected from the condition of the possibility of a spark discharge between them at a given electrical voltage at the working electrodes of the stun device, and measures the air gap between the centers of the front ends of selected projectiles exceeding twice the value of said distance. 2. The cartridge according to claim 1, characterized in that the electrical connection of the projectile with the electrical contacts is made by means of additional easily destructible conductors located on the outer surface of the indoor unit. 3. The cartridge according to claim 1, characterized in that the electrical connection of the projectile with the electrical contacts is made by perpendicular to the output channels of the through holes in the internal block between each of the projectile and placed on the inner surface of the external unit of the corresponding electrical contact, the length of the through holes being selected from the condition of occurrence of a spark discharge in them. 4. The cartridge according to claim 1, characterized in that the electrical connection of the projectile with the electrical contacts is made by means of intermediate conductors installed in the through holes perpendicular to the output channels between each of the projectile and part of the corresponding electrical contact located on the inner surface of the external unit. 5. The cartridge according to claim 1, characterized in that each of the arresters located in the corresponding working channel is fixed therein by means of a threaded connection. 6. The cartridge according to claim 1, characterized in that each of the arresters located in the corresponding working channel is fixed therein by means of a wedge connection, while the arresters and the corresponding parts of the working channels are made wedge-shaped. 7. The cartridge according to claim 1, characterized in that each of the ejected flexible conductors located in the corresponding cavity of the indoor unit is laid in it in the form of a multilayer coil, while the turns of each subsequent winding layer are inclined with respect to the turns of the previous layer. 8. The cartridge according to claim 1, characterized in that in the front of the indoor unit, in each of the cavities and in each of the output channels, grooves are made for laying sections of the ejected flexible current conductors. 9. The cartridge according to claim 1, characterized in that it contains at least one additional non-stun projectile projectile and corresponding additional guide channel, piston, spark gap and O-ring. 10. The cartridge according to claim 1, characterized in that each of the pistons is made conical. 11. The cartridge according to claim 1, characterized in that each of the pistons is made in the form of two coaxial cylinders of different diameters, while the o-ring is placed on the piston part of a smaller diameter. 12. The cartridge according to claim 1, characterized in that the connecting conductor is placed on the rear end of the indoor unit. 13. The cartridge according to claim 1, characterized in that it is equipped with an easily destructible membrane made of dielectric material located on the inner block from its front side with the overlapping output channels. 14. The cartridge according to claim 1, characterized in that a thin information sticker made of dielectric material is placed on the external unit and the front side of the internal unit, part of which is located above the openings of the output channels, while perforation intersecting the centers of these openings is made in it.