RU170787U9 - Shock shield with electroshock - Google Patents

Abstract

The utility model relates to protective devices for protecting law enforcement from the actions of an aggressive crowd, and specifically to anti-ballistic shields with the possibility of electroshock exposure to offenders. The shield contains a protective plane of electrical insulating and impact-resistant material with handles on the inner side facing the user, working electrodes made in the form of metallized tracks, with at least one place for demonstrating the electric discharge located on the outer side of the shield, electrically connected to an electroshock device, fixed on the inside of the switchboard and equipped with a control and a power source. In this case, the working electrodes have a multiply perforated protective mask made of electrical insulating material, located on top of the working electrodes on the outside of the shield, a dedicated place for visualization of the electric discharge, located on the outer surface of the shield and also serving as the location of the protective electrodes of the aforementioned stun device. The maximum operational efficiency and reliability of the device during intensive operation, as well as an increase in the output electric power, are achieved by introducing a protective mask for the working electrodes, mainly from impact-resistant and abrasion-resistant polymer, and introducing an electric discharge visualization site in the form of a plate made of heat-resistant insulating material. The stun device is made with the possibility of autonomous operation and is mounted on the inner surface of the shield with the ability to quickly disconnect. 8 s.p. f-ly, 2 ill.

Description

The technical field to which the utility model relates.

The utility model relates to protective devices in the form of hand shields to protect law enforcement officers from the actions of an aggressive crowd, blows and pushes by the extremities of offenders, improvised throwing weapons of all types, to self-defense devices, to electroshock devices (ESH), and specifically to anti-ballistic shields with the possibility of electroshock on offenders.

State of the art

Protective shockproof shields with the possibility of electroshock action on attackers were selected as analogues of the utility model, for example, according to patents CN No. 104329992 [1], CN No. 204100925 U [2]. The patents describe shockproof shields made of polymeric materials with high shockproof strength (mainly made of polycarbonate) having metal working electrodes of various shapes on their outer surface (shield surface facing offenders), fixed to the shield surface in one way or another (mainly by gluing metal foil) connected to an ESH placed in the handle to hold the shield by the user. The ESA is switched on by the user of the shield in case of the need to avoid snatching from the user of the shield by offenders, or the need to push back or disperse offenders acting as a group.

As a prototype of a utility model, an Nova Electric RiotShield shockproof shield with the Nova Electric RiotShield company [3] was selected. The design consists of a shield made of transparent polycarbonate, on the outer surface of which working electrodes (tracks) made of metal foil are glued. On the inside of the shield, a fixed (rigidly fixed) EShU, as well as handles for holding the shield, are installed. The working electrodes of the shield are connected to the output electrodes of the EShU.

The main disadvantage of the prototype is the increased wear of the working electrodes, as a result of which the efficiency of the ESD for offenders deteriorates over time. When transporting the shield in police vehicles (during emergency movements of police personnel from object to object), the shields do not have time to put them into protective covers and are transported in bulk, and there are often cases when the shields serve as a support for the legs (soles of berets) of police officers when moving police vehicles . With constant impacts on the working electrodes of the shield with the edges and planes of other shields and / or soles of police berets with abrasive particles of road dust and dirt, the working electrodes (tracks) of metal foil are peeled off and chipped. In this case, both the reduction in the shield area of the impact on the application object and the complete breakage of the electrode tracks at the beginning or middle of their total length, starting from the point where the track is connected to the corresponding EShD electrode, with the failure (termination of) of half or all of the existing on offenders shield area.

Another disadvantage of the prototype is the low output electric power of the ESH shield. Spark electric discharges of the ESA of the shield during the demonstration of work and when the offender is used to directly contact the working electrodes spread directly over the surface of the shield material between the ends of the working electrode tracks closest to each other. Such a design is operable only with insignificant energy of spark discharges (energy of a pulse of discharge) and a low frequency of discharges of ESW. With an increase in energy in a discharge pulse or an increase in the frequency of discharges, i.e. increasing the output power, spark electric discharges passing directly over the surface of the shield material (polycarbonate) will burn on the shield shield material with carbonization of the material. Carbonized channels first partially reduce the breakdown voltage through the air between the working electrodes of the shield, i.e. they reduce the thickness of the offender’s clothing pierced by an electric discharge, and then completely disrupt the shield, stopping the electroshock effect on the offender, since the ESH starts to work on a short circuit (a completely conductive carbon path appears in the charred shield material) between the working electrodes. The output power of electroshock-proof panels by Nova Security Group and other companies producing shock-proof panels with electroshock does not exceed 2-4 W.

A similar situation arises when exposed to rain or mud droplets falling on the surface of the shield between the working electrodes. These droplets are an electrically conductive material, therefore, at a high power output of the ESD, they can also cause paths with carbonization of the shield material and subsequent short circuit of the working electrodes.

The purpose of the utility model is to increase operational efficiency and reliability while increasing the output electric power of the device.

