CN210154435U - Throwing type net electric shocking device - Google Patents

Abstract

The embodiment of the utility model discloses a throwing type mesh electric shock device, which comprises an electric shock high-voltage generator, a mesh electric shock device connected with the electric shock high-voltage generator and a mesh electric shock device launching tractor connected with the mesh electric shock device; the mesh-shaped electric shock device comprises a high-potential conductive net, an insulating net and a low-potential conductive net, wherein the high-potential conductive net is connected to the low-potential conductive net through the insulating net, so that the mesh-shaped electric shock device is in a spider-web shape; wherein, netted electroshock ware transmission tractor sets up on the outer peripheral edge of spider-web shape, including haulage rope and tractor, haulage rope one end connect in the tractor, the other end connect in netted electroshock ware. The throwing type mesh electric shock device does not need accurate aiming, can timely play the electric shock function to enable the caught object to lose the resistance capability immediately, and the hand is arrested.

Description

Throwing type net electric shocking device

Technical Field

The utility model relates to a security field, concretely relates to throwing type network form electric shock device.

Background

When the prior army, armed police and special police carry out criminals or suspects to arrest and other tasks, the traditional double-firing pin electric shock device and single electric shock device are very easy to deviate from an arrested object in the arresting process and cannot effectively carry out electric shock action on the arrested object to cause the arrested object to lose the resistance capacity immediately, so that a non-fatal arresting weapon which can not need accurate aiming and can timely play the electric shock action is urgently needed to cause the arrested object to lose the resistance capacity immediately and be arrested by a capturer. Meanwhile, the trapping devices for casualties of law enforcement personnel are reduced.

The information disclosed in this background section of the invention is only for enhancement of understanding of the general background of the invention and should not be taken as an acknowledgement or any form of suggestion that this information constitutes prior art already known to a person skilled in the art.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a throwing type netted electric shock device, this throwing type netted electric shock device need not the accuracy, and can in time exert the electric shock effect and make the object of being arrested lose the resistance ability at once, and the rider just catches.

In order to achieve the above object, according to the utility model provides a net electric stunner of casting type, this net electric stunner of casting type includes:

a high voltage shock generator, a mesh stunner connected to the high voltage shock generator, and a mesh stunner firing retractor connected to the mesh stunner;

the mesh-shaped electric shock device comprises a high-potential conductive net, an insulating net and a low-potential conductive net, wherein the high-potential conductive net is connected to the low-potential conductive net through the insulating net, so that the mesh-shaped electric shock device is in a spider-web shape;

the electric shock high-voltage generator comprises a high-potential output end and a bottom-potential output end, wherein the high-potential output end is electrically connected to the high-potential conductive net, and the bottom-potential output end is electrically connected to the low-potential conductive net;

wherein, netted electroshock ware transmission tractor sets up on the outer peripheral edge of spider-web shape, including haulage rope and tractor, haulage rope one end connect in the tractor, the other end connect in netted electroshock ware.

Preferably, the electric shock device further comprises a transmitter, and the mesh electric shock device, the electric shock high voltage generator and the mesh electric shock device transmitting retractor are arranged in the transmitter.

Preferably, the transmitter includes transmitter trunk line, a plurality of tractor transmitting tubes, the quick interface of transmitter, trunk line sealing plate and tractor transmitting tube and seals the end cap, the tractor transmitting tube is located the outer edge of transmitter trunk line, the quick interface of transmitter connect in the transmitter air flue, the transmitter air flue communicate in the transmitter trunk line reaches the tractor transmitting tube, the trunk line sealing plate is used for sealing the transmitter trunk line, the tractor transmitting tube seals the end cap and is used for sealing the tractor transmitting tube.

Preferably, the quick interface of transmitter includes lock sleeve, adapter main part, locking steel ball, locking reset spring and sealing washer, the adapter main part sets up the one end of lock sleeve, locking reset spring sets up the adapter main part with between the lock sleeve, the locking steel ball sets up the interior edge of lock sleeve is last, semicircular groove has been seted up on the outer wall of transmitter air flue, the locking steel ball can the joint be in the semicircular groove, the sealing washer sets up the adapter main part is close to the one end of lock sleeve.

Preferably, the high-potential conductive net and the low-potential conductive net are formed by splicing conducting wires or conducting strips, and the insulating net is formed by weaving and splicing insulating rope materials.

Preferably, the high-potential conductive net, the insulating net and the low-potential conductive net are arranged in a split shape, and the high-potential conductive net and the low-potential conductive net are symmetrically arranged on two sides of the insulating net.

