CN215598233U - Electric shock gun - Google Patents

Abstract

The utility model discloses an electric shock gun which comprises a magazine, a main body and an orientation sensing module, wherein the magazine comprises a transmitting component and a power component, the transmitting component comprises two transmitting electrodes, the two transmitting electrodes are positioned on the same plane, the power component is used for transmitting the transmitting electrodes to a remote target, the main body comprises a circuit module, the circuit module is electrically connected with the transmitting electrodes, the circuit module is used for conducting current generated by the circuit module to the remote target through the transmitting electrodes, the orientation sensing module is provided with a preset reference plane, the preset reference plane is parallel or vertical to a horizontal plane, and the orientation sensing module is used for sensing the plane where the two transmitting electrodes are positioned. According to the technical scheme, when the electric shock gun is used for emitting the two emitting electrodes, the direction sensing module senses whether the planes of the two emitting electrodes are parallel or coincident with the preset reference surface, so that whether the long-distance target is correctly aimed or not is judged, and the emitting electrodes are prevented from being missed.

Description

Electric shock gun

Technical Field

The utility model relates to the technical field of electronic riot equipment, in particular to an electric shock gun.

Background

An electric stun gun is an electronic anti-riot device, generally comprising a main body including a circuit module therein to generate a high voltage pulse current, and a magazine assembly including a firing assembly including at least a pair of positive and negative firing electrodes electrically connected to the circuit module by a wire, and a power assembly for firing the electrodes to a remote target.

When the electric shock gun is used, when a user pulls a trigger of the electric shock gun, the power assembly in the electric shock gun magazine is excited, so that high-pressure gas is released instantly, the electrode is emitted, the electrode is communicated with the electrode through a target to form a loop after hitting the target, and current generated by a circuit module of the electric shock gun acts on the target through the electrode, so that the effect of uniforming the target is achieved.

Generally, the action target of the electric shock gun is a human body, and the electric shock gun is characterized in that the long axis of the human body (namely the vertical central axis of the human body trunk) is vertical to the ground horizontal plane in an upright state, and the length of the human body in the vertical direction of the long axis of the human body is far larger than the width of the human body in the horizontal direction; in other cases, the stun gun may also be used with other quadruped animals, where the long axis of the body of the target is parallel to the ground level and the body shape is greater in length horizontally than vertically along the long axis of the body.

To accommodate the physical characteristics of the target, the two electrodes in the stun gun magazine are typically set to a 5-8 degree firing angle to cover a larger body area at a distance to ensure uniform results, and are arranged in the same reference plane, which ideally should be perpendicular to the horizontal when the stun gun is used for upright human targets (which may be criminals) and parallel to the horizontal when used for quadruped animals.

The prior art stun gun is equipped with a laser and a sight mechanism for aiming at a target, and the aiming point can be approximately positioned at the center position along the long axis of the body of the target when the stun gun is used, however, unlike the traditional lethal weapon which fires a single projectile, the stun gun uses a pair of electrodes, and the separation distance between the electrodes is increased along the firing distance when the stun gun is used for a long-distance target, so that even if the aiming point of the prior art stun gun aiming arrangement is positioned at the center position of the long axis of the body of the target, the reference plane of the electrodes can be usually only close to or intersected with a certain point of the target along the center line of the long axis of the body, the reference plane of the electrodes can not be ensured to be parallel to or coincident with the center line of the long axis of the target body, and errors caused by other factors such as tension and the like when the stun gun is used for walking animals on four limbs need to be rotated to be held by a vertical handle, it is easier to cause at least one electrode to be off target and ineffective.

Therefore, the existing aiming and positioning method of the electric shock gun has defects, and a technology is expected, when the electric shock gun is used for aiming at a long-distance target, the reference plane where the electrode is located can be overlapped with the long axis of the long-distance target, so that the defect that the electrode is easy to miss the target is overcome, the shooting accuracy is improved, and the effective application of the electric shock gun is ensured.

