RU2070310C1 - Electric-shock device - Google Patents

Abstract

FIELD: defence against aggressors, electric-shock therapy. SUBSTANCE: device has case in the form of hollow cylinder made of glass-reinforced plastic and accommodating mounting frame. Separating ring 4 mounted between working part 1 of case 1 and its handle 3 carries start button 5 with interlocking mechanism 6. Central working electrode mounted in center of working end of case 1 is connected to low-potential lead of high-voltage pulse supply; side electrodes 8 are arranged over its circumference, equally spaced apart, and connected to high-potential lead of high-voltage pulse supply. Working electrodes 7,8 are pointed pins with drilling on cylindrical surface; they are connected to leads of high-voltage pulse supply. At working end of case 1, on its side surface, there is safety electrode 9 in the form of carbon plastic ring. End of case 1 on side of handle 3 may be provided with cover 10 that closes input pin contacts of built-in charging device. EFFECT: improved design. 6 cl, 3 dwg

Description

 The invention relates to high-voltage spark gaps and can be used in devices for protecting animals or offenders from attack by exposure to a series of high-voltage discharges, as well as for electroshock therapy.

A device with an electric spark arrester containing placed in a cylindrical housing a source of low DC voltage, a converter, an oscillation generator, a step-up transformer, a rectifier, as well as discharge electrodes and a switch located on the outer surface of the housing [1]
This device provides the formation and transmission of a series of electric shocks, characterized by low current and short duration, to objects with which it is in contact. This device does not provide effective self-defense when an offender tries to grab him from the hands of the owner.

It is also known a device with an electric spark arrester, containing a pulse generator located in an elongated housing, a switch, a power source, a transformer, the arrester itself is included in the secondary winding [2]
In addition to the drawback indicated above, which makes it possible to snatch this self-defense product from the hands of its owner, it has low mechanical strength and shock resistance due to the design features of its body, which may result in self-protection with this device in some cases.

Also known is a multifunctional device for equipping law enforcement personnel, comprising a cylindrical body of non-conductive material, on the lateral surface of the working part of which are applied many parallel electrical conductors, as well as a metal ring; the power supply, converter and switching means are located in the device’s case [3]
In this device, due to the choice of distances between the parallel conductors, as well as between their ends and the metal ring, a spark discharge is formed, which is used for self-defense when monitoring the actions of the offender. The optical and acoustic effects accompanying the spark discharge are an additional deterrent factor.

 This technical solution provides resistance to the attack of the enemy when he tries to grab a means of self-defense, however, its insufficient effectiveness is associated with the need to act at a fairly close distance from the enemy (it is necessary to ensure contact with the side of the device). The housing design is not optimal from the point of view of the user's safety, the handle is not separated from the working part of the housing, along the entire length of which high-potential conductors are applied. High-voltage discharge occurs on the surface of the housing, which leads to a decrease in the mechanical strength of the device and ultimately to premature failure.

The closest to the claimed device in technical essence and the technical result achieved is a self-contained spark gap, which is a device for self-defense against attacks using high voltage, containing a housing made in the form of a hollow cylinder of dielectric material, two working electrodes placed on its working end, and two protective electrodes located diametrically opposite on the side surface of the housing in its working part, connected to the source m high pulsed voltage, disposed inside the housing, which on the side surface between its operating part and the handle release button located and positioned within the housing a power source [4]
This device provides more effective and more reliable protection against attack due to the placement of working electrodes at the end, which allows for effective self-defense at a greater distance from the enemy, as well as through the use of protective electrodes on the working part of the body, which implement the function of anti-snatcher.

 However, this known technical solution has several disadvantages that reduce the effectiveness of self-defense and safety for the user. So, the above shape and location of the working and protective electrodes lead, firstly, to the appearance of high-voltage discharges on the surface of the housing, which reduce the mechanical strength of the device, and secondly, does not exclude the risk of electric shocks for the user himself in case of accidental contact with the working part of the housing, made as a whole with a handle. The acoustic and optical effects accompanying an electric discharge, although they are to a certain extent a factor of intimidation of the enemy, it is unlikely that this factor can be considered sufficiently effective due to the well-known, traditional form of the electric spark discharge resulting from this.