Preferably, the high-potential conductive net, the insulating net and the low-potential conductive net are arranged in a multi-branch shape in a warp direction, and the high-potential conductive net, the insulating net and the low-potential conductive net are alternately arranged at intervals.

Preferably, the high-potential conductive net, the insulating net and the low-potential conductive net are arranged in a weft-wise multilayer shape, and the high-potential conductive net, the insulating net and the low-potential conductive net are arranged layer by layer from inside to outside by taking the center of the mesh-shaped electric shocker as a starting point.

Preferably, the high-potential conductive net, the insulating net and the low-potential conductive net are arranged in a warp shape, the high-potential conductive net and the low-potential conductor are in a line shape, the insulating net is in a net shape, and the high-potential conductive net, the insulating net and the low-potential conductive net are alternately arranged and sequentially connected.

Preferably, the high-potential conductive net, the insulating net and the low-potential conductive net are arranged in a weft shape, and the insulating net and the low-potential conductive net are annular and are arranged layer by layer from inside to outside with the center of the mesh-shaped electric shock device as a starting point.

Has the advantages that: the throwing type mesh electric shock device can be rapidly unfolded in the flying process due to the arrangement of the traction rope and the tractor after being launched. At the moment, the electric shock high-voltage generator sends out electric shock pulse high voltage to the high-potential conductive net and the low-potential conductive net, and the electric shock pulse carries out electric shock on the captured object so that the captured object loses the reactive power immediately. Because the mesh-shaped electric shock device has a large opening area, the electric shock to the captured object can be ensured only by probability aiming during transmission. Meanwhile, the caught object can be caught by net-tensioning winding.

Drawings

Fig. 1 is a schematic structural view of the throwing type mesh electric stunner of the present invention.

Fig. 2a to 2d respectively show the structure schematic diagrams of the high potential conductive net, the insulating net, the low potential conductive net and the mesh-shaped electric shock device of embodiment 1 of the present invention.

Fig. 3a to 3d respectively show the structure schematic diagrams of the high potential conductive net, the insulating net, the low potential conductive net and the mesh-shaped electric shock device of embodiment 2 of the present invention.

Fig. 4a to 4d are schematic structural diagrams of the high potential conductive net, the insulating net, the low potential conductive net and the mesh-shaped electric shock device according to embodiment 3 of the present invention.

Fig. 5a to 5d are schematic structural diagrams of the high potential conductive net, the insulating net, the low potential conductive net and the mesh-shaped electric shock device according to embodiment 4 of the present invention.

Fig. 6a to 6d are schematic structural diagrams of the high potential conductive net, the insulating net, the low potential conductive net and the mesh-shaped electric shock device according to embodiment 5 of the present invention.

Fig. 7 is a schematic diagram of the high potential output end structure of the electric shock high voltage generator of the throwing type mesh electric stunner of the present invention.

Fig. 8 is a schematic view of the structure of the bottom potential output end of the electric shock high voltage generator of the throwing type mesh electric stunner of the present invention.

Fig. 9 is a side view of the electric shock high voltage generator of the tossing-type mesh stunner of the present invention.

Fig. 10 is a schematic view of the connection state between the electric shock high voltage generator and the mesh electric shock device of the throwing type mesh electric shock device of the present invention.

Fig. 11 is a circuit diagram of the electric shock pulse high voltage generation of the electric shock high voltage generator of the throwing type mesh electric stunner of the present invention.

Fig. 12 is a front view of the emitter of the throwing type mesh electric stunner of the present invention.

Fig. 13 is a top view of the emitter of the throwing type electric stunner.

Fig. 14 is a schematic diagram of a state to be sent of the throwing type mesh electric stunner of the present invention.

Fig. 15 is a schematic block diagram of the transmitter quick interface of the tossing-type mesh stunner of the present invention.

Fig. 16 is a schematic structural view of a launcher of a throwing type mesh electric stunner according to the present invention.

Description of reference numerals:

1. a mesh-like electric stunner; 2. an electric shock high voltage generator; 3. a mesh stunner firing retractor; 4. a transmitter;

1.1, a high-potential conductive net; 1.2, insulating nets; 1.3, a low-potential conductive net; 1.4, conducting wires; 1.5 insulating the wire; 1.6, an insulating layer;

2.1, a high potential output end; 2.2, a low potential output end; 2.3, high potential output line; 2.4, high potential output line;

3.1, pulling a rope; 3.2, tying a rope point by the traction rope;

4.1, a transmitter main pipeline; 4.2, a tractor emission tube; 4.3, a transmitter quick interface; 4.4, a main pipeline sealing plate; 4.5, a retractor transmitting tube sealing plug; 4.6, a locking sleeve; 4.7, an adapter body; 4.8, locking the steel ball; 4.9, locking a return spring; 4.10 sealing ring; 4.11, transmitter airway.

