US20190331464A1

US20190331464A1 - Catching Glove Management System and Supervision Method

Info

Publication number: US20190331464A1
Application number: US16/475,099
Authority: US
Inventors: Zhiyong Jiang; Xiangang Xu; Weiqing JING; Liang Liu; Shuping ZHENG; Kai Liu
Original assignee: SHENZHEN SENXUNDA ELECTRONIC TECHNOLOGY Co Ltd
Current assignee: SHENZHEN SENXUNDA ELECTRONIC TECHNOLOGY Co Ltd
Priority date: 2017-07-31
Filing date: 2017-07-31
Publication date: 2019-10-31
Also published as: WO2019023826A1; CN108700397A; CN108700397B

Abstract

The present invention discloses an arrest glove management system and a monitoring method. The system includes a control end, a mobile terminal and an arrest glove; a monitoring APP capable of invoking a map is installed on the mobile terminal; the map is embedded into the control end; the arrest glove includes a glove body and pulse output electrodes; a power supply, a microprocessor, a pulse output circuit, a satellite positioning module and a wireless transmission module are disposed in the glove body; the microprocessor includes a pulse oscillation circuit and a booster circuit; the pulse output circuit includes a first output end and a second output end; a current output by the power supply sequentially passes through the pulse oscillation circuit and the booster circuit to convert into a set magnitude of pulse current; the pulse output electrodes are connected with the booster circuit via the pulse output circuit; and when the arrest glove is out of a scope of a predetermined use area, the power supply is controlled to disable an arrest function of the arrest glove. According to the arrest glove management system and the monitoring method provided by the present invention, the use process of the arrest glove can be monitored, the abuse of a police force is prevented, and the criminal suspect can be effectively controlled.

Description

PRIORITY

Applicant claims priority to PCT/CN2017/095097 entitled “Catching Glove Management System and Supervision Method” filed on Jul. 31, 2017.

TECHNICAL FIELD

The present invention relates to the field of arrest glove management, and in particular to an arrest glove management system and a monitoring method.

BACKGROUND

At present, the arrest and defense of a criminal suspect are mainly accomplished by hands of a people's police. Certainly, holding a sword, a spear and a club with a hand acts as a deterrent to the criminal suspect. However, the weapon in the hand is conspicuous and is hidden inconveniently to fight against an enemy or even may be captured and used by the enemy to hurt the police. Moreover, the weapon is stored troublesomely and carried inconveniently at ordinary times. In a utility model patent with the authorization No. CN 2358706 Y, there is provided a police anti-violence electric shock glove. The main technical solution is to adopt a high-voltage electric shock manner on the glove to meet the requirement of a police to perform an official business. However, the defect lies in that the high-voltage discharge can burn the human skin. The output voltage is tens of thousands of volts, and with such a high voltage, a certain damage will be caused to human heart and nervous centralis; and for a person suffering from a heart disease, the ventricular fibrillation will be caused by the high-voltage electric shock glove, or even the heart stops beating in a severe case.
A Chinese invention patent with the publication No. CN 102778173A discloses a police arrest glove, which includes an insulating sleeve, a first contact electrode, a second contact electrode and a body induction low-voltage pulse generator; the sleeve includes a palm side; the first contact electrode and the second contact electrode are disposed on the palm side in a mutually insulating manner, the body induction low-voltage pulse generator includes a first output electrode and a second output electrode; the first output electrode is electrically connected with the first contact electrode; the second output electrode is electrically connected with the second contact electrode; and when the first contact electrode and the second contact electrode are connected, the body induction low-voltage pulse generator outputs a current via the first output electrode and the second output electrode.
In an invention patent application with the publication No. CN 105146813A, there is disclosed an intelligent arrest glove. The intelligent arrest glove is connected by a glove body (1), palm electric shock pulse conductors (2), finger electric shock pulse conductors (3), suspension rings (4), a connection buckle (5), an adhesive tape (6), a switch (7), a battery (8), a hand back striking shell (9), finger striking shells (10) and a thumb striking piece (11), where two suspension rings (4) are connected on top ends of finger sleeves; the connection buckle (5) is connected at one side of a bottom end of the glove body (1); the adhesive tape (6) is connected at the other side of the bottom end of the glove body (1); a module is connected on a power wire; the module is connected with the palm electric shock pulse conductors and the finger electric shock pulse conductors via a circuit; the palm electric shock pulse conductors (2) are fixed at a palm of the glove body (1) by leather gaskets; the finger electric shock pulse conductors (3) are fixed at root places of four fingers by leather gaskets; the thumb striking piece (11) is fixed on a back side of a thumb of the glove; the hand back striking shell (9) is fixed in a middle of a back side of the glove body (1); the hand back striking shell (9) is of a shape in which four finger joints are raised; the finger striking shells (10) are fixed on an upper end of the back side of the glove body (1); each of the finger striking shells (10) is of a peach raised shape; the switch (7) is fixed at one side of a lower edge of the hand back striking shell (9) on the back side of the glove body (1); the switch (7) is connected with the battery (8) via the power wire; the module is connected on the power wire; and the module is connected to the palm electric shock pulse conductors (2) and the finger electric shock pulse conductors (3) via the circuit.
Concerning the above various arrest gloves, the problem of injury of the electric shock glove in the prior art is solved to a certain extent. But such a manner still has the following problems: as a police law enforcement device, the arrest glove is not monitored in use and obviously has a blank in the monitoring aspect to lead to the abuse of the police force; and in addition, a non-exposed skin portion cannot be effectively controlled.

