CN209945141U - Electric shock gloves - Google Patents

Abstract

The utility model discloses an electric shock glove, which comprises a glove body, wherein the glove body sequentially comprises a cutting-proof layer, a waterproof layer and an inner lining from outside to inside, and a wiring area for wiring is arranged between the cutting-proof layer and the waterproof layer; the at least two electrodes are distributed and fixed on the glove body, and the distance between any two electrodes is larger than or equal to 5 cm; a power supply unit for supplying power to the electrode; and the control unit is used for controlling the connection between the power supply unit and the electrode and comprises an operation switch. The utility model discloses an electric shock gloves is through the rational arrangement electrode on the gloves body to set up power supply unit and the control unit for the electrode, make the electrode exportable voltage on the gloves body, be favorable to improving and grab the success rate, the utility model discloses an electric shock gloves have convenient to use, be difficult for being robbed and do not hinder the advantage of wearing personnel's both hands.

Description

Electric shock gloves

Technical Field

The utility model relates to a police equips the field, especially relates to an electric shock gloves.

Background

At present, police arrest criminals mainly rely on both hands and a plurality of police to use the apparatus, and the most commonly used and portable only uses the apparatus for electric baton, and electric baton's use has following not enough: (1) police may have no time to pull out the electric baton when meeting emergency, cause the electric baton can't play a role in the emergency; (2) the electric baton is easy to fall off the hand or be seized by the other party, and the situations are not favorable for the safety of the police; (3) the electric baton needs to additionally occupy one hand of the police, so that the police cannot fully exert the fighting skill when encountering a fierce gangster.

The patent application of the Chinese utility model with the publication number of CN 205860863U provides a pulse electronic control capture glove, which comprises a glove body, a power supply module, a first switch module, a pulse generation module, a second switch module, a plurality of pulse output points and a pulse control module; the glove body is connected with a power supply module, a first switch module, a pulse generation module, a second switch module and a plurality of pulse output points respectively; the power supply module is connected with the first switch module; the first switch module is connected with the pulse generation module; the pulse generation module is connected with the second switch module; the second switch module is respectively connected with each pulse output point; the pulse control module is connected with the pulse generation module. The pulse electronic control capture glove has the advantages that the safety and the practicability of use are improved through the arrangement of the two switches, and the pulse electronic control capture glove can be flexibly adjusted according to various different actual combat scenes and use requirements, so that the requirements of various different actual combat environments are met, and the practicability and the safety are enhanced.

However, the above-mentioned solution still has the following problems: the pulse output points are unreasonably arranged, and the pulse output points often cannot effectively contact suspects in actual combat, so that the pulse output points are difficult to shock.

Disclosure of Invention

The purpose of the invention is as follows: in order to overcome the deficiencies in the prior art, the utility model provides an electric shock glove aims at providing one kind and has electric shock function and reasonable police gloves of electrode distribution, can assist the police to arrest the criminal.

The technical scheme is as follows: in order to achieve the above object, the electric shock glove of the present invention comprises:

the glove body sequentially comprises an anti-cutting layer, a waterproof layer and a lining from outside to inside, and a wiring area for wiring is arranged between the anti-cutting layer and the waterproof layer;

the at least two electrodes are distributed and fixed on the glove body, and the distance between any two electrodes is larger than or equal to 5 cm;

a power supply unit for supplying power to the electrode; and

and the control unit is used for controlling the connection between the power supply unit and the electrode to be switched on and off and comprises an operation switch.

Further, the parameters of the output power of the power supply unit are as follows: the voltage range is 5-30KV, the current range is 7-15mA, the frequency is 0.5-5Hz, and the duty ratio is 50-95%.

Further, the frequency of the output electricity of the power supply unit is 0.5-3Hz, and the duty ratio is 70-90%.

Furthermore, a shielding layer is arranged between the waterproof layer and the lining, and the shielding layer is made of flexible conductive materials.

Furthermore, the electrodes are embedded in the rubber shielding bodies, and the rubber shielding bodies are fixed on the surface of the cutting-proof layer or embedded and fixed on the glove body.

Furthermore, the outer surface layer is made of a leather material, and the anti-cutting layer is made of aramid or high-polyethylene.

Further, the control unit further includes:

the operating switch is connected with the controller;

the electric control switch is arranged between the power supply unit and the electrode and is electrically connected with the controller;

a sensor assembly electrically connected to the controller, including a wearing state detection sensor that can detect a wearing state of the electric shock glove.