Detailed Description

The technical scheme of the utility model is described in detail with the accompanying drawings.

According to the utility model discloses an aspect provides a net electric stunner of casting type, and this net electric stunner of casting type includes:

a high voltage shock generator, a mesh stunner connected to the high voltage shock generator, and a mesh stunner firing retractor connected to the mesh stunner;

the mesh-shaped electric shock device comprises a high-potential conductive net, an insulating net and a low-potential conductive net, wherein the high-potential conductive net is connected to the low-potential conductive net through the insulating net, so that the mesh-shaped electric shock device is in a spider-web shape;

the electric shock high-voltage generator comprises a high-potential output end and a bottom-potential output end, wherein the high-potential output end is electrically connected to the high-potential conductive net, and the bottom-potential output end is electrically connected to the low-potential conductive net;

wherein, netted electroshock ware transmission tractor sets up on the outer peripheral edge of spider-web shape, including haulage rope and tractor, haulage rope one end connect in the tractor, the other end connect in netted electroshock ware.

Specifically, when the throwing type mesh electric shock device is used, the throwing type mesh electric shock device is placed in the emitter, high-pressure gas is sprayed out, the mesh electric shock device can be unfolded through the counterweight effect of the tractor which is emitted by the mesh electric shock device in the flying process of the throwing type mesh electric shock device, high-potential conducting nets discharge electricity to high-potential conducting nets and low-potential conducting nets to send high-voltage pulses, and the high-voltage pulses are used for electrically shocking a caught object to enable the caught object to lose the reactive power immediately. Because the mesh-shaped electric shock device has a large opening area, the electric shock to the captured object can be ensured only by probability aiming during transmission. Meanwhile, the caught object can be caught by net-tensioning winding.

Specifically, the high-potential conductive net and the low-potential conductive net are provided with outer insulating layers at the connection positions with the electric shock high-voltage generator, so as to prevent high-voltage short circuit from occurring between the high-potential conductive net and the low-potential output end within the range of the distance of the output end of the electric shock high-voltage generator.

Specifically, the mesh shape of the mesh-shaped electric shocker can be a regular polygon, a diamond shape, a triangle or other polygonal structures.

Further, still include the transmitter, netted electric stun ware, electric shock high voltage generator and netted electric stun ware transmission tractor are used for setting up in the transmitter.

Further, the transmitter includes transmitter trunk line, a plurality of tractor transmitting tubes, the quick interface of transmitter, trunk line sealing plate and tractor transmitting tube and seals the end cap, the tractor transmitting tube is located the outer edge of transmitter trunk line, the quick interface of transmitter connect in the transmitter air flue, the transmitter air flue communicate in the transmitter trunk line reaches the tractor transmitting tube, the trunk line sealing plate is used for sealing the transmitter trunk line, the tractor transmitting tube seals the end cap and is used for sealing the tractor transmitting tube.

Specifically, when the electric shock high-voltage generator and the mesh electric shock device are used, the electric shock high-voltage generator and the mesh electric shock device are arranged in the main pipe of the transmitter, the electric shock high-voltage generator is firstly arranged, then the mesh electric shock device is arranged, and then the sealing plate of the main pipe is used for sealing, so that the electric shock high-voltage generator and the mesh electric shock device are prevented from falling off; the net-shaped electric shock device launching retractors are respectively arranged in the retractor transmitting tubes on the periphery of the main tube of the ejector, and the retractor transmitting tubes are used for sealing the plugs and preventing the net-shaped electric shock device launching retractors from dropping out. The mesh stunner is ready to fire. This arrangement facilitates rapid deployment of the mesh stunner during the launch flight.

Further, the quick interface of transmitter includes lock sleeve, adapter main part, locking steel ball, locking reset spring and sealing washer, the adapter main part sets up the one end of lock sleeve, locking reset spring sets up the adapter main part with between the lock sleeve, the locking steel ball sets up the interior edge of lock sleeve is last, semicircular groove has been seted up on the outer wall of transmitter air flue, the locking steel ball can the joint be in the semicircular groove, the sealing washer sets up the adapter main part is close to the one end of lock sleeve.