SUMMARY

The technical problem to be solved by the present invention for the above defect in the prior art is to provide an arrest glove management system capable of monitoring a use process of an arrest glove, preventing the abuse of a police force and effectively controlling a criminal suspect, and a monitoring method.
The technical solutions adopted by the present invention to solve the technical problem are as follows: an arrest glove management system includes a control end, a mobile terminal and an arrest glove; a monitoring APP capable of invoking a map is installed on the mobile terminal; the map is embedded into the control end; a predetermined use area and use time of the arrest glove are set via the control end; and the mobile terminal sends an application for enabling an arrest function to the control end via the monitoring APP, and enables the arrest function of the arrest glove upon the reception of a response of the control end;
the arrest glove includes a glove body and pulse output electrodes covered on a palm side of the glove body; a power supply, a microprocessor, a pulse output circuit, a satellite positioning module and a wireless transmission module are disposed in the glove body; the microprocessor includes a pulse oscillation circuit and a booster circuit; a current output by the power supply sequentially passes through the pulse oscillation circuit and the booster circuit to convert into a set magnitude of pulse current; and the pulse output electrodes are connected with the booster circuit via the pulse output circuit;
the satellite positioning module acquires geographical position data of the arrest glove in real time and sends the geographical position data to the microprocessor, the microprocessor receives predetermined use area information sent by the wireless transmission module and decodes the predetermined use area information to obtain predetermined monitoring area data; the microprocessor compares the geographical position data of the arrest glove with the predetermined monitoring area data; when the arrest glove is within a scope of the predetermined use area, the microprocessor has no action, and when the arrest glove is out of the scope of the predetermined use area, the microprocessor transmits an alarm signal and the geographical position data of the arrest glove to the monitoring APP via the wireless transmission module and controls the power supply to disable the arrest function of the arrest glove; and the mobile terminal records geographical position information of the arrest glove in each communication via the monitoring APP, and presents a historical track of the arrest glove on the map in a manner of connecting points into a line.
In the arrest glove management system provided by the present invention, a first timer for recording enabling time or disabling time of the arrest function is further built in the microprocessor.
In the arrest glove management system provided by the present invention, the pulse output circuit includes a first output end and a second output end; a second timer is further disposed in the glove body; and the second timer is disposed between the first output end and the second output end, and is configured to record a connected duration of the arrest glove in an arrest.
In the arrest glove management system provided by the present invention, a sampling circuit is further disposed in the glove body; sampling endpoints are arranged on the palm side of the glove body; and the sampling circuit is respectively connected with the microprocessor and the sampling endpoints, and is configured to measure a resistance value of an object captured by the palm side of the glove body.
In the arrest glove management system provided by the present invention, the pulse current is output by the first output end and the second output end; the pulse output electrodes are respectively connected with the first output end and the second output end; the booster circuit includes a first booster circuit, a second booster circuit and a shift switch; the shift switch includes a movable end, a first static end, a second static end and a third static end; one end of the first booster circuit is connected with the pulse oscillation circuit, and the other end of the first booster circuit is connected with the movable end; the first static end is grounded, the second static end is respectively connected with the first output end and the second output end, the third static end is connected with one end of the second booster circuit, and the other end of the second booster circuit is respectively connected with the first output end and the second output end; when the shift switch is shifted to the first static end, the arrest glove is in a closed state; when the shift switch is shifted to the second static end, each of the pulse output electrodes outputs a low-voltage pulse current of which the pulse parameter scope is 320-380 V, 15-30 mA and 25-30 Hz; and when the shift switch is shifted to the third static end, each of the pulse output electrodes outputs a high-voltage pulse current of which the pulse parameter scope is 2000-20000 V, 0.25-3 mA and 25-50 Hz.