SUMMERY OF THE UTILITY MODEL

The utility model mainly aims to provide an electric shock gun, aiming at solving the technical problem that the target is easy to miss when the electric shock gun is used.

In order to achieve the above object, the present invention provides a stun gun including:

the magazine comprises a launching assembly and a power assembly, wherein the launching assembly comprises two launching electrodes, the two launching electrodes are positioned on the same plane, and the power assembly is used for launching the launching electrodes to a remote target;

the main body comprises a circuit module, the circuit module is electrically connected with the transmitting electrode, and the circuit module is used for conducting the current generated by the circuit module to the remote target through the transmitting electrode;

the orientation sensing module is provided with a preset reference surface, the preset reference surface is vertical to the horizontal plane, and the orientation sensing module is used for sensing the plane where the two transmitting electrodes are located.

Further, to achieve the above object, another electric shock gun according to the present invention includes:

the magazine comprises a launching assembly and a power assembly, wherein the launching assembly comprises two launching electrodes, the two launching electrodes are positioned on the same plane, and the power assembly is used for launching the launching electrodes to a remote target;

the main body comprises a circuit module, the circuit module is electrically connected with the transmitting electrode, and the circuit module is used for conducting the current generated by the circuit module to the remote target through the transmitting electrode;

the orientation sensing module is provided with a preset reference surface, the preset reference surface is parallel to the horizontal plane, and the orientation sensing module is used for sensing the plane where the two transmitting electrodes are located.

Optionally, the orientation sensing module is configured to sense a state that the preset reference plane is parallel to or coincident with a plane where the two transmitting electrodes are located.

Optionally, the electric shock gun further comprises an indication module, and the indication module gives a prompt when the direction sensing module senses that the preset reference plane is parallel to or coincident with the plane where the two emitting electrodes are located.

Optionally, the indication module comprises at least one of an audible, optical and electrical indication.

Optionally, the stun gun further comprises a mechanical aiming positioning device for aiming positioning of the remote target.

Optionally, the mechanical sighting and positioning device comprises a laser and/or a sight.

Optionally, when the orientation sensing module senses that the preset reference plane is parallel to or coincides with the plane where the two transmitting electrodes are located, and the mechanical aiming and positioning device is positioned on the long axis of the body of the remote target, the preset reference plane coincides with the plane where the two transmitting electrodes are located.

Optionally, the orientation sensing module comprises a gyroscope, a gravity sensor or an angle sensor.

In the technical scheme of the utility model, because the electric shock gun is internally provided with the orientation sensing module which is provided with the preset reference surface which is parallel or vertical to the horizontal plane, the preset reference surface does not rotate along with the rotation of the electric shock gun, the angle between the preset reference surface and the horizontal plane is always unchanged, and the two transmitting electrodes can rotate along with the rotation of the electric shock gun, namely the plane where the two transmitting electrodes are positioned is the same as the motion state of the electric shock gun, therefore, the angle between the plane where the two transmitting electrodes are positioned and the preset reference surface is changed along with the rotation of the electric shock gun, and because the orientation sensing module can sense the plane where the two transmitting electrodes are positioned, the angle between the plane where the two transmitting electrodes are positioned and the preset reference surface can be sensed by the orientation sensing module on the basis that the angle between the preset reference surface and the horizontal plane is unchanged, the angle between the plane where the two transmitting electrodes are located and the horizontal plane can be sensed through the direction sensing module, when an electric shock gun is used for electrically shocking a long-distance target, and the long axis of the long-distance target is perpendicular to the horizontal plane, when the direction sensing module senses that the plane where the two transmitting electrodes are located is perpendicular to the horizontal plane, the plane where the two transmitting electrodes are located is coincident with or parallel to the long axis of the long-distance target, at the moment, the two transmitting electrodes can be transmitted, the projection area of the two transmitting electrodes on the long-distance target can be increased, the hit probability is improved, and miss is avoided; when the long axis of the remote target is parallel to the horizontal plane, when the orientation sensing module senses that the planes where the two transmitting electrodes are located are parallel to the horizontal plane, the planes where the two transmitting electrodes are located are coincident or parallel to the long axis of the remote target, at the moment, the two transmitting electrodes can be transmitted, the projection area of the two transmitting electrodes on the remote target can be increased, the hit probability is improved, and miss is avoided.