Specifically, one end of the transmitter quick interface is connected with an air passage of the transmitter, and the other end of the transmitter quick interface can be connected with any high-pressure air source output port in a matched mode. The transmitter can be quickly connected with the distributed gas power source through the transmitter quick interface. The power source may be a blank cartridge, compressed high pressure gas or high pressure gas generator.

Further, the electric shock high voltage generator is located at the center of the spider-web shape.

Furthermore, the high-potential conductive net and the low-potential conductive net are formed by splicing conducting wires or conducting strips, and the insulating net is formed by weaving and splicing insulating rope materials.

Furthermore, the high-potential conductive net, the insulating net and the low-potential conductive net are arranged in a split shape, and the high-potential conductive net and the low-potential conductive net are symmetrically arranged on two sides of the insulating net.

Particularly, the split sheet-shaped high-potential conductive net and the low-potential conductive net are arranged in a warp shape, so that an electric shock effect is easily exerted on a caught person.

Furthermore, the high-potential conductive net, the insulating net and the low-potential conductive net are arranged in a warp-wise multi-branch shape, and the high-potential conductive net, the insulating net and the low-potential conductive net are alternately arranged at intervals.

Particularly, the high-potential conductive net and the low-potential conductive net are arranged in a warp-wise multi-branch shape, so that an electric shock effect is easily exerted on a caught person.

Furthermore, the high-potential conductive net, the insulating net and the low-potential conductive net are arranged in a weft-wise multilayer shape, and the high-potential conductive net, the insulating net and the low-potential conductive net are arranged layer by layer from inside to outside by taking the center of the mesh-shaped electric shocker as a starting point.

Particularly, the high-potential conductive net and the low-potential conductive net which are arranged in a multi-branch shape in the warp direction have larger widths, so that the captured people are easy to be shocked.

Furthermore, the high-potential conductive net, the insulating net and the low-potential conductive net are arranged in a warp shape, the high-potential conductive net and the low-potential conductor are in a line shape, the insulating net is in a net shape, and the high-potential conductive net, the insulating net and the low-potential conductive net are alternately arranged and sequentially connected.

Specifically, the high-potential conductive net and the low-potential conductive net arranged in a warp-wise manner are small in width, so that the high-potential conductive net rope and the low-potential conductive net rope are not easily pulled together by a person caught forcibly, and the short circuit of the high-potential conductive net rope and the low-potential conductive net rope is caused to lose the electric shock effect.

Furthermore, the high-potential conductive net, the insulating net and the low-potential conductive net are arranged in a weft shape, and the insulating net and the low-potential conductive net are annular and are arranged layer by layer from inside to outside by taking the center of the mesh-shaped electric shock device as a starting point.

Specifically, the high-potential conductive net and the low-potential conductive net arranged in the weft shape are small in width, so that the high-potential conductive net rope and the low-potential conductive net rope are not easily pulled together by a person caught forcibly, and the short circuit of the high-potential conductive net rope and the low-potential conductive net rope is caused to lose the electric shock effect.

Example 1

Fig. 1 is a schematic structural view of the throwing type mesh electric stunner of the present invention. Fig. 2a to 2d respectively show the structure schematic diagrams of the high potential conductive net, the insulating net, the low potential conductive net and the mesh-shaped electric shock device of embodiment 1 of the present invention. Fig. 7 is a schematic diagram of the high potential output end structure of the electric shock high voltage generator of the throwing type mesh electric stunner of the present invention. Fig. 8 is a schematic view of the structure of the bottom potential output end of the electric shock high voltage generator of the throwing type mesh electric stunner of the present invention. Fig. 9 is a side view of the electric shock high voltage generator of the tossing-type mesh stunner of the present invention. Fig. 10 is a schematic view of the connection state between the electric shock high voltage generator and the mesh electric shock device of the throwing type mesh electric shock device of the present invention. Fig. 11 is a circuit diagram of the electric shock pulse high voltage generation of the electric shock high voltage generator of the throwing type mesh electric stunner of the present invention. Fig. 12 is a front view of the emitter of the throwing type mesh electric stunner of the present invention. Fig. 13 is a top view of the emitter of the throwing type electric stunner. Fig. 14 is a schematic diagram of a state to be sent of the throwing type mesh electric stunner of the present invention. Fig. 15 is a schematic block diagram of the transmitter quick interface of the tossing-type mesh stunner of the present invention. Fig. 16 is a schematic structural view of a launcher of a throwing type mesh electric stunner according to the present invention.