In the arrest glove management system provided by the present invention, protrusions for preventing knife cutting and reinforcing an attack are disposed on a back side of the glove body, and the protrusions are made of a glass fiber, an Acrylonitrile Butadiene Styrene (ABS), a Polycarbonate (PC) or a carbon fiber.
In the arrest glove management system provided by the present invention, the pulse output electrodes are attached to the palm side of the glove body by using conductive fabrics, or are hidden in the palm side of the glove body by using elastic electrode needles, and when the palm side of the glove body is stressed, the electrode needles are bounced out.
In the arrest glove management system provided by the present invention, a tangent side of the glove body includes an inner layer for fitting a hand of a wearer, a shielding layer for preventing a current from accidentally injuring the wearer and an anti-cutting layer for taking a knife in an actual combat that are arranged sequentially from inside out; the anti-cutting layer is made of a Kevlar material or a high-strength high-modulus polyethylene fiber coated glass fiber, a spandex or a steel wire; the tangent side of the glove body further includes an outer layer arranged out of the anti-cutting layer; and a gap for arranging a conductive fabric is formed on the anti-cutting layer or the outer layer.
The present invention further relates to a monitoring method using the arrest glove management system, which includes the following steps:
A) opening a monitoring APP installed on a mobile terminal, and invoking a map via the monitoring APP;
B) setting, by a user, a predetermined use area and use time of an arrest glove on a control end;
C) sending, by the monitoring APP, an application for enabling an arrest function to the control end, and enabling the arrest function of the arrest glove upon the reception of a response of the control end;
D) acquiring, by a satellite positioning module, geographical position data of the arrest glove in real time and sending the geographical position data to a microprocessor, and judging, by the microprocessor, whether or not the arrest glove is within the predetermined use area, if yes, executing the step F), or otherwise, executing the step E);
E) transmitting, by the microprocessor, an alarm signal and the geographical position data of the arrest glove to the monitoring APP of the mobile terminal via a wireless transmission module to give an alarm and controlling a power supply to disable the arrest function of the arrest glove, and recording, by the mobile terminal, geographical position information of the arrest glove in each communication via the monitoring APP and presenting a historical track of the arrest glove on the map in a manner of connecting points into a line; and
F) keeping an arrested state without alarming.
The monitoring method using the arrest glove management system provided by the present invention further includes after the step F):
G) collecting, by a sampling circuit, a resistance of an object captured by a palm side of the arrest glove and sending the collected resistance value to the microprocessor to execute the step H);
H) judging, by the microprocessor, whether or not the collected resistance value is greater than a set value, if yes, executing the step I), or otherwise, executing the step J);
I) sequentially passing a current through a first booster circuit, a second booster circuit and a pulse output circuit, and outputting a high-voltage pulse current of 2000-20000 V, 0.25-3 mA and 25-50 Hz from pulse output electrodes; and
J) sequentially passing the current through the first booster circuit and the pulse output circuit, and outputting a low-voltage pulse current of 320-380 V, 15-30 mA and 25-30 Hz from pulse output electrodes.
The arrest glove management system and the monitoring method provided by the present invention have the following beneficial effects: since the control end, the mobile terminal and the arrest glove are provided; the arrest glove includes the glove body and the pulse output electrodes; the power supply, the microprocessor, the pulse output circuit, the satellite positioning module and the wireless transmission module are disposed in the glove body; the microprocessor includes the pulse oscillation circuit and the booster circuit; when the arrest glove is out of the scope of the predetermined use area, the microprocessor transmits the alarm signal and the geographical position data of the arrest glove to the monitoring APP via the wireless transmission module and controls the power supply to disable the arrest function of the arrest glove, and thus the monitoring on the arrest glove is implemented. Therefore, the use process of the arrest glove can be monitored, the abuse of the police force is prevented and the criminal suspect can be effectively controlled.