 The objective of the invention is the creation of a highly efficient electroshock device (autonomous spark gap), free from the above disadvantages. The technical result achieved in this case is to increase the efficiency of self-defense while increasing user safety by increasing the mechanical strength and impact resistance of the arrester design, as well as changing the characteristics of the generated spark arrester in such a way as to enhance the effect of acoustic and optical effects accompanying the electric discharge.

 The specified technical result is achieved by the fact that in the stun device containing a housing made in the form of a hollow cylinder of dielectric material, a protective electrode placed on the housing at its working end, two working electrodes placed on this end and connected to a source of high pulse voltage, placed inside the housing, the start button located on the side surface of the housing between its working part and the handle, and the power source located inside the housing, the mounting an arch made in the form of a hollow cylinder made of dielectric material inserted into the body, rigidly fixed in the body by means of a sleeve of dielectric material, a dividing ring placed in the middle part of the body between its working part and the handle, and at least two working electrodes are additionally introduced, while each of the working electrodes is made in the form of a pointed pin with grooves on its cylindrical surface in its middle part, one of them is located in the center of the working end and connected to a low flow a special output of a high pulse voltage source, and the remaining working electrodes forming a group of side electrodes are located at the same distance from each other on the circumference of the concentric axis of the central electrode, and are connected to a high potential output of a high pulse voltage source, the protective electrode is made in the form of a carbon fiber ring , the smallest distance of which from the working end is chosen to be larger than the distance between the central and any of the side electrodes, and the start button tanovlena in the sleeve is provided with a locking mechanism and placed on the spacer ring.

 In this case, the housing may be made of fiberglass or may be multilayer, with one or more layers predominantly adjacent to the outer surface of the housing, in this case made of Kevlaroglass, and the remaining layers of fiberglass. The outer surface of the handle may be coated with a soft dielectric material.

 The power source can be made in the form of a rechargeable battery, while a built-in charger with input pin contacts located inside the housing in the area of the handle at its end equipped with a removable cover can be inserted into the device.

 The achievement of the technical result provided by the invention is due to the totality of the essential features. The features that distinguish the invention from the prototype are the introduction, implementation and placement of the mounting frame, the dividing ring, the additional introduction of at least two working electrodes, the form and placement of the protective and working electrodes and the design features of connecting them with the terminals of the high pulse voltage source and material selection housing and protective electrode, as well as in the design features of the start button, power supply and the handle of the housing. All these signs together contribute to increasing the mechanical and electrical strength of the shock resistance of the device, and therefore, the reliability of its operation, while increasing the convenience of handling and safety for the user himself, as well as the degree of effective impact on the enemy (due to the amplification of acoustic and optical impact factors, without increasing the power of electric shock), which ultimately leads to an increase in the effectiveness of self-defense.

 In FIG. 1 shows the appearance of an electroshock device made in accordance with the invention; in FIG. 2 is a section along line A A in FIG. 1 of the working part of the stun device, illustrating the connection of the working electrodes with a source of high pulse voltage; figure 3 is a section along the line B B in fig. 1, illustrating the placement and operation of a start button with a locking mechanism.

 According to FIG. 1, the stun device includes a housing 1 made in the form of a hollow cylinder made of dielectric material, for example, fiberglass, having a working part 2 and a handle 3, between which a dividing ring 4 is mounted, on which a start button 5 with a locking mechanism 6 is placed. At the working end of the housing 1, working electrodes are installed, one of which is 7 central, low potential, located in the center of the end, and the remaining three lateral, high potential, 8 at the same distance from each other on a circle, concentric axis of the central electrode 7. At the working end of the housing 1 on its side surface there is a protective electrode 9 made in the form of a carbon fiber ring, the smallest distance from the working end of the housing 1 is chosen smaller than the distance between the central 7 and any of the side working electrodes 8. the housing 1 from the side of the handle 3 can be closed with a removable cover 10, fixed in its center by a screw 11, which serves to fasten the belt loop 12.