As shown in fig. 1, 2 a-2 d, 7, 10-16, the throwing-type mesh stunner includes a high-voltage shock generator 2, a mesh stunner 1 connected to the high-voltage shock generator 2, a mesh stunner-emitting retractor 3 connected to the mesh stunner 1, and a transmitter 4;

the mesh-shaped electric shock device 1 comprises a high-potential conductive net 1.1, an insulating net 1.2 and a low-potential conductive net 1.3, wherein the high-potential conductive net 1.1 is connected to the low-potential conductive net 1.3 through the insulating net 1.2, so that the mesh-shaped electric shock device 1 is in a spider-web shape;

wherein, the electric shock high voltage generator 2 comprises a high potential output end 2.1 and a bottom potential output end 2.2, the high potential output end 2.1 is electrically connected with the high potential conductive net 1.1, the bottom potential output end 2.1 is electrically connected with the low potential conductive net 1.3, an insulating layer 1.6 is arranged at the joint of the net-shaped electric shock device 1 and the electric shock high voltage generator 2

Wherein, netted electric shock ware transmission tractor 2 sets up on the outer peripheral edge of spider-web shape, including haulage rope 3.1 and tractor, haulage rope 3.1 one end connect in the tractor, the other end connect in netted electric shock ware 1, haulage rope 3.1 with the junction of netted electric shock ware 1 is haulage rope knot rope point 3.2.

Wherein the mesh electric stunner 1, the electric stunning high voltage generator 2 and the mesh electric stunner emitting retractor 3 are arranged in the emitter 4.

Wherein, transmitter 4 includes that transmitter trunk line 4.1, a plurality of tractor launching tube 4.2, transmitter quick-operation interface 4.3, trunk line seal board 4.4 and tractor launching tube seal end cap 4.5, tractor launching tube 4.2 is located transmitter trunk line 4.1's outer edge, transmitter quick-operation interface 4.3 connect in transmitter air flue 4.11, transmitter air flue 4.11 communicate in transmitter trunk line 4.1 reaches tractor launching tube 4.2, trunk line seal board 4.4 is used for sealing transmitter trunk line 4.1, tractor launching tube seal end cap 4.5 is used for sealing tractor launching tube 4.2.

Wherein, transmitter quick interface 4.3 includes lock sleeve 4.6, adapter main part 4.7, locking steel ball 4.8, locking reset spring 4.9 and sealing washer 4.10, adapter main part 4.7 sets up the one end of lock sleeve 4.6, locking reset spring 4.9 sets up adapter main part 4.7 with between the lock sleeve 4.6, locking steel ball 4.8 sets up on the interior edge of lock sleeve 4.6, semicircular groove has been seted up on the outer wall of transmitter air flue 4.11, locking steel ball 4.8 can the joint be in the semicircular groove, sealing washer 4.10 sets up adapter main part 4.7 is close to the one end of lock sleeve 4.6.

Wherein the electric shock high voltage generator 2 is located at the center of the spider-web shape.

The high-potential conductive net 1.1 and the low-potential conductive net 1.3 are formed by splicing wires 1.4, and the insulating net 1.2 is formed by weaving and splicing insulating ropes 1.5.

The high-potential conductive net 1.1, the insulating net 1.2 and the low-potential conductive net 1.3 are arranged in a split shape, and the high-potential conductive net 1.1 and the low-potential conductive net 1.3 are symmetrically arranged on two sides of the insulating net 1.2.

Example 2

Fig. 1 is a schematic structural view of the throwing type mesh electric stunner of the present invention. Fig. 3a to 3d respectively show the structure schematic diagrams of the high potential conductive net, the insulating net, the low potential conductive net and the mesh-shaped electric shock device of embodiment 1 of the present invention. Fig. 7 is a schematic diagram of the high potential output end structure of the electric shock high voltage generator of the throwing type mesh electric stunner of the present invention. Fig. 8 is a schematic view of the structure of the bottom potential output end of the electric shock high voltage generator of the throwing type mesh electric stunner of the present invention. Fig. 9 is a side view of the electric shock high voltage generator of the tossing-type mesh stunner of the present invention. Fig. 10 is a schematic view of the connection state between the electric shock high voltage generator and the mesh electric shock device of the throwing type mesh electric shock device of the present invention. Fig. 11 is a circuit diagram of the electric shock pulse high voltage generation of the electric shock high voltage generator of the throwing type mesh electric stunner of the present invention. Fig. 12 is a front view of the emitter of the throwing type mesh electric stunner of the present invention. Fig. 13 is a top view of the emitter of the throwing type electric stunner. Fig. 14 is a schematic diagram of a state to be sent of the throwing type mesh electric stunner of the present invention. Fig. 15 is a schematic block diagram of the transmitter quick interface of the tossing-type mesh stunner of the present invention. Fig. 16 is a schematic structural view of a launcher of a throwing type mesh electric stunner according to the present invention.