BRIEF DESCRIPTION OF DRAWINGS

In order to describe the technical solutions in the embodiments of the present invention or in the prior art more clearly, a simple introduction to the accompanying drawings which are needed in the description of the embodiments or the prior art is given below. Apparently, the accompanying drawings in the description below are merely some of the embodiments of the present invention, based on which other drawings may be obtained by those of ordinary skill in the art without any creative effort.

FIG. 1 is a structural schematic diagram of a system in one embodiment of an arrest glove management system and a monitoring method provided by the present invention;

FIG. 2 is a schematic diagram of a palm side of an arrest glove in the embodiment;

FIG. 3 is another schematic diagram of a palm side of an arrest glove in the embodiment;

FIG. 4 is a schematic diagram of a back side of an arrest glove in the embodiment; and

FIG. 5 is a flowchart of a monitoring method in the embodiment.

DESCRIPTION OF EMBODIMENTS

A clear and complete description of the technical solutions in the embodiments of the present invention will be given below, in combination with the accompanying drawings in the embodiments of the present invention. Apparently, the embodiments described below are a part, but not all, of the embodiments of the present invention. All of the other embodiments, obtained by those of ordinary skill in the art based on the embodiments of the present invention without any inventive efforts, fall into the protection scope of the present invention.
In an embodiment of an arrest glove management system and a monitoring method provided by the present invention, the structural schematic diagram of the arrest glove management system is as shown in FIG. 1. In FIG. 1, the arrest glove management system includes a control end 1, a mobile terminal 2 and an arrest glove 3, where a monitoring APP is installed on the mobile terminal 2; a map may be invoked via the monitoring APP; the map is also embedded into the control end 1; a predetermined use area and use time of the arrest glove are set via the control end 1; and the mobile terminal 2 sends or submits an application for enabling an arrest function to the control end 1 via the monitoring APP, and enables the arrest function of the arrest glove 3 upon the reception of a response of the control end 1. It is to be noted that the mobile terminal 2 may be an intelligent mobile phone, a tablet computer or a Personal Digital Assistant (PDA), etc.
In this embodiment, the arrest glove 3 includes a glove body 31 and pulse output electrodes 32, and the pulse output electrodes 32 are covered on a palm side of the glove body 31. FIG. 2 is a schematic diagram of a palm side of an arrest glove in this embodiment. As may be seen from FIG. 2, the pulse output electrodes 32 are covered on the palm side of the glove body 31. The pulse output electrodes 32 may be covered on the palm side of the glove body 31 in an upper and lower arrangement manner, or a left and right arrangement manner, or other parallel arrangement manners.
A power supply 33, a microprocessor 34, a pulse output circuit 35, a satellite positioning module 36 and a wireless transmission module 37 are disposed in the glove body 31; the microprocessor 34 includes a pulse oscillation circuit 341 and a booster circuit 342; a current output by the power supply 33 sequentially passes through the pulse oscillation circuit 341 and the booster circuit 342 to convert into a set magnitude of pulse current; and the pulse output electrodes 32 are connected with the booster circuit 342 via the pulse output circuit 35. It is to be noted that the set magnitude of pulse current is a pulse current of 300-400 V, 10-35 mA and 25-35 Hz.
In this embodiment, the satellite positioning module 36 acquires geographical position data of the arrest glove 3 in real time and sends the geographical position data to the microprocessor 34; the microprocessor 34 receives predetermined use area information sent by the wireless transmission module 37 and decodes the predetermined use area information to obtain predetermined monitoring area data; the microprocessor 34 compares the geographical position data of the arrest glove 3 with the predetermined monitoring area data; when the arrest glove 3 is within a scope of the predetermined use area, the microprocessor has no action, and when the arrest glove 3 is out of the scope of the predetermined use area, the microprocessor 34 transmits an alarm signal and the geographical position data of the arrest glove 3 to the monitoring APP of the mobile terminal 2 via the wireless transmission module 37 and controls the power supply 33 to disable the arrest function of the arrest glove 3; and the mobile terminal 2 records geographical position information of the arrest glove 3 in each communication via the monitoring APP, and presents a historical track of the arrest glove 3 on the map in a manner of connecting points into a line. In this way, the monitoring function on the arrest glove 3 is implemented; and therefore, the use process of the arrest glove 3 can be monitored, the abuse of a police force is prevented, and the criminal suspect can be effectively controlled.
It is to be noted that the wireless transmission module 37 may be a Bluetooth module, an infrared module, a Wireless Fidelity (Wi-Fi) module, a General Packet Radio Service (GPRS) module, a Zibgee module, a Code Division Multiple Access (CDMA) module, a Wideband Code Division Multiple Access (WCDMA) or a LoRa module, etc. For the GPRS module, the GPRS module may be a 2G module, a 3G module or a 4G module, etc. By providing multiple wireless communication manners, the requirements of different users may be met and the flexibility of communication is increased. Particularly, when the LoRa module is adopted, the transmission distance is far and the communication is stable.
In this embodiment, a first timer (not shown in the figure) is further built in the microprocessor 34. The first timer is configured to record enabling time or disabling time of the arrest function.