The objective of the claimed utility model is to provide a shockproof device with an electroshock effect, devoid of prototype defects, with the exception of the possibility of damage and destruction of working electrodes while increasing the output electric power to the limits permitted by the legislation of the Russian Federation for police EShU types and medical standards for the permissible power of electroshock exposure for a person power services of the Russian Federation (10 W).

The problem is solved in that in a shockproof shield with an electroshock effect, containing a protective plane of electrical insulating and shockproof material with handles on the inner side facing the user, with working electrodes made in the form of metallized tracks, with at least one place for demonstrating electric discharge, located on the outside of the shield, electrically connected to an electroshock device, mounted on the inside of the shield and provided with a control member and and by the power supply source, the working electrodes have a multiply perforated protective mask made of electrical insulation material, located on top of the working electrodes on the outside of the shield, with a dedicated visualization of the electric discharge located on the outer surface of the shield and also serving as the location of the protective electrodes of the said electroshock device.

An additional feature is that the stun device is a non-removable unit.

An additional feature is that the stun device is located in the cavity of the shield handle, and the control is located in the upper part of the handle and is controlled by the user's thumb.

An additional feature is that the power supply of the stun device is a rechargeable battery located in the cavity of the shield handle under a removable cover.

An additional feature is that the stun device is made with the possibility of autonomous operation, mainly in the form of a baton, and is fixed with the possibility of quick disconnection.

An additional feature is that the said perforated protective mask is made of an adhesive polymer film.

An additional feature is that the said perforated protective mask has perforations with a density that creates the effect of diaphragming the light flux.

An additional feature is that the aforementioned allocated place for visualization of the electric discharge is made in the form of a plate of heat-resistant electrical insulation material.

An additional feature is that the said plate of electrical insulating and impact-resistant material is made transparent in the aforementioned designated place for visualization of the electric discharge.

The claimed utility model has high operational reliability during intensive operation due to the introduction of a protective mask of the working electrodes, increased output electric power due to the introduction of the visualization site of the electric discharge (and simultaneously ESD protective electrodes) in the form of a plane made of heat-resistant insulating material, and also using a quick-detachable ESH that can work both as part of a shockproof shield with an electroshock effect, and autonomously, for example, as Lyceum special devices (electroshock batons).

The utility model is illustrated by drawings, which depict:

FIG. 1 is a general view of a shockproof shield with electroshock exposure (front view);

FIG. 2 is a general view of a shockproof shield with electroshock exposure (rear view).

FIG. 1 and 2. The shockproof shield with electroshock action contains a protective plane 1 of electrical insulating and impact-resistant material (mainly polycarbonate) with working electrodes 2 fixed on its outer side in the form of metallized tracks (made, for example, by adhesive metal foil) with a place 3 for visualization of spark electrical discharge on which the outputs of 4 working electrodes are located. At the top, plane 1 with working electrodes 4, except for the place 3 for visualizing the electric discharge, is covered with a perforated protective mask 5, which is a polymer film made of impact and abrasion resistant polymer with frequent perforation, glued or fused to plane 1 with electrodes 4. Protective mask, without interfering the passage of the damaging electric discharge from the working electrodes to the body of the offender, protects the thin working electrodes from mechanical damage, including, but not limited to, breaks, tearing, and wear from the air the effects of abrasive particles during transportation of boards laid in bulk in vehicles.

The working electrodes 2 are electrically connected to an autonomous quick-detachable EShU 6, for example, an EShU type made in the form of an AIR-107U baton, armed with the Ministry of Internal Affairs of the Russian Federation and other power services of the Russian Federation. The ESA 6 is fixed on the inside of the shield using elastic clamps of the fastening 7, which ensures reliable fixation of the ESA on the shield and, at the same time, quick disconnection of the ESh from the shield if necessary. On the inside of the shield there is also a handle 8 located next to the ESH handle, a handle 9 and a clamp handle 10. The electric discharge visualization site 3 is made in the form of a glass or ceramic plate, fixed, for example, with glue on plane 1. The outputs of 4 working electrodes carry a function both visualization of the working electric discharge for delinquents and the user, and the function of the protective electrodes of an autonomous removable stun device.

Visualization of the working electric discharge is necessary so that when the ESD is turned on, the user is convinced that the device is working correctly, the working electrodes are energized, and the electrical part of the shield does not fail. In collisions of the police with a rioting crowd, noise from the crowd, as well as blows to the shields of thrown stones and other objects, do not allow the user to verify the correct operation of the ESH shield, for example, by the sound of a spark discharge. The visualization site should be optimally positioned at the user's eye level (in the user's field of vision) with the working position of the shield in the user's hands. In the case of manufacturing a shield from an opaque material or with an opaque coating, it is advisable to make the visualization place transparent so that the user sees the spark discharge-ESA of the shield visualizing the operation of the shield.

