阅读说明：本技术 枪械安全控制装置 (Firearm safety control device ) 是由 陈飞 胡可 王玮 黄飞跃 闵奕波 符海琳 于 2019-10-24 设计创作，主要内容包括：本发明公开一种枪械安全控制装置,该枪械安全控制装置的电池模块、运动感知模块、远程通信模块、身份验证模块和电子开锁模块分别与控制器互相电连接,锁体的输入端与电子开锁模块的输出端连接；运动感知模块,获取控制器的运动状态,并输出运动状态信号至控制器；控制器根据输出运动状态信号,输出第一控制信号以控制远程通信模块的开启/关闭；远程通信模块,接收远程服务器的授权信号,并输出第一开锁信号至控制器；身份验证模块,接收枪械使用者的生物识别信号并进行验证,验证通过后输出第二开锁信号至控制器；电子开锁模块,用于根据第一开锁信号和/或第二开锁信号,控制锁体的开启。本方案提升了涉枪单位对于枪械使用的安全性。(The invention discloses a firearm safety control device, wherein a battery module, a motion sensing module, a remote communication module, an identity verification module and an electronic unlocking module of the firearm safety control device are respectively and electrically connected with a controller, and the input end of a lock body is connected with the output end of the electronic unlocking module; the motion sensing module acquires the motion state of the controller and outputs a motion state signal to the controller; the controller outputs a first control signal to control the opening/closing of the remote communication module according to the output motion state signal; the remote communication module receives an authorization signal of the remote server and outputs a first unlocking signal to the controller; the identity authentication module receives and authenticates a biological identification signal of a firearm user, and outputs a second unlocking signal to the controller after the authentication is passed; and the electronic unlocking module is used for controlling the unlocking of the lock body according to the first unlocking signal and/or the second unlocking signal. This scheme has promoted and has waded the security of rifle unit to the firearms use.)

1. A firearm safety control device is characterized by comprising a battery module, a motion sensing module, a remote communication module, a controller, an identity verification module, an electronic unlocking module and a lock body;

the battery module, the motion sensing module, the remote communication module, the identity verification module and the electronic unlocking module are electrically connected with the controller respectively, and the input end of the lock body is connected with the output end of the electronic unlocking module;

the motion sensing module is used for acquiring the motion state of the controller and outputting a motion state signal to the controller;

the controller is used for outputting a first control signal to the remote communication module according to the motion state signal output by the motion sensing module so as to control the opening/closing of the remote communication module;

the remote communication module is used for receiving an authorization signal of a remote server and outputting a first unlocking signal to the controller;

the identity authentication module is used for receiving and authenticating a biological identification signal of a firearm user and outputting a second unlocking signal to the controller after the authentication is passed;

and the electronic unlocking module is used for controlling the unlocking of the lock body according to the first unlocking signal and/or the second unlocking signal.

2. The firearm safety control device according to claim 1, further comprising a positioning module, the positioning module being electrically interconnected with the controller;

the controller is further used for outputting a motion state signal according to the motion sensing module and outputting a second control signal to the positioning module so as to control the opening/closing of the positioning module;

the positioning module is used for positioning a firearm and outputting a firearm position signal to the remote communication module through the controller.

3. The firearm safety control device of claim 2, wherein the positioning module is a GPS module or a beidou module.

4. The firearm safety control device according to claim 1, further comprising a power management module coupled between the battery module and the controller;

and the power supply management module is used for detecting the electric quantity signal and the charge-discharge state signal of the battery module and outputting the electric quantity signal and the charge-discharge state signal to the controller.

5. The firearm safety control device according to claim 4, further comprising a short-range communication module electrically interconnected with the controller;

the controller is further used for outputting an electric quantity signal detected by the power management module to the short-range communication module;

the short-range communication module is used for receiving the biological identification signal or the erasing signal of the short-range server and outputting the biological identification signal or the erasing signal to the controller.

6. The firearm safety control device of claim 5, wherein the short-range communication module is a Bluetooth module or an NFC module.

7. The firearm safety control device according to claim 4, wherein the firearm safety control device further comprises a USB port;

and the USB port is used for outputting the electric quantity signal and the charge-discharge state signal detected by the power management module to the short-range communication module.

8. The firearm safety control device of claim 1, wherein the authentication module is a fingerprint module.

9. The firearm safety control device of claim 1, wherein the remote communication module is a cellular mobile communication module.

10. The firearm safety control device of any of claims 1-9, wherein the lock body comprises a mechanical unlocking module coupled to the lock body.