As shown in fig. 1, 3 a-3 d, 7, 10-16, the throwing-type mesh stunner includes a high-voltage shock generator 2, a mesh stunner 1 connected to the high-voltage shock generator 2, a mesh stunner-emitting retractor 3 connected to the mesh stunner 1, and a transmitter 4;

the mesh-shaped electric shock device 1 comprises a high-potential conductive net 1.1, an insulating net 1.2 and a low-potential conductive net 1.3, wherein the high-potential conductive net 1.1 is connected to the low-potential conductive net 1.3 through the insulating net 1.2, so that the mesh-shaped electric shock device 1 is in a spider-web shape;

wherein, the electric shock high voltage generator 2 comprises a high potential output end 2.1 and a bottom potential output end 2.2, the high potential output end 2.1 is electrically connected with the high potential conductive net 1.1, the bottom potential output end 2.1 is electrically connected with the low potential conductive net 1.3, an insulating layer 1.6 is arranged at the joint of the net-shaped electric shock device 1 and the electric shock high voltage generator 2

Wherein, netted electric shock ware transmission tractor 2 sets up on the outer peripheral edge of spider-web shape, including haulage rope 3.1 and tractor, haulage rope 3.1 one end connect in the tractor, the other end connect in netted electric shock ware 1, haulage rope 3.1 with the junction of netted electric shock ware 1 is haulage rope knot rope point 3.2.

Wherein the mesh electric stunner 1, the electric stunning high voltage generator 2 and the mesh electric stunner emitting retractor 3 are arranged in the emitter 4.

Wherein, transmitter 4 includes that transmitter trunk line 4.1, a plurality of tractor launching tube 4.2, transmitter quick-operation interface 4.3, trunk line seal board 4.4 and tractor launching tube seal end cap 4.5, tractor launching tube 4.2 is located transmitter trunk line 4.1's outer edge, transmitter quick-operation interface 4.3 connect in transmitter air flue 4.11, transmitter air flue 4.11 communicate in transmitter trunk line 4.1 reaches tractor launching tube 4.2, trunk line seal board 4.4 is used for sealing transmitter trunk line 4.1, tractor launching tube seal end cap 4.5 is used for sealing tractor launching tube 4.2.

Wherein, transmitter quick interface 4.3 includes lock sleeve 4.6, adapter main part 4.7, locking steel ball 4.8, locking reset spring 4.9 and sealing washer 4.10, adapter main part 4.7 sets up the one end of lock sleeve 4.6, locking reset spring 4.9 sets up adapter main part 4.7 with between the lock sleeve 4.6, locking steel ball 4.8 sets up on the interior edge of lock sleeve 4.6, semicircular groove has been seted up on the outer wall of transmitter air flue 4.11, locking steel ball 4.8 can the joint be in the semicircular groove, sealing washer 4.10 sets up adapter main part 4.7 is close to the one end of lock sleeve 4.6.

Wherein the electric shock high voltage generator 2 is located at the center of the spider-web shape.

The high-potential conductive net 1.1 and the low-potential conductive net 1.3 are formed by splicing wires 1.4, and the insulating net 1.2 is formed by weaving and splicing insulating ropes 1.5.

The high-potential conductive net 1.1, the insulating net 1.2 and the low-potential conductive net 1.3 are arranged in a multi-branch shape in a warp direction, and the high-potential conductive net 1.1, the insulating net 1.2 and the low-potential conductive net 1.3 are alternately arranged at intervals.