Has the advantages that: the utility model discloses an electric shock gloves is through the rational arrangement electrode on the gloves body to for electrode setting power supply unit and the control unit, make the electrode exportable voltage on the gloves body, the voltage of output so can act on the criminal and make the criminal lose the resistance ability, be favorable to improving and arrest the success rate, the utility model discloses an electric shock gloves have convenient to use, be difficult for being robbed and do not hinder the advantage of wearing personnel both hands.

Drawings

FIG. 1 is a structural view of an electric shock glove;

FIG. 2 is a block diagram of another embodiment of an electric stun glove;

FIG. 3 is a structural view of the fabric of the glove body;

FIG. 4 is a view showing a structure of a combination of an electrode and a rubber shield;

FIG. 5 is a schematic diagram showing the connection relationship among the electrode, the power supply unit and the control unit;

FIG. 6 is a flow chart of a shock control method;

FIG. 7 is a schematic flow chart of the control unit performing the authentication of the user;

the names of the parts represented by the reference numerals are as follows:

1-glove body; 11-outer surface layer; 12-a cut-resistant layer; 13-a shielding layer; 14-a waterproof layer; 15-lining; 16-a shielding layer; 2-an electrode; 3-a power supply unit; 31-a power supply; 32-an oscillating circuit; 33-a boost circuit; 4-a control unit; 41-operating switch; 42-a controller; 43-an electrically controlled switch; 44-a sensor assembly; 441-wearing state detection sensor; 442-gesture operation sensors; 443-a biological information collection sensor; 5-a rubber shield; 6-ring wrist portion; 61-plug head.

Detailed Description

The present invention will be further described with reference to the accompanying drawings.

The electric shock glove shown in fig. 1 comprises a glove body 1, at least two electrodes 2, a power supply unit 3 and a control unit 4.

The glove body 1 is similar to a common glove in appearance, the fabric forming the glove body 1 is formed by overlapping multiple layers of materials, as shown in fig. 3, the glove body sequentially comprises an outer surface layer 11, a cutting-proof layer 12, an insulating layer 13, a waterproof layer 14, a shielding layer 16 and an inner lining 15 from outside to inside, and a wiring area for wiring is arranged between the cutting-proof layer 12 and the shielding layer 13. The outer surface layer 11 is made of polymer materials such as leather materials or anti-slip leather, and is relatively wear-resistant and plays a role in water prevention; the material of anti-cutting layer 12 is high strength material, and preferred aramid fiber or high polyethylene, anti-cutting layer 12 can make gloves body 1 can not damaged by sharp sword, both can protect personnel's safety, makes personnel of wearing can fight the sword in actual combat, can protect the inside circuit structure of gloves body 1 again and prevent that it from suffering destruction. Insulating layer 13 can prevent that electric shock gloves from hindering the person of wearing self, waterproof layer 14 plays waterproof role, prevents that moisture from the inside circuit destruction circuit that permeates wherein of gloves body 1, and inside lining 15 is established at gloves body 1's inlayer for guarantee the travelling comfort of wearing personnel contact, shielding layer 16 is flexible conducting material like conductive cloth or wire, metal mesh grid etc. can prevent the electric current entering inside lining when the electric leakage condition takes place, only flows outside the shielding layer.

All electrodes 2 are distributed and fixed on the glove body 1, the electrodes 2 can be fixed on the palm, fingers, the back of the hand and other parts of the glove body 1, the electrodes 2 are in an exposed state, the distance between any two electrodes 2 is larger than or equal to 5cm, the electrodes 2 are distributed reasonably, the electrodes 2 cannot interfere with each other, a wearer can effectively enable electric pulses output by the electrodes 2 to act on criminals, and the catching success rate is improved. Preferably, as shown in fig. 4, the electrode 2 is embedded in the rubber shield 5, the rubber shield 5 is fixed on the surface of the cut-preventing layer 12 or embedded on the glove body 1, and the rubber shield 5 can firmly fix the electrode 2 and effectively isolate the electrode 2 from the glove body 1, so as to prevent the electrode 2 from hurting the wearer. Preferably, an electrode array consisting of the electrodes 2 can be arranged on the palm part of the glove body 1 including the finger part, so that the probability that the electrodes 2 contact the body of a suspect when a police worker carries out a catching task is greatly improved, and the electric shock glove plays a decisive role.

The power supply unit 3 is configured to supply power to the electrode 2, and preferably, the output power of the power supply unit 3 is in a form of pulse power, and parameters of the pulse power include a voltage range of 5-25KV, a current range of 7-15mA, a frequency of 0.5-5Hz, and a duty ratio of 50-95%. The pulse electricity of parameter acts on the criminal can make the criminal receive the electric shock effect and lose the reaction ability like this, and the voltage of this pulse electricity can effectively pierce through the clothing that the criminal wore for it also can act on the criminal's health to separate the clothing, simultaneously because the electric current of pulse electricity is lower and frequency and duty cycle set up rationally, be unlikely to make the criminal lose when making the pulse electricity act on the criminal.