Technical Field

The invention relates to the technical field of circuit control, in particular to a firearm safety control device.

Background

Aiming at armed escort enterprises and other gun-related units, after a firearm manager gives the firearm to a user, the firearm can be subjected to non-rational firing or illegal firing by other people except the user. Firing of a firearm involves three general actions, opening the safety, loading the cartridge, and cocking the trigger. However, the safety control of the use of firearms by firearms managers is currently in a management blind area, which causes the firearms managers to release the firearms to users and then to be in a non-controllable state.

Disclosure of Invention

The invention mainly aims to provide a firearm safety control device, aiming at improving the safety of a gunnery for the use of firearms.

In order to achieve the purpose, the firearm safety control device provided by the invention comprises a battery module, a motion sensing module, a remote communication module, a controller, an identity verification module, an electronic unlocking module and a lock body;

the battery module, the motion sensing module, the remote communication module, the identity verification module and the electronic unlocking module are electrically connected with the controller respectively, and the input end of the lock body is connected with the output end of the electronic unlocking module;

the motion sensing module is used for acquiring the motion state of the controller and outputting a motion state signal to the controller;

the controller is used for outputting a first control signal to the remote communication module according to the motion state signal output by the motion sensing module so as to control the opening/closing of the remote communication module;

the remote communication module is used for receiving an authorization signal of a remote server and outputting a first unlocking signal to the controller;

the identity authentication module is used for receiving and authenticating a biological identification signal of a firearm user and outputting a second unlocking signal to the controller after the authentication is passed;

and the electronic unlocking module is used for controlling the unlocking of the lock body according to the first unlocking signal and/or the second unlocking signal.

Optionally, the firearm safety control device further comprises a positioning module, wherein the positioning module is electrically connected with the controller;

the controller is further used for outputting a motion state signal according to the motion sensing module and outputting a second control signal to the positioning module so as to control the opening/closing of the positioning module;

the positioning module is used for positioning a firearm and outputting a firearm position signal to the remote communication module through the controller.

Optionally, the positioning module is a GPS module or a beidou module.

Optionally, the firearm safety control device further comprises a power management module, and the power management module is connected between the battery module and the controller;

and the power supply management module is used for detecting the electric quantity signal and the charge-discharge state signal of the battery module and outputting the electric quantity signal and the charge-discharge state signal to the controller.

Optionally, the firearm safety control device further comprises a short-range communication module electrically interconnected with the controller;

the controller is further used for outputting an electric quantity signal detected by the power management module to the short-range communication module;

the short-range communication module is used for receiving the biological identification signal or the erasing signal of the short-range server and outputting the biological identification signal or the erasing signal to the controller.

Optionally, the short-range communication module is a bluetooth module or an NFC module.

Optionally, the firearm safety control device further comprises a USB port;

and the USB port is used for outputting the electric quantity signal and the charge-discharge state signal detected by the power management module to the short-range communication module.

Optionally, the identity verification module is a fingerprint module.

Optionally, the remote communication module is a cellular mobile communication module.

Optionally, the lock body comprises a mechanical unlocking module, the mechanical unlocking module being connected with the lock body.

According to the technical scheme, the motion state of the controller is obtained through the motion sensing module in the firearm safety control device, when the controller is in a moving state, the motion sensing module outputs a motion state signal to the controller, and the controller outputs a first control signal according to the received motion state signal so as to control the remote communication module to be started. After the remote communication module is opened, a firearm manager can remotely authorize through the remote communication module, and the remote communication module outputs a first unlocking signal. Thereby improving the safety of the firearm in use. Meanwhile, the identity authentication module in the firearm safety control device can receive the biological identification signal of the firearm user for authentication, verify whether the firearm user is a legal user, and after the identity authentication is passed, the identity authentication module outputs a second unlocking signal. Therefore, the identification of the firearm user is improved. After the remote communication module outputs a first unlocking signal and/or the identity verification module outputs a second unlocking signal, the electronic unlocking module in the firearm safety control device can control the unlocking of the lock body. The technical scheme of the invention improves the safety of the gun-related unit for the use of firearms.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the structures shown in the drawings without creative efforts.

FIG. 1 is a schematic structural diagram of a firearm safety control device according to an embodiment of the present invention;

FIG. 2 is a schematic structural diagram of an embodiment of a positioning module of the firearm safety control device of the present disclosure;

fig. 3 is a schematic structural diagram of an embodiment of a short-range communication module of the firearm safety control device according to the invention.