Example 3

Fig. 1 is a schematic structural view of the throwing type mesh electric stunner of the present invention. Fig. 4a to 4d are schematic structural diagrams of the high potential conductive net, the insulating net, the low potential conductive net and the mesh-shaped electric shock device according to embodiment 3 of the present invention. Fig. 7 is a schematic diagram of the high potential output end structure of the electric shock high voltage generator of the throwing type mesh electric stunner of the present invention. Fig. 8 is a schematic view of the structure of the bottom potential output end of the electric shock high voltage generator of the throwing type mesh electric stunner of the present invention. Fig. 9 is a side view of the electric shock high voltage generator of the tossing-type mesh stunner of the present invention. Fig. 10 is a schematic view of the connection state between the electric shock high voltage generator and the mesh electric shock device of the throwing type mesh electric shock device of the present invention. Fig. 11 is a circuit diagram of the electric shock pulse high voltage generation of the electric shock high voltage generator of the throwing type mesh electric stunner of the present invention. Fig. 12 is a front view of the emitter of the throwing type mesh electric stunner of the present invention. Fig. 13 is a top view of the emitter of the throwing type electric stunner. Fig. 14 is a schematic diagram of a state to be sent of the throwing type mesh electric stunner of the present invention. Fig. 15 is a schematic block diagram of the transmitter quick interface of the tossing-type mesh stunner of the present invention. Fig. 16 is a schematic structural view of a launcher of a throwing type mesh electric stunner according to the present invention.

As shown in fig. 1, 4a to 4d, 7, 10 to 16, the throwing-type mesh stunner includes a high-voltage shock generator 2, a mesh stunner 1 connected to the high-voltage shock generator 2, a mesh stunner-emitting retractor 3 connected to the mesh stunner 1, and a transmitter 4;

the mesh-shaped electric shock device 1 comprises a high-potential conductive net 1.1, an insulating net 1.2 and a low-potential conductive net 1.3, wherein the high-potential conductive net 1.1 is connected to the low-potential conductive net 1.3 through the insulating net 1.2, so that the mesh-shaped electric shock device 1 is in a spider-web shape;

wherein, the electric shock high voltage generator 2 comprises a high potential output end 2.1 and a bottom potential output end 2.2, the high potential output end 2.1 is electrically connected with the high potential conductive net 1.1, the bottom potential output end 2.1 is electrically connected with the low potential conductive net 1.3, an insulating layer 1.6 is arranged at the joint of the net-shaped electric shock device 1 and the electric shock high voltage generator 2

Wherein, netted electric shock ware transmission tractor 2 sets up on the outer peripheral edge of spider-web shape, including haulage rope 3.1 and tractor, haulage rope 3.1 one end connect in the tractor, the other end connect in netted electric shock ware 1, haulage rope 3.1 with the junction of netted electric shock ware 1 is haulage rope knot rope point 3.2.

Wherein the mesh electric stunner 1, the electric stunning high voltage generator 2 and the mesh electric stunner emitting retractor 3 are arranged in the emitter 4.

Wherein, transmitter 4 includes that transmitter trunk line 4.1, a plurality of tractor launching tube 4.2, transmitter quick-operation interface 4.3, trunk line seal board 4.4 and tractor launching tube seal end cap 4.5, tractor launching tube 4.2 is located transmitter trunk line 4.1's outer edge, transmitter quick-operation interface 4.3 connect in transmitter air flue 4.11, transmitter air flue 4.11 communicate in transmitter trunk line 4.1 reaches tractor launching tube 4.2, trunk line seal board 4.4 is used for sealing transmitter trunk line 4.1, tractor launching tube seal end cap 4.5 is used for sealing tractor launching tube 4.2.

Wherein, transmitter quick interface 4.3 includes lock sleeve 4.6, adapter main part 4.7, locking steel ball 4.8, locking reset spring 4.9 and sealing washer 4.10, adapter main part 4.7 sets up the one end of lock sleeve 4.6, locking reset spring 4.9 sets up adapter main part 4.7 with between the lock sleeve 4.6, locking steel ball 4.8 sets up on the interior edge of lock sleeve 4.6, semicircular groove has been seted up on the outer wall of transmitter air flue 4.11, locking steel ball 4.8 can the joint be in the semicircular groove, sealing washer 4.10 sets up adapter main part 4.7 is close to the one end of lock sleeve 4.6.

Wherein the electric shock high voltage generator 2 is located at the center of the spider-web shape.

The high-potential conductive net 1.1 and the low-potential conductive net 1.3 are formed by splicing wires 1.4, and the insulating net 1.2 is formed by weaving and splicing insulating ropes 1.5.

The high-potential conductive net 1.1, the insulating net 1.2 and the low-potential conductive net 1.3 are arranged in a multi-branch shape in a warp direction, and the high-potential conductive net 1.1, the insulating net 1.2 and the low-potential conductive net 1.3 are alternately arranged at intervals.