Specifically, the power supply unit 3 includes a power supply 31, an oscillation circuit 32, and a voltage boosting circuit 33 in this order, in which the oscillation circuit 32 changes the output power of the power supply unit 3 into the form of pulse power, and the voltage boosting circuit 33 boosts the voltage of the pulse power output by the oscillation circuit 32 to a set parameter.

In one embodiment, the power supply unit 3 may be disposed in the glove body 1, that is, a compartment provided in the glove body 1, and the power supply unit 3 is mounted in the compartment, in this way, the integrity of the electric shock glove is high, but in this way, the volume of the power supply 31 cannot be large, and the power of the power supply 31 is limited.

In the second embodiment, the power supply unit 3 is disposed independently from the glove body 1, i.e. the power supply unit 3 is disposed outside the glove body 1, and when the power supply unit 3 is disposed outside the glove body 1, the power supply 31 is disposed outside the glove body 1. In this embodiment, the portion of the glove body 1 that is externally disposed is connected to the electrodes 2 on the glove body 1 and the other portion of the power supply unit 3 in the glove body 1 in a pluggable manner (in the case where a part of the power supply unit 3 is externally disposed on the glove body 1). In this embodiment, as shown in fig. 2, the glove further includes a ring wrist portion 6, the ring wrist portion 6 can be sleeved on the wrist of the wearer and has a lock similar to a watch and capable of adjusting tightness, the power supply unit 3 is integrally or the power supply 31 is disposed in the ring wrist portion 6, the ring wrist portion 6 has a leading-out wire, the leading-out wire has a plug head 61, the glove body 1 has a plug hole, and the plug head 61 supplies power to the electrode 2 after being inserted into the plug hole. Adopt above-mentioned mode, on the one hand can guarantee that power 31 is great, make it have sufficient electric quantity continuously to supply for electrode 2, most importantly, can prevent that electric shock gloves from being snatched by the criminal and reacting on police service personnel, adopt such split type structure, after the criminal snatched gloves body 1, gloves body 1 broke away from with ring wrist portion 6, owing to do not have the power supply of power 31, gloves body 1 and other parts that it contains will be difficult to play a role, so can effectively guarantee police service personnel's safety.

The control unit 4 is used for controlling the connection between the power supply unit 3 and the electrode 2, and comprises an operation switch 41.

In one embodiment, the operation switch 41 is a mechanical switch directly disposed between the power supply unit 3 and the electrode 2, and the user can directly control the opening and closing of the electric shock glove by pulling the mechanical switch.

In another embodiment, as shown in fig. 5, the control unit 4 further comprises a controller 42, an electrically controlled switch 43 and a sensor assembly 44, wherein the operating switch 41 is connected to the controller 42, where the operating switch 41 is a switch such as a tact switch that can provide a trigger signal to the controller 42; the electric control switch 43 is arranged between the power supply unit 3 and the electrode 2 and is electrically connected with the controller 42, the controller 42 controls the electric control switch 43 after receiving a trigger signal so that the power supply unit 3 is electrically connected with the electrode 2, and the electric control switch 43 is a common switch circuit; the sensor assembly 44 is electrically connected to the controller 42 and includes a wearing state detection sensor 441 capable of detecting a wearing state of the electric shock glove, in this embodiment, the wearing state detection sensor 441 includes a bioelectrical impedance sensor, the bioelectrical impedance sensor is disposed in an innermost layer of the glove body 1, and the controller 42 determines whether heart rate information exists by detecting acquired data through the bioelectrical impedance sensor, so as to determine whether a person wears the glove.

The electric shock control method based on the electric shock glove, as shown in fig. 6, includes the following steps S701-S703:

step S701, judging whether a starting trigger signal is received or not;

step S702, receiving a signal collected by the wearing state detection sensor and judging the wearing state of the electric shock glove when receiving a starting trigger signal;

step S703, when the electric shock glove is in a worn state, controlling the electric control switch 43 to establish a connection between the power supply unit 3 and the electrode 2.