The reference numbers illustrate:

reference numerals	Name (R)	Reference numerals	Name (R)
				10	Battery module	50	Identity verification module
11	Power supply management module	60	Electronic unlocking module
				20	Motion perception module	70	Lock body
30	Remote communication module	80	Positioning module
				40	Controller	90	Short-range communication module

The implementation and functional features of the object of the present invention will be further explained with reference to the accompanying drawings.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

It should be noted that, if directional indications (such as up, down, left, right, front, and back … …) are involved in the embodiment of the present invention, the directional indications are only used to explain the relative positional relationship between the components, the movement situation, and the like in a specific posture (as shown in the drawing), and if the specific posture is changed, the directional indications are changed accordingly.

In addition, if there is a description of "first", "second", etc. in an embodiment of the present invention, the description of "first", "second", etc. is for descriptive purposes only and is not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature. In addition, if appearing throughout the text, "and/or" is meant to include three juxtaposed aspects, taking "A and/or B" as an example, including either the A aspect, or the B aspect, or both A and B satisfied aspects. In addition, technical solutions between various embodiments may be combined with each other, but must be realized by a person skilled in the art, and when the technical solutions are contradictory or cannot be realized, such a combination should not be considered to exist, and is not within the protection scope of the present invention.

The invention provides a firearm safety control device.

In one embodiment of the present invention, as shown in fig. 1, the firearm safety control device includes a battery module 10, a motion sensing module 20, a remote communication module 30, a controller 40, an authentication module 50, an electronic unlocking module 60, and a lock body 70;

the battery module 10, the motion sensing module 20, the remote communication module 30, the identity verification module 50 and the electronic unlocking module 60 are electrically connected to the controller 40, respectively, and an input end of the lock body 70 is connected to an output end of the electronic unlocking module 60;

the motion sensing module 20 is configured to obtain a motion state of the controller 40 and output a motion state signal to the controller 40;

the controller 40 is configured to output a motion state signal according to the motion sensing module 20, and output a first control signal to the remote communication module 30 to control the remote communication module 30 to be turned on/off;

the remote communication module 30 is configured to receive an authorization signal of a remote server and output a first unlocking signal to the controller 40;

the identity authentication module 50 is configured to receive and authenticate a biometric signal of a firearm user, and output a second unlocking signal to the controller 40 after the biometric signal passes the authentication;

the electronic unlocking module 60 is configured to control the unlocking of the lock body 70 according to the first unlocking signal and/or the second unlocking signal.

In this embodiment, since the battery module 10 and the controller 40 are electrically connected to each other, and the motion sensing module 20, the remote communication module 30, the authentication module 50 and the electronic unlocking module 60 are respectively electrically connected to the controller 40, the battery module 10 can supply power to the motion sensing module 20, the remote communication module 30, the authentication module 50 and the electronic unlocking module 60, so that the firearm safety control device can be connected to a power supply to work normally. It is understood that the battery module 10 may be a rechargeable battery, such as a lithium ion battery, a nickel chromium battery, a nickel hydrogen battery, etc., without limitation.

In this embodiment, the motion sensing module 20 may be a gyroscope, and the gyroscope may acquire the motion state of the controller 40 to feed back a motion state signal to the controller 40. Further, when the remote communication module 30 is turned off, and the gyroscope detects that the controller 40 is in a motion state, the controller 40 outputs a first control signal to the remote communication module 30 to control the remote communication module 30 to be turned on; when the remote communication module 30 is in the on state, the gyroscope may also detect the motion state of the controller 40 all the time, and feed back the motion state information of the controller 40 to the controller 40, and if the motion state information received by the controller 40 is still within a certain period of time, the remote communication module 30 is controlled to be turned off, so as to reduce the power consumption of the firearm safety control device. It is understood that the period of time may be 1 minute, 2 minutes, or 3 minutes, and is set according to the actual application scenario, and is not limited herein.

The motion sensing module 20 may be an attitude sensor. In this embodiment, the motion state of the controller 40 is obtained by the attitude sensor, so as to feed back a motion state signal to the controller 40.

In this embodiment, the identity verification module 50 may receive the biometric signal of the firearm user for verification through the identity information of the firearm user stored in the controller 40. It can be understood that the stored identity information of the firearm user is pre-entered, and when the firearm user needs to use the firearm, the firearm user information can be verified through the identity verification module 50; the biometric signal is a physical characteristic signal of the firearm user, such as fingerprint information of the firearm user.