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 diagram of the overall structure of an embodiment of a stun gun of the present invention;

FIG. 2 is a schematic cross-sectional view of another embodiment of a stun gun of the present invention;

fig. 3 is a first schematic view of the stun gun of fig. 1 aimed at the long axis of the body;

fig. 4 is a second schematic structural view of the stun gun of fig. 1 aimed at the long axis of the body.

The reference numbers illustrate:

reference numerals	Name (R)	Reference numerals	Name (R)
				1	Magazine	2	Main body
111	Emitter electrode	12	Power assembly
				5	Azimuth sensing module	3	Indicating module
41	Laser	42	Sight
				11	Transmitting assembly	10	Object/body long axis

The implementation, functional features and advantages of the objects 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, 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 utility model provides an electric shock gun, which is used for solving the technical problem that a target is easy to miss when the electric shock gun is used.

In the embodiment of the present invention, as shown in fig. 1 and 2, the electric shock gun includes a magazine 1, a main body 2 and an orientation sensing module 5, the magazine 1 includes a launching assembly 11 and a power assembly 12, the launching assembly 11 includes two launching electrodes 111, the two launching electrodes 111 are located on the same plane, the power assembly 12 is used for launching the launching electrodes 111 to a remote target, the main body 2 includes a circuit module, the circuit module is electrically connected with the launching electrodes 111, the circuit module is used for conducting the current generated by the circuit module to the remote target through the launching electrodes 111;

the orientation sensing module 5 has a preset reference plane, the preset reference plane is perpendicular to the horizontal plane, and the orientation sensing module 5 is used for sensing the plane where the two transmitting electrodes 111 are located.

In another alternative embodiment of the present invention, the electric shock gun comprises a magazine 1, a body 2 and an orientation sensing module 5, wherein the magazine 1 comprises a transmitting assembly 11 and a power assembly 12, the transmitting assembly 11 comprises two transmitting electrodes 111, the two transmitting electrodes 111 are in the same plane, the power assembly 12 is used for transmitting the transmitting electrodes 111 to a remote target, the body 2 comprises a circuit module, the circuit module is electrically connected with the transmitting electrodes 111, and the circuit module is used for conducting the current generated by the circuit module to the remote target through the transmitting electrodes 111;

the orientation sensing module 5 has a preset reference plane parallel to the horizontal plane, and the orientation sensing module 5 is configured to sense the plane where the two transmitting electrodes 111 are located.