 In FIG. 2, illustrating a fragment of the construction of the device in section, the working end of the housing 1 is closed by the head 13. The mounting frame 14, made in the form of a hollow cylinder of dielectric material inserted into the housing 1, is designed to install and fasten the structural elements of the device placed inside the housing 1. In the mounting frame 14, a frame 15 of a high voltage transformer of a high pulse voltage source with a winding 16 and a core 17 is installed. Each of the working electrodes 7, 8 mounted, for example, on the thread in the head 13, has the shape of a pointed pin with a groove on a cylindrical surface. The low-potential central electrode 7 is connected to a common wire 18, and the high-potential side electrodes 8 (one of them is shown in Fig. 2) are connected to the output wire 20 of the high-voltage transformer by means of a pressing and connecting ring 19. In FIG. 2 also shows a protective electrode 9 (anti-snatcher) made in the form of a ring and a through hole 21 in the mounting frame 14 and in the housing 1 for connecting the protective electrode 9.

 In FIG. 3, illustrating the implementation and principle of operation of the start button 5 with the locking mechanism 6, a fragment of a section of the device is shown in the installation plane on the dividing ring 4 of the starting button 5 with the locking mechanism 6 (Fig. 1). As shown in FIG. 3 of the embodiment, the start button 5 is a microswitch 22 with a pusher 23 mounted on the sleeve 24 and locked in the initial state by a plate 25 mounted for movement using the key 26. Elements 25, 26 form the lock of the start button 5. The sleeve 24 provides mounting mounting frame 14 to the housing 1 and together with the microswitch 22 is placed in the insert 27. The outer surface of the handle 3 may be provided with a coating of soft dielectric material (not shown in detail in the drawings) .

 Electroshock device operates as follows.

 When you press the start button 5 (previously unlocked by moving the key 26 of the locking mechanism 6 and thereby release the pusher 23 by the plate 25 (see Fig. 3), the power supply is connected to the high pulse voltage source. In this case, between the central 7 and each of the side 8 electrodes there is a spark discharge (simultaneously or alternately). When penetrating or approaching a distance of less than half the distance between the central 7 and any of the side 8 electrodes to the target the latter experiences the effect of electric shock. A similar effect described above occurs when penetrating or approaching the same distance to the protective electrode 9. If you touch the side surface at a distance from the protective electrode 9 (anti-snatch) greater than the above, the same the result can be achieved by forcibly reducing this distance by changing the angular orientation of the device by its owner. The above-described features of the constructive implementation of the protective electrode 9 provide this for any spatial orientation of the device relative to its owner and the target (attacking enemy).

 Due to the above-described embodiment of the working electrodes 7, 8, a spark discharge is formed at the ends of the electrodes 7, 8, which eliminates the possibility of breakdown on the housing and, as a result, increases the mechanical strength of the device.

 The location of the high potential side electrodes 8 symmetrically with respect to the low potential central electrode 7 leads to a discharge, which is visually represented as a multitude of spark discharges, and the acoustic and optical effects that accompany them, with simultaneous or almost simultaneous, with insignificant temporary deviations for different pairs of (central-lateral) electrodes ("running" flashes, crackle discharges) enhance their terrifying effect on the enemy.

 In addition, the arrangement of the central 7 and side 8 electrodes provided for by the invention allows the central 7 and side 8 electrodes to the greatest extent to make it possible to simplify the connection of the electrodes 7, 8 with the leads 18, 20 of the high voltage transformer of the high pulse voltage source to the greatest extent (see Fig. 2) This eliminates the need to create and isolate additional leads, consumes less wires and reduces the risk of internal breakdowns, which also leads to an increase in electrical and Mechanical Protection strength.