In this embodiment, the pulse output circuit 35 includes a first output end 351 and a second output end 352; a second timer 38 is further disposed in the glove body 31; and the second timer 38 is disposed between the first output end 351 and the second output end 352, and is configured to record a connected duration of the arrest glove 3 in an arrest, i.e., a duration for a pulse released when a criminal suspect is captured; and the quantity of electric charges received by the criminal suspect and the time may be calculated via an output power. In addition, the connected duration in the arrest is recorded by the second timer 38, and the connected duration may further be compared with the predetermined use time.
In this embodiment, the pulse current is output by the first output end 351 and the second output end 352; the pulse output electrodes 32 are respectively connected with the first output end 351 and the second output end 352; the booster circuit 342 includes a first booster circuit 343, a second booster circuit 344 and a shift switch K; the shift switch K includes a movable end, a first static end, a second static end and a third static end; the shift switch K is a single-pole multi-throw switch; and the shift switch K may adopt a manner of a rotary knob switch, and may also adopt a manner of a toggle switch. One end of the first booster circuit 343 is connected with the pulse oscillation circuit 341, and the other end of the first booster circuit 343 is connected with the movable end; the first static end is grounded, the second static end is respectively connected with the first output end 351 and the second output end 352, the third static end is connected with one end of the second booster circuit 344, and the other end of the second booster circuit 344 is respectively connected with the first output end 351 and the second output end 352. When the shift switch K is shifted to the second static end, a low-voltage solution is provided. When the shift switch K is shifted to the third static end, a high-voltage solution is provided. By integrating the high-voltage solution and the low-voltage solution into the same glove, when the weather is hot or the body skin of the criminal suspect is exposed too much, the low-voltage solution is used for arresting, thus being safe and efficient. When the criminal suspect wears too much, the high-voltage solution is used with high efficiency; and since the current may penetrate through clothes, the criminal suspect can be effectively controlled.
Specifically, when the shift switch K is shifted to the first static end, the arrest glove 3 is in a closed state; when the shift switch K is shifted to the second static end, each of the pulse output electrodes 32 outputs a low-voltage pulse current of which the pulse parameter scope is 320-380 V, 15-30 mA and 25-30 Hz, thus forming the low-voltage solution; and when the shift switch K is shifted to the third static end, each of the pulse output electrodes 32 outputs a high-voltage pulse current of which the pulse parameter scope is 2000-20000 V, 0.25-3 mA and 25-50 Hz, thus forming the high-voltage solution.
It is to be noted that, in some cases of this embodiment, the shift switch K may further include more static ends. At this moment, the shift switch becomes a single-pole four-throw switch, a single-pole five-throw switch, a single-pole six-throw switch and the like; and more corresponding booster circuits 342 may further be provided, i.e., the booster circuit 342 may further include a third booster circuit, a fourth booster circuit and the like for different clothes.
FIG. 3 is another schematic diagram of a palm side of an arrest glove in this embodiment. In this embodiment, a sampling circuit 39 is further disposed in the glove body 31; sampling endpoints 40 are arranged on the palm side of the glove body 31; and the sampling circuit 40 is respectively connected with the microprocessor 34 and the sampling endpoints 40, and is configured to measure a resistance value of an object captured by the palm side of the glove body 31. When the measured resistance value is greater than 2000 ohms, the pulse output circuit 35 outputs the current of 2000-20000 V, 0.25-3 mA and 25-50 Hz via the first booster circuit 343 and the second booster circuit 344. When the measured resistance value is smaller than or equal to 2000 ohms, the pulse output circuit 35 outputs the current of 320-380 V, 15-30 mA and 25-30 Hz via the first booster circuit 343, the first output end 351, the second output end 352 and the pulse output electrodes 32.
FIG. 4 is a schematic diagram of a back side of an arrest glove in this embodiment. Protrusions 5 for preventing knife cutting and reinforcing an attack are disposed on a back side of the glove body 31. The protrusions 5 are specifically disposed at each finger on the back side of the glove body 31. The protrusions 5 may be made of a glass fiber, an ABS, a PC or a carbon fiber, etc.
Preferably, the pulse output electrodes 32 are attached to the palm side of the glove body 31 by using conductive fabrics, and may also be hidden in the palm side of the glove body 31 by using elastic electrode needles, where when the palm side of the glove body is stressed, the electrode needles are bounced out.
In this embodiment, a tangent surface of the glove body 31 includes an inner layer, a shielding layer and an anti-cutting layer (not shown in the figure) arranged sequentially from inside out, where the inner layer is configured to fit a hand of a wearer, the shielding layer is configured to prevent a current from accidentally injuring the wearer and the anti-cutting layer is configured to take a knife in an actual combat. The anti-cutting layer is made of a Kevlar material or a high-strength high-modulus polyethylene fiber coated glass fiber, a spandex or a steel wire, and a gap for arranging a conductive fabric is formed on the anti-cutting layer or the outer layer. Certainly, an outer layer may also be disposed out of the anti-cutting layer, i.e., the tangent surface of the glove body 31 further includes the outer layer disposed out of the anti-cutting layer; and a gap for disposing a conductive fabric is formed on the outer layer.
The present invention further relates to a monitoring method using the arrest glove management system, and the flowchart is as shown in FIG. 5. In FIG. 5, the monitoring method using the arrest glove management system includes the following steps.
Step S01: Open a monitoring APP installed on a mobile terminal, and invoke a map via the monitoring APP. In this step, the monitoring APP installed on the mobile terminal is opened, and the map is invoked via the monitoring APP.
Step S02: A user sets a predetermined use area and use time of an arrest glove on a control end. In this step, the user sets the predetermined use area and the use time of the arrest glove on the control end.