In this embodiment, the electronic unlocking module 60 may include a motor driver and a motor, that is, when the controller 40 receives the first unlocking signal and/or the second unlocking signal, the motor driver is further controlled to drive the motor to operate, so as to control the unlocking of the lock body 70.

Based on the above embodiment, after the firearm safety control device is powered on, the identity authentication module 50 and the remote communication module 30 are kept closed at this time, and enter a standby state; that is, the authentication module 50 and the remote communication module 30 are in a low power consumption standby state. It can be understood that the motion sensing module 20 is in an operating state after the firearm safety control device is powered on, and senses the motion state of the controller 40 at any time, and when the motion sensing module 20 detects the motion of the controller 40, the controller 40 outputs a first control signal to the remote communication module 30 to control the remote communication module 30 to be turned on. The remote communication module 30 can be brought online with a remote server, the firearm attendant sends an authorization signal to the remote communication module 30 via the remote server, and the remote communication module 30 outputs a first unlock signal to the controller 40. At this time, the firearm user can verify the identity through the identity verification module 50, after the identity verification passes, the identity verification module 50 outputs a second unlocking signal to the controller 40, the controller 40 can receive the identity verification success signal, and the controller 40 can control the electronic unlocking module 60 to drive the lock body 70 to be unlocked according to the first unlocking signal and/or the second unlocking signal.

It should be noted that the electronic unlocking module 60 controls the unlocking of the lock body 70 according to the first unlocking signal and/or the second unlocking signal. That is, when the telecommunication module 30 is unlocked, the electronic unlocking module 60 may control the unlocking of the lock body 70 according to the first unlocking signal; or the electronic unlocking module 60 may also control the unlocking of the lock body 70 according to the first unlocking signal and the second unlocking signal. The electronic unlocking module 60 may control the unlocking of the lock body 70 according to the second unlocking signal when the telecommunication module 30 is closed.

For the above-mentioned electronic unlocking module 60 controlling the unlocking of the lock body 70 after passing the authentication information, the description related to the specific circuit and structure can refer to the patent with application number CN 201920192862.7.

According to the technical scheme of the invention, the motion state of the controller 40 is obtained through the motion sensing module 20 in the firearm safety control device, when the controller 40 is in a moving state, the motion sensing module 20 outputs a motion state signal to the controller 40, and the controller 40 outputs a first control signal according to the received motion state signal so as to control the remote communication module 30 to be started. When the remote communication module 30 is turned on, the firearm manager can remotely authorize the firearm through the remote communication module 30, and the remote communication module 30 outputs a first unlock signal. Thereby improving the safety of the firearm in use. Meanwhile, the identity verification module 50 in the firearm safety control device can receive the biological identification signal of the firearm user for verification, verify whether the firearm user is a legal user, and after the identity verification is passed, the identity verification module 50 outputs a second unlocking signal. Therefore, the identification of the firearm user is improved. The electronic unlocking module 60 in the firearm safety control device controls the unlocking of the lock body 70 after the remote communication module 30 outputs the first unlocking signal and/or the authentication module 50 outputs the second unlocking signal. The technical scheme of the invention improves the safety of the gun-related unit for the use of firearms.

In one embodiment, as shown in fig. 2, the firearm safety control device further comprises a positioning module 80, wherein the positioning module 80 is electrically interconnected with the controller 40;

the controller 40 is further configured to output a motion state signal according to the motion sensing module 20, and output a second control signal to the positioning module 80 to control the positioning module 80 to be turned on/off;

the positioning module 80 is configured to position a firearm and output a firearm position signal to the remote communication module 30 via the controller 40.

In this embodiment, the positioning module 80 is a GPS module or a beidou module. It is understood that the GPS module is an integrated circuit that integrates the RF chip, the baseband chip and the core CPU, and the related peripheral circuits, and in this embodiment, the firearm safety control device can be located, so that the location information of the controller 40 is transmitted to the remote server through the remote communication module 30 via the controller 40. Similarly, the beidou module can also realize the positioning of the firearm safety control device so as to send the positioning information of the controller 40 to the remote server. This scheme has realized the firearms administrator to the grasp of the real-time positioning information of firearms, has promoted the security of wading rifle unit to the firearms use.

It should be noted that, since the positioning module 80 is electrically connected to the controller 40, the battery module 10 can supply power to the positioning module 80 through the controller 40.

In one embodiment, as shown in fig. 3, the firearm safety control device further includes a power management module 11, where the power management module 11 is connected between the battery module 10 and the controller 40;

the power management module 11 is configured to detect an electric quantity signal and a charge/discharge state signal of the battery module 10, and output the electric quantity signal and the charge/discharge state signal to the controller 40.