Optionally, the sensor assembly 44 further comprises a gesture operation sensor 442, and the gesture operation sensor 442 comprises a piezoelectric sensor disposed at a knuckle of each finger portion on the palm side of the glove body 1, and the user can generate a signal by bending the finger, so that the user can send a trigger signal to the controller 42 by a preset operation gesture, such as: only the index finger and the middle finger are bent for 3 times continuously, the controller 42 receives three groups of electric signals generated by the piezoelectric sensors corresponding to the positions of the index finger and the middle finger and does not receive the electric signals of other piezoelectric sensors, conditions for generating a trigger signal are judged, the electric control switch 43 is controlled to enable the power supply unit 3 to be electrically connected with the electrode 2, compared with a mode that the electric shock glove is started by touching the operation switch 41 with the other hand to generate the trigger signal, the starting mode can be completed only by one hand, and the problem that the electric shock glove cannot be started by both hands in time when a wearer is attacked can be solved. Based on this, the determining whether the start trigger signal is received includes: and judging whether a trigger signal sent by the operation switch 41 is received or not, or collecting a signal collected by the gesture operation sensor and judging whether a condition for generating the trigger signal is formed or not.

Further, the sensor assembly 44 further includes a biological information collecting sensor 443, the biological information collecting sensor 443 can collect biological information such as a fingerprint of the user, as shown in fig. 7, and the method further includes the following steps S801-S804:

step S801, acquiring signals acquired by the wearing state detection sensor and continuously monitoring the wearing state of the electric shock gloves;

step S802, when the wearing state is switched from a state of being worn to a state of not being worn to a state of being worn again, acquiring user data by the biological information acquisition sensor;

step S803, judging whether the user is a user with permission to use according to the collected user data;

step S804, when the user is a user with permission to use, entering a standby state. Here, the standby state is the state described in step S701.

Through step S802, the controller 42 can determine that the glove body 1 leaves the hand of the wearer and is worn again, and there is a possibility that the electric shock glove is snatched in the process, so that the identity of the wearer needs to be verified again, and the biological information collecting sensor can be directly arranged at the finger portion in the glove body 1, so that the user can collect the fingerprint information without scanning the fingerprint intentionally, and the user can collect the fingerprint information by wearing the glove, which is in accordance with the special situation in the emergency state, and avoids unnecessary danger caused by the user performing extra operations with distraction. Preferably, the biological information acquisition sensor and the glove body 1 and the ring wrist part 6 are designed to be separated, so that double guarantee can be achieved, and criminals are prevented from robbing the electric shock gloves to hurt police officers.

The utility model discloses an electric shock gloves is through arranging the electrode on the gloves body to set up power supply unit and the control unit for the electrode, make the electrode exportable voltage on the gloves body, the voltage of output so can act on the criminal and make the criminal lose the resistance ability, is favorable to improving and catches the success rate, the utility model discloses an electric shock gloves have convenient to use, be difficult for being robbed and do not hinder the advantage of wearing personnel both hands.

The above description is only a preferred embodiment of the present invention, and it should be noted that: for those skilled in the art, without departing from the principle of the present invention, several improvements and modifications can be made, and these improvements and modifications should also be considered as the protection scope of the present invention.

Claims (7)

1. An electric shock glove, characterized in that it comprises:

the glove comprises a glove body (1), wherein the glove body sequentially comprises a cutting-proof layer (12), a waterproof layer (14) and an inner liner (15) from outside to inside, and a wiring area for wiring is arranged between the cutting-proof layer (12) and the waterproof layer;

at least two electrodes (2) which are distributed and fixed on the glove body (1), wherein the distance between any two electrodes (2) is more than or equal to 5 cm;

a power supply unit (3) for supplying power to the electrode (2); and

a control unit (4) for controlling the connection between the power supply unit (3) and the electrode (2), comprising an operating switch (41).

2. The shockable glove of claim 1 wherein the parameters of the output of electricity from the power supply unit (3) are: the voltage range is 5-30KV, the current range is 7-15mA, the frequency is 0.5-5Hz, and the duty ratio is 50-95%.

3. The shockable glove of claim 2 wherein said power supply unit (3) outputs power at a frequency of 0.5 to 3Hz and at a duty cycle of 70 to 90%.

4. The shockable glove of claim 1 wherein a shield (16) is disposed between said waterproof layer and said inner liner, said shield (16) being a flexible conductive material.

5. The shocking glove of claim 1 wherein the electrodes (2) are embedded in a rubber shield (5), the rubber shield (5) being fixed to the surface of the cut-resistant layer (12) or to the glove body (1).

6. The shockable glove of claim 4 wherein said cut resistant layer (12) is aramid or high polyethylene.

7. The shockable glove of claim 1 wherein said control unit (4) further comprises:

a controller (42), wherein the operation switch (41) is connected with the controller (42);

an electrically controlled switch (43) interposed between the power supply unit (3) and the electrode (2) and electrically connected to the controller (42);

a sensor assembly (44) electrically connected to the controller (42) including a donning status detection sensor that can detect a donning status of the stun glove.

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