Step S03: The monitoring APP sends an application for enabling an arrest function to the control end, and enables the arrest function of the arrest glove upon the reception of a response of the control end. In this step, the monitoring APP sends the application for enabling the arrest function to the control end via a wireless manner, the control end makes a response upon the reception of the application for enabling the arrest function, and the monitoring APP enables the arrest function of the arrest glove upon the reception of the response of the control end.
Step S04: A satellite positioning module acquires geographical position data of the arrest glove in real time and sends the geographical position data to a microprocessor, and the microprocessor judges whether or not the arrest glove is within the predetermined use area. In this step, the satellite positioning module acquires the geographical position data of the arrest glove in real time and sends the geographical position data to the microprocessor, the microprocessor judges whether or not a position of the arrest glove is within the predetermined use area, if a judgment result is that the position of the arrest glove is within the predetermined use area, the step S06 is executed, or otherwise, the step 05 is executed.
Step S05: The microprocessor transmits an alarm signal and the geographical position data of the arrest glove to the monitoring APP of the mobile terminal via a wireless transmission module to give an alarm and controls a power supply to disable the arrest function of the arrest glove, and the mobile terminal records geographical position information of the arrest glove in each communication via the monitoring APP and presents a historical track of the arrest glove on the map in a manner of connecting points into a line. In this step, the microprocessor transmits the alarm signal and the geographical position data of the arrest glove to the monitoring APP of the mobile terminal via the wireless transmission module to give the alarm to remind the user, and then controls the power supply to disable the arrest function of the arrest glove.
Step S06: Keep an arrested state without alarming. If the judgment result in the step S04 is that the position of the arrest glove is within the predetermined use area, this step is executed. In this step, the arrested state is kept without alarming. In this way, the monitoring function on the arrest glove is implemented; and therefore, the use process of the arrest glove can be monitored, the abuse of a police force is prevented, and the criminal suspect can be effectively controlled.
In this embodiment, after the completion of the step S06, the following steps may further be executed.
Step 07: A sampling circuit collects a resistance of an object captured by a palm side of the arrest glove and sends the collected resistance value to the microprocessor. In this step, the sampling circuit collects the resistance of the object captured by the palm side of the arrest glove, and sends the collected resistance value to the microprocessor. After the completion of this step, the step 08 is executed.
Step 08: The microprocessor judges whether or not the collected resistance value is greater than a set value. In this step, the microprocessor judges whether or not the collected resistance value is greater than the set value, if a judgment result is that the resistance value is greater than the set value, the step S10 is executed, or otherwise, the step 09 is executed.
Step 09: A current sequentially passes through a first booster circuit and a pulse output circuit, and a low-voltage pulse current of 320-380 V, 15-30 mA and 25-30 Hz is output from pulse output electrodes. If the judgment result in the step S08 is that the resistance value is not greater than the set value, this step is executed. In this step, the current sequentially passes through the first booster circuit and the pulse output circuit, and the low-voltage pulse current of 320-380 V, 15-30 mA and 25-30 Hz is output from the pulse output electrodes.
Step 10: A current sequentially passes through a first booster circuit, a second booster circuit and a pulse output circuit, and a high-voltage pulse current of 2000-20000 V, 0.25-3 mA and 25-50 Hz is output from pulse output electrodes. If the judgment result in the step S08 is that the resistance value is greater than the set value, this step is executed. In this step, the current sequentially passes through the first booster circuit, the second booster circuit and the pulse output circuit, and the high-voltage pulse current of 2000-20000 V, 0.25-3 mA and 25-50 Hz is output from the pulse output electrodes. By integrating the high-voltage solution and the low-voltage solution into the same glove, the abuse of the police force is prevented and the criminal suspect can be effectively controlled.
In conclusion, according to the monitoring method provided by the present invention, with the shift of the shift switch K, the low-voltage solution and the high-voltage solution may be switched there between. By integrating the high-voltage solution and the low-voltage solution into the same glove, when the weather is hot or the body skin of the criminal suspect is exposed too much, the low-voltage solution is used for arresting, thus being safe and efficient; when the criminal suspect wears too much, the high-voltage solution is used with high efficiency; and since the current may penetrate through clothes, the criminal suspect can be effectively controlled. When the arrest glove 3 is out of the scope of the predetermined use area, the microprocessor 34 transmits the alarm signal and the geographical position data of the arrest glove 3 to the monitoring APP via the wireless transmission module, and controls the power supply 33 to disable the arrest function of the arrest glove 3, and thus the monitoring on the arrest glove 3 is implemented. Therefore, the use process of the arrest glove 3 can be monitored, the abuse of the police force is prevented and the criminal suspect can be effectively controlled.
The above are merely preferred embodiments of the present invention and are not intended to limit the present invention. Any modification, equivalent replacement and improvement made within the spirit and principle of the present invention all should be included in the protection scope of the present invention.