Place 3 of the visualization of the spark electric discharge, made mainly in the form of a glass or ceramic plate, has the purpose of not only informing the user about the normal operation of the electrical part of the shield, but also (and this is the main thing) makes it possible for a long time demonstration of the working electric discharge by the shield user (police) to opposing offenders without burnout of the shield material under the action of an electric spark (and with a large output power - actually a thermal arc) discharge. The burning out of the shield material, as already indicated in the analysis of the prototype, ends in partial or complete carbonization of the burned path. Carbonized tracks first partially reduce the breakdown voltage through the air between the working electrodes of the shield, i.e. reduce the thickness of the offender’s clothing pierced by the electric discharge, and when completely charred, they completely disrupt the shield, causing a short circuit in the ESD. The demonstration of a working electric discharge (i.e., the demonstration to the offender of a striking high-voltage electric spark discharge, which has a frightening appearance and sound, before using the shield) has a great psychophysical effect on aggressive offenders. The demonstration of a working electric discharge before the direct use of an ESA, as shown by statistics on the use of an ESA, in most cases reduces the aggression of the enemy, forces him to obey legal requirements, which eliminates the need for further force actions to enforce the rule of law.

The protective mask with multiple perforations, in addition to the protective function, creates the effect of diaphragming the light flux, in which the user of the shield sees through it, and the offender, who is at a certain distance from the user of the shield, does not see the user. This property is very useful for the work of power services in the capture of criminals and terrorists and performs the same role as the masks of special forces. In addition, a protective mask with multiple perforations, made, for example, in the form of small holes, protects the working electrodes of the shield from ingress of dirt and rain drops, while the possibility of paths with charring of the shield material and subsequent short-circuiting of the working electrodes is significantly reduced.

The representative of the security services, using the proposed shield, as a regular shockproof one, can also produce electroshock impact on close offenders trying to break the chain of law enforcement officers with a mass of bodies, or grab the shield from the hands of a law enforcement officer in order to break the chain or strike the law enforcement officer. To perform an electroshock impact (or to demonstrate a combat electrical discharge to offenders before using the shield), a law enforcement officer can use the controls mounted on the inside of the ESHU 6 shield, using the thumb of the right hand holding the handle 8. If necessary, use the ESH as intended in the form of an autonomous ESH, the user quickly disconnects the ESA 6 from the shield, removing it from the clamps of the fastening 7, and uses the ESA in the usual way as a baton with an electroshock action.

The possibility of disconnecting the ESH from the panels allows transporting the panels, including those stacked in bulk, in vehicles without the risk of breaking the ESH, which also significantly increases their operational efficiency and reliability.

Technical implementation

The shockproof shield with an electroshock effect is made on the basis of a police shield of the ПЩ-015 type using a quick-detachable ЭУУ type АИР-107У. The main technical characteristics of the device: width 600 mm, height 1000 mm, shield material - polycarbonate, weight 4.5 kg, output operating voltage - not less than 50 kV, output power of the EShU 8.5 ± 1.5 W.

The above description characterizes the claimed utility model as industrially applicable and, in particular, as optimal for power services according to the criteria of “operational reliability” and “effectiveness of impact on offenders”.

BIBLIOGRAPHY

1. http://www.google.com/patents/CN104329992A?cl=en

2. https://www.google.com/patents/CN204100925U?cl=en&dq=CN+%E2%84%96+204100925+U&hl=en&sa=X&ved=0ahUKEwiP6vvUwoHKAhXjn3IKHYReAAQO6AEIHTAA

3. http://www.lesslethalproducts.com/NOVA_Stun_Devices.php

Claims (9)

1. The shockproof shield with electroshock exposure, comprising a protective plane of electrical insulating and impact resistant material with handles on the inner side facing the user, working electrodes made in the form of metallized tracks, with at least one place for the demonstration of electric discharge, located on the outer side of the shield, electrically connected to an electroshock device mounted on the inside of the switchboard and equipped with a control body and a power source, characterized in that of the working electrodes have plural perforated protective mask of electrically insulating material disposed over the working electrode on the outer side of the shield, allocated space visualization electrodischarge disposed on the outer surface of the panel and also serves as a place of the protective arrangement of the electrodes of said stun device. 2. The device according to claim 1, characterized in that the stun device is a non-removable unit. 3. The device according to claim 2, characterized in that the electric shock device is located in the cavity of the shield handle, and the control is located in the upper part of the handle and is controlled by the user's thumb. 4. The device according to p. 1, characterized in that the power source of the stun device is a battery located in the cavity of the shield handle under a removable cover. 5. The device according to claim 1, characterized in that the stun device is made with the possibility of autonomous operation, mainly in the form of a baton, and is fixed with the possibility of quick disconnection. 6. The device according to claim 1, characterized in that the said perforated protective mask is made of an adhesive polymer film. 7. The device according to claim 1, characterized in that the said perforated protective mask has perforations with a density that creates the effect of diaphragming the light flux. 8. The device according to p. 1, characterized in that the aforementioned allocated spot visualization of the electric discharge is made in the form of a plate of heat-resistant electrical insulation material. 9. The device according to p. 8, characterized in that the said plate of electrical insulating and impact-resistant material is made transparent in the aforementioned designated place for visualization of the electric discharge.

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