According to the technical scheme, the two transmitting electrodes 111 can be transmitted to a remote target through the power assembly 12, so that the remote target, the two transmitting electrodes 111 and the circuit module are combined to form a closed loop to generate an electric shock effect on the remote target; because the azimuth sensing module 5 is arranged in the electric shock gun, the azimuth sensing module 5 is provided with a preset reference plane, and the preset reference plane is parallel to or perpendicular to the horizontal plane, the preset reference plane does not rotate along with the rotation of the electric shock gun, the angle between the preset reference plane and the horizontal plane is always constant, and the two emitting electrodes 111 rotate along with the rotation of the electric shock gun, namely the plane where the two emitting electrodes 111 are located is the same as the motion state of the electric shock gun, so the angle between the plane where the two emitting electrodes 111 are located and the preset reference plane changes along with the rotation of the electric shock gun, and because the azimuth sensing module 5 can sense the plane where the two emitting electrodes 111 are located, the angle between the plane where the two emitting electrodes 111 are located and the preset reference plane can be sensed by the azimuth sensing module 5 on the basis that the angle between the preset reference plane and the horizontal plane is constant, the angle between the plane in which the two transmitting electrodes 111 are located and the horizontal plane can be sensed by the orientation sensing module 5. As shown in fig. 3, when the electric shock gun is used to shock a remote target, and the long axis 10 of the remote target is perpendicular to the horizontal plane, when the orientation sensing module 5 senses that the planes of the two transmitting electrodes 111 are perpendicular to the horizontal plane, it indicates that the planes of the two transmitting electrodes 111 are coincident with or parallel to the long axis 10 of the remote target, and at this time, the two transmitting electrodes 111 can be transmitted, so that the projection area of the two transmitting electrodes 111 on the remote target can be increased, thereby increasing the hit probability and avoiding miss-target; when the long axis of the remote target is parallel to the horizontal plane, as shown in fig. 4, when the orientation sensing module 5 senses that the planes of the two transmitting electrodes 111 are parallel to the horizontal plane, it is indicated that the planes of the two transmitting electrodes 111 are coincident with or parallel to the long axis 10 of the remote target, and at this time, the two transmitting electrodes 111 can be transmitted, so that the projection area of the two transmitting electrodes 111 on the remote target can be increased, thereby improving the hit probability and avoiding miss-target.

It will be appreciated that when the long axis 10 of the remote target is perpendicular to the horizontal, as shown in figure 3, the remote target may be a human body (e.g., criminals, terrorists, etc.); as shown in fig. 4, the distant target may be a quadruped reptile (e.g., pig, sheep, cow, etc.) when the long axis 10 of the distant target is parallel to the horizontal.

It is understood that the orientation sensing module 5 can be disposed at any suitable location of the electric stun gun, such as in the magazine 1, or in the body 2, which is not limited herein; the magazine 1 and body 2 are mounted in a manner comparable to existing stun guns.

It is understood that the predetermined reference plane is a reference plane set for a specific purpose in this embodiment.

In an embodiment, the orientation sensing module 5 is configured to sense a state that the preset reference plane is parallel to or overlapped with the plane where the two transmitting electrodes 111 are located, and because the preset reference plane is parallel to or perpendicular to the horizontal plane, when the orientation sensing module 5 senses that the plane where the two transmitting electrodes 111 are located is parallel to or overlapped with the preset reference plane, it indicates that the electric shock gun has met the shooting requirement, and the two transmitting electrodes 111 can be transmitted to shock the remote target.

In one embodiment, as shown in fig. 1 and 2, the electric shock gun further includes an indication module 3, and the indication module 3 gives a prompt when the orientation sensing module 5 senses that the preset reference plane is parallel to or coincident with the plane where the two emitting electrodes 111 are located, and when the indication module 3 gives a prompt, it indicates that the electric shock gun is correctly aimed, and the user can shoot.

In the present embodiment, the indication module 3 is provided on the main body 2.

In an embodiment, the indication module 3 comprises at least one of an audible, optical and electrical indication.

In this embodiment, the light indication may be an indicator light and the electrical indication may be a display screen indication.

In one embodiment, as shown in fig. 1, the electric shock gun further comprises a mechanical aiming positioning device, and the mechanical aiming positioning device is used for aiming and positioning the remote target, so that the remote target can be aimed through the mechanical aiming positioning device and the orientation sensing module 5 together, the hit rate is improved, and the off-target of the transmitting electrode 111 is avoided.

In one embodiment, as shown in FIG. 1, the mechanical aiming feature includes a laser 41 and/or a sight 42, the laser 41 and/or sight 42 being used for aiming positioning of a remote target.

In one embodiment, as shown in fig. 3 and 4, the initial aiming reference points of the laser aiming 41 and the sight aiming 42 are on the same plane as the two emitting electrodes 111, when the orientation sensing module 5 senses that the preset reference plane is parallel to or coincident with the plane where the two emitting electrodes 111 are located and the mechanical aiming and positioning device is located at the long axis of the body of the remote target, the preset reference plane is coincident with the plane where the two emitting electrodes 111 are located, and at this time, the indicating module 3 gives a prompt that the electric stun gun has been aimed at the remote target, so that the user can directly shoot.