Claims

What is claimed is:

1. (canceled)

2. (canceled)

3. (canceled)

4. (canceled)

5. (canceled)

6. (canceled)

7. (canceled)

8. (canceled)

9. (canceled)

10. (canceled)

11) An arrest glove management system for use with a criminal suspect; the arrest glove management system comprising:

a) a control end (1) controlling operation of the glove management system, wherein the control end (1) is adapted for:

i) authorizing a predetermined time and geographic area of use for operation of the glove management system; and

ii) intercommunicating with a mobile terminal (2);

b) the mobile terminal (2) comprising a monitoring APP; the monitoring APP intercommunicating with the control end (1) and an arrest glove (3), wherein upon authorization from the control end (1), the monitoring APP enables arrest functions of arrest glove (3) for the predetermined time and geographic area and records a historical record of the arrest glove's (3) use and transmits the historical record to the control end (1); and

c) the arrest glove (3) comprising a glove body (31); the glove body (31) comprising:

i) a power supply (33) and one or more pulse output electrodes (32) connected with a pulse output circuit (34); the pulse output circuit (34) comprising a first output end (351) and a second output end (352) for delivery of electricity to the pulse output electrodes (32);

ii) a microprocessor (34) intercommunicating with:

a wireless communication module (37) intercommunicating with the mobile terminal (2);

a pulse oscillation circuit (341) connected with a booster (342) comprising a first booster circuit (343); the booster (342) connected with the pulse oscillation circuit (341) and a switch (K) adapted for connection with a second booster circuit (344), the first output end (351) or the second output end (352) such that the position of switch (K) causes a higher or a lower voltage delivery to the one or more pulse output electrodes (32);

iii) a satellite positioning module (36) adapted to monitor a location of the arrest glove (3); the satellite positioning module (36) intercommunicating with the microprocessor (34) and causing the microprocessor (34) to forward an alarm to the monitoring APP when the arrest glove (3) is located outside the predetermined area; and

iv) a first timer for disabling the arrest glove (3) after the predetermined time is exceeded.