 The choice of material and form of execution of the housing 1, as well as the introduction and form of execution of the mounting frame 14 are dictated by the requirements of high mechanical strength and impact resistance in combination with good dielectric properties. Thus, the execution of the housing 1 of fiberglass, including multilayer, when performing its individual layers, mainly close to the outer surface, of high-strength Kevlaroglass, allows to increase the mechanical strength of the device, and therefore, the effectiveness of the self-defense provided by it in terms of impact-crushing action. The choice of material of the protective electrode 9 is also dictated by the requirement to increase mechanical strength. In addition, carbon fiber material, similar in its properties to the material of the body (including electrical conductivity). Such uniformity of properties enhances the manufacturability of the device design.

 The introduction of the separation ring 4 increases the safety for the user by eliminating the possibility of accidentally slipping the hand from the handle 3 to the working part 2 of the housing 1. Providing the start button 5 with the locking mechanism 6 and placing it on the separation ring 4 increases the usability of the device and eliminates its unintentional activation, which ultimately leads to increased operational reliability, directly related to ensuring the required effectiveness of self-defense.

 Features of the implementation of the power source, the introduction of an integrated charger while ensuring ease of access to it, can increase the life of the device between sub-bits and simplify the sub-discharge procedure, which also has a direct relationship with increased operational reliability, ensuring that the device is ready for operation and reliable operation at the right time.

 The supply of the handle 3 with a coating of soft dielectric material, in addition to user convenience, helps to improve the dielectric properties of the housing 1, i.e., increase the dielectric strength, which can be important under adverse environmental conditions, for example, at high humidity.

 Example. The stun device is made in dimensions: diameter 41 mm, total length 320 mm, body length 300 mm. Weight 720 g. The discharge voltage is 45 kV, the discharge repetition rate is 400 40 Hz, the voltage of the power source is 12 V. The duration of continuous operation is at least 2 hours, the battery charge time is not more than 10 hours. A stable shock effect is achieved when the exposure time is about 1 from.

 The invention provides an increase in the efficiency of self-protection implemented using an electroshock device while simultaneously improving the safety of its user by increasing the mechanical strength and shock resistance of the structure and increasing its electric strength, as well as by increasing the effectiveness of the optical and acoustic effects of a spark discharge. At the same time, the use of an electroshock device for its intended purpose does not pose a danger to a living organism and its vital functions.

Claims (6)

 1. An electroshock device comprising a housing made in the form of a hollow cylinder made of dielectric material, a protective electrode placed on the housing at its working end, two working electrodes located on this end and connected to a high pulse voltage source located inside the housing, a start button located on the side surface of the housing between its working part and the handle, and the power source located inside the housing, connected via the start button to a source of high pulse voltage pressure, characterized in that it introduced a mounting frame made in the form of a hollow cylinder of dielectric material inserted into the body, rigidly fixed in the body by means of a sleeve of dielectric material, a dividing ring placed in the middle of the body between its working part and the handle, and at least two working electrodes were additionally introduced, each of the working electrodes being made in the form of a pointed pin with grooves on its cylindrical surface in its middle part, one of them being located in the center of the working end of the housing and connected to the low-potential output of the high pulse voltage source, and the remaining working electrodes, forming a group of side electrodes, are located at the same distance from each other on the circumference of the concentric axis of the central electrode, and are connected to the high-potential output of the high pulse voltage source , the protective electrode is made in the form of a carbon fiber ring, the smallest distance of which from the working end of the housing is chosen large distance between the central and any of the side electrodes, and the start button is installed in the sleeve, is equipped with a locking mechanism and is placed on the spacer ring.  2. The device according to p. 1, characterized in that the housing is made of fiberglass.  3. The device according to p. 1, characterized in that the housing is multilayer, and one or more layers, mainly closest to the outer surface of the housing, are made of Kevlarostekloplastik, and the remaining layers are made of fiberglass.  4. The device according to claim 1, characterized in that the outer surface of the handle is provided with a coating of soft dielectric material.  5. The device according to p. 1, characterized in that the power source is made in the form of a battery.  6. The device according to p. 5, characterized in that it has a built-in charger with input pin contacts located inside the housing in the area of the handle at its end, equipped with a removable cover.

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