In this embodiment, the firearm safety control device further comprises a short-range communication module 90, the short-range communication module 90 being electrically interconnected with the controller 40;

the controller 40 is further configured to output the power signal detected by the power management module 11 to the short-range communication module 90;

the short-range communication module 90 is configured to receive a biometric signal or an erasure signal from the short-range server and output the biometric signal or the erasure signal to the controller 40.

In this embodiment, the power management module 11 may detect the power information of the battery module 10 and the charge/discharge state information, so as to send the power information to the remote server for display through the remote communication module 30 via the controller 40; or sent to the proximity server for display via the proximity communication module 90. So that a firearm administrator can know the battery state of the firearm safety control device at any time. It will be appreciated that the erase signal is an erase of the stored biometric signal in the controller, i.e. the stored biometric signal of the firearm user in the controller is erased when the firearm user returns the firearm.

In this embodiment, through the connection between the short-range communication module 90 and the short-range server, when the firearm is out of the warehouse, the identity authentication information of the firearm user can be entered through the short-range server, and the identity authentication information is transmitted to the controller 40 through the short-range communication module 90 for storage, so as to be used for identity authentication when the lock body 70 is opened. It should be noted that, since the short-range communication module 90 is electrically connected to the controller 40, the battery module 10 may supply power to the short-range communication module 90 through the controller 40.

In this embodiment, the short-range communication module 90 is a bluetooth module or an NFC module. It can be understood that the bluetooth module is a general short-distance wireless communication technology, and has the advantages of low cost, low power consumption, high transmission rate, and the like. In order to ensure low power consumption and timely respond to the server connection request, the bluetooth low energy is kept turned on under the power-on condition of the controller 40, so that the controller 40 can timely respond to the external connection signal. Because the low-power-consumption Bluetooth has high connection speed and extremely low power consumption but cannot transmit a large amount of data in a short time, the traditional Bluetooth has high transmission speed but large power consumption. Can adopt bluetooth bimodulus module (the bluetooth module that supports bluetooth low energy and traditional bluetooth simultaneously is called bluetooth bimodulus module), controller 40 during operation bluetooth module is in the low power consumption state all the time, guarantees to connect in time, when the data transmission of authentication information needs to be accomplished, opens bluetooth module and connects proximity server transmission data, finishes transmitting and closes bluetooth module. This scheme has reduced firearms safety control device's consumption. The NFC module may also enable communication of the firearm security control device with the proximity server.

In this embodiment, the firearm safety control device further includes a USB port; the USB port is configured to output the electric quantity signal and the charge/discharge state signal detected by the power management module 11 to the short-range communication module 90. It will be appreciated that the firearm safety control device may also communicate with a controller in the firearm safety control device by way of a wired USB port connection, whereby a biometric or erase signal of the proximity server 90 may be transmitted in the event that charging of the battery module is achieved. Meanwhile, the power signal and the charge/discharge state signal of the battery module 10 detected by the power management module 11 may be transmitted to the short-range communication module 90 through the USB port.

It should be noted that the USB port may also transmit the operation status information of the controller 40 and the version upgrade information of the controller 40, so as to enable the firearm manager to manage the firearm safety control device.

In one embodiment, the authentication module 50 is a fingerprint module. It can be understood that, when taking the firearm out of the warehouse, the firearm user can enter the fingerprint module for the fingerprint information of the firearm user through the short-range server, and when the firearm user needs to use the firearm, after the authorization of the long-range server, the firearm user can verify through the fingerprint information of the firearm user, and after the verification is passed, the controller 40 can control the electronic unlocking module 60 to drive the unlocking of the lock body 70.

In one embodiment, the telecommunications module 30 is a cellular mobile communications module. It is understood that the cellular mobile communication module may be a 2G module, a 3G module, a 4G module, a 5G module, etc., and is not limited thereto.

Based on the above-mentioned embodiment, the lock body 70 includes a mechanical unlocking module, and the mechanical unlocking module is connected with the lock body 70. It will be appreciated that at any time, a firearms attendant may control the opening of the lock body 70 by mechanically unlocking the module.

The above description is only an alternative embodiment of the present invention, and not intended to limit the scope of the present invention, and all modifications and equivalents of the present invention, which are made by the contents of the present specification and the accompanying drawings, or directly/indirectly applied to other related technical fields, are included in the scope of the present invention.