12) The arrest glove management system according to claim 11 comprising a second timer intercommunicating with the microprocessor (34); the second timer recording duration of delivery of the higher or the lower voltage to the one or more pulse output electrodes (32).

13) The arrest glove management system according to claim 12; the glove body (31) comprising one or more sampling end points (40) communicating with the microprocessor (34), wherein the one or more sampling end points (40) measures an electrical resistance value for the object contacted by the one or more sampling end points (40).

14) The arrest glove management system according to claim 13, wherein

a) the lower voltage pulse parameter's range is from about 320-380 V, 15-30 mA and 25-30 Hz; and

b) the higher voltage pulse parameter's range is from about 2000-20000 V, 0.25-3 mA and 25-50 Hz.

15) The arrest glove management system of claim 14, wherein the glove body (31) comprises:

a) an inner layer contacting the user's hand;

b) a shielding layer shielding the user of the arrest glove (3) from electricity delivered to the one or more pulse output electrodes (32); and

c) an anti-cutting layer to defend against a knife used by the criminal suspect, wherein the anti-cutting layer comprises one or more of the following: aramid fibers, a high-strength high-modulus polyethylene fiber coated glass fiber, a spandex and/or a steel wire,

16) The arrest glove management system of claim 15, wherein the one or more pulse output electrodes (32) are:

a) connected with conductive fabrics covering a palm side of glove body (31); or

b) extend beyond the palm side of the glove body (31) when use of the glove body (31) applies stress to the glove body (31).

17) The arrest glove management system of claim 16; the back side of the glove body (31) comprising reinforcing protrusions, wherein the reinforcing protrusions comprise one or more of the following: a glass fiber, an acrylonitrile butadiene styrene (ABS), a polycarbonate (PC) or a carbon fiber or any combination thereof.

18) A method of using an arrest glove management system with a criminal suspect; the method comprising the steps of:

a) establishing a control end (1) controlling operation of the glove management system, wherein the control end (1) is adapted for authorizing a predetermined time and geographic area of use for operation of the glove management system; ii)

b) providing a mobile terminal (2) comprising a monitoring APP; the monitoring APP intercommunicating with the control end (1) and an arrest glove (3), wherein upon authorization from the control end (1), the monitoring APP enables arrest functions of arrest glove (3) for the predetermined time and geographic area and records a historical record of the arrest glove's (3) use and transmits the historical record to the control end (1); and

c) providing the arrest glove (3) comprising a glove body (31); the glove body (31) comprising:

ii) a microprocessor (34) intercommunicating with:

iv) a first timer for disabling the arrest glove (3) after the predetermined time is exceeded;

d) requesting the predetermined time and the predetermined area of use by the user of the arrest glove (3) from control end (1);

e) granting authorization by control end (1) for use of the arrest glove (3) to the monitoring APP, thereby enabling use of the arrest glove (3) on the criminal suspect; and

e) unless disabled prior to use on the criminal suspect, applying the arrest glove (3) to the criminal suspect.

19) The method of using an arrest glove management system with a criminal suspect of claim 9; wherein the user of the arrest glove (3) can select step of applying:

a) the lower voltage pulse parameter's range from about 320-380 V, 15-30 mA and 25-30 Hz to the criminal suspect; or

b) the higher voltage pulse parameter's range from about 2000-20000 V, 0.25-3 mA and 25-50 Hz to the criminal suspect.

20) The method of using an arrest glove management system with a criminal suspect of claim 19 comprising the step of providing the glove body (31) with one or more sampling end points (40) communicating with the microprocessor (34), wherein the one or more sampling end points (40) measures an electrical resistance value for the object contacted by the one or more sampling end points (40).

21) The method of using an arrest glove management system with a criminal suspect of claim 20, wherein the microprocessor (34) judges whether the step of applying:

a) the lower voltage pulse parameter's range from about 320-380 V, 15-30 mA and 25-30 Hz to the criminal suspect is utilized; or

b) the higher voltage pulse parameter's range from about 2000-20000 V, 0.25-3 mA and 25-50 Hz to the criminal suspect is utilized.