In an embodiment, the orientation sensing module 5 comprises a gyroscope, a gravity sensor or an angle sensor.

In addition, based on the electric shock gun described in any of the above embodiments, the embodiment of the present invention further provides a method for using the electric shock gun, where the method for using the electric shock gun is as follows:

activating a circuit module of the electric shock gun to enable the electric shock gun to be in an open state;

aiming at a remote target, and adjusting the shooting angle of the electric shock gun until the direction sensing module 5 senses that the preset reference plane is parallel to or coincident with the plane where the two emitting electrodes 111 are located;

the trigger is pulled to fire the electrode 111.

According to the using method of the electric shock gun provided by the embodiment of the utility model, the angle of the electric shock gun relative to the horizontal plane is adjusted, so that the plane where the two transmitting electrodes 111 are located is parallel to or coincident with the preset reference plane of the orientation sensing module 5, when the orientation sensing module 5 senses the state, the indicating module 3 gives a prompt to indicate that the correct aiming is achieved, a user can shoot, the hit rate of the two transmitting electrodes 111 can be improved, and the transmitting electrodes 111 are prevented from being off target.

The above description is only a preferred embodiment of the present invention, and not intended to limit the scope of the present invention, and all modifications and equivalents of the technical solutions of the present invention, which are made by using 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.

Claims (9)

1. A stun gun, comprising:

the magazine comprises a launching assembly and a power assembly, wherein the launching assembly comprises two launching electrodes, the two launching electrodes are positioned on the same plane, and the power assembly is used for launching the launching electrodes to a remote target;

the main body comprises a circuit module, the circuit module is electrically connected with the transmitting electrode, and the circuit module is used for conducting the current generated by the circuit module to the remote target through the transmitting electrode;

the electric shock gun is characterized by further comprising an orientation induction module, wherein the orientation induction module is provided with a preset reference surface, the preset reference surface is vertical to the horizontal plane, and the orientation induction module is used for inducing the plane where the two emitting electrodes are located.

2. A stun gun, comprising:

the magazine comprises a launching assembly and a power assembly, wherein the launching assembly comprises two launching electrodes, the two launching electrodes are positioned on the same plane, and the power assembly is used for launching the launching electrodes to a remote target;

the main body comprises a circuit module, the circuit module is electrically connected with the transmitting electrode, and the circuit module is used for conducting the current generated by the circuit module to the remote target through the transmitting electrode;

the electric shock gun is characterized by further comprising an orientation induction module, wherein the orientation induction module is provided with a preset reference surface, the preset reference surface is parallel to the horizontal plane, and the orientation induction module is used for inducing the plane where the two emitting electrodes are located.

3. The electric shock gun according to claim 1 or 2, wherein the orientation sensing module is configured to sense a state in which the predetermined reference plane is parallel to or coincident with a plane in which the two transmitting electrodes are located.

4. The electric shock gun of claim 3, further comprising an indication module that gives a prompt when the orientation sensing module senses that the preset reference plane is parallel to or coincides with the plane in which the two emitting electrodes are located.

5. The stun gun of claim 4, wherein the indication module includes at least one of an audible, light, and electrical indication.

6. The stun gun of claim 5, further comprising a mechanical aiming positioning device for aiming positioning of the remote target.

7. The stun gun of claim 6, wherein the mechanical aiming feature comprises a laser and/or a sight.

8. The electric shock gun of claim 7, wherein when the orientation sensing module senses that the predetermined reference plane is parallel to or coincides with the plane of the two emitting electrodes and the mechanical aiming positioning device is positioned at the long axis of the body of the remote target, the predetermined reference plane coincides with the plane of the two emitting electrodes.

9. The stun gun of claim 8, wherein the orientation sensing module includes a gyroscope, a gravity sensor, or an angle sensor.

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