Example 4

Fig. 1 is a schematic structural view of the throwing type mesh electric stunner of the present invention. Fig. 5a to 5d are schematic structural diagrams of the high potential conductive net, the insulating net, the low potential conductive net and the mesh-shaped electric shock device according to embodiment 4 of the present invention. Fig. 7 is a schematic diagram of the high potential output end structure of the electric shock high voltage generator of the throwing type mesh electric stunner of the present invention. Fig. 8 is a schematic view of the structure of the bottom potential output end of the electric shock high voltage generator of the throwing type mesh electric stunner of the present invention. Fig. 9 is a side view of the electric shock high voltage generator of the tossing-type mesh stunner of the present invention. Fig. 10 is a schematic view of the connection state between the electric shock high voltage generator and the mesh electric shock device of the throwing type mesh electric shock device of the present invention. Fig. 11 is a circuit diagram of the electric shock pulse high voltage generation of the electric shock high voltage generator of the throwing type mesh electric stunner of the present invention. Fig. 12 is a front view of the emitter of the throwing type mesh electric stunner of the present invention. Fig. 13 is a top view of the emitter of the throwing type electric stunner. Fig. 14 is a schematic diagram of a state to be sent of the throwing type mesh electric stunner of the present invention. Fig. 15 is a schematic block diagram of the transmitter quick interface of the tossing-type mesh stunner of the present invention. Fig. 16 is a schematic structural view of a launcher of a throwing type mesh electric stunner according to the present invention.

As shown in fig. 1, 5a to 5d, 7, 10 to 16, the throwing-type mesh stunner includes a high-voltage shock generator 2, a mesh stunner 1 connected to the high-voltage shock generator 2, a mesh stunner-emitting retractor 3 connected to the mesh stunner 1, and a transmitter 4;

the mesh-shaped electric shock device 1 comprises a high-potential conductive net 1.1, an insulating net 1.2 and a low-potential conductive net 1.3, wherein the high-potential conductive net 1.1 is connected to the low-potential conductive net 1.3 through the insulating net 1.2, so that the mesh-shaped electric shock device 1 is in a spider-web shape;

wherein, the electric shock high voltage generator 2 comprises a high potential output end 2.1 and a bottom potential output end 2.2, the high potential output end 2.1 is electrically connected with the high potential conductive net 1.1, the bottom potential output end 2.1 is electrically connected with the low potential conductive net 1.3, an insulating layer 1.6 is arranged at the joint of the net-shaped electric shock device 1 and the electric shock high voltage generator 2

Wherein, netted electric shock ware transmission tractor 2 sets up on the outer peripheral edge of spider-web shape, including haulage rope 3.1 and tractor, haulage rope 3.1 one end connect in the tractor, the other end connect in netted electric shock ware 1, haulage rope 3.1 with the junction of netted electric shock ware 1 is haulage rope knot rope point 3.2.

Wherein the mesh electric stunner 1, the electric stunning high voltage generator 2 and the mesh electric stunner emitting retractor 3 are arranged in the emitter 4.

Wherein, transmitter 4 includes that transmitter trunk line 4.1, a plurality of tractor launching tube 4.2, transmitter quick-operation interface 4.3, trunk line seal board 4.4 and tractor launching tube seal end cap 4.5, tractor launching tube 4.2 is located transmitter trunk line 4.1's outer edge, transmitter quick-operation interface 4.3 connect in transmitter air flue 4.11, transmitter air flue 4.11 communicate in transmitter trunk line 4.1 reaches tractor launching tube 4.2, trunk line seal board 4.4 is used for sealing transmitter trunk line 4.1, tractor launching tube seal end cap 4.5 is used for sealing tractor launching tube 4.2.

Wherein, transmitter quick interface 4.3 includes lock sleeve 4.6, adapter main part 4.7, locking steel ball 4.8, locking reset spring 4.9 and sealing washer 4.10, adapter main part 4.7 sets up the one end of lock sleeve 4.6, locking reset spring 4.9 sets up adapter main part 4.7 with between the lock sleeve 4.6, locking steel ball 4.8 sets up on the interior edge of lock sleeve 4.6, semicircular groove has been seted up on the outer wall of transmitter air flue 4.11, locking steel ball 4.8 can the joint be in the semicircular groove, sealing washer 4.10 sets up adapter main part 4.7 is close to the one end of lock sleeve 4.6.

Wherein the electric shock high voltage generator 2 is located at the center of the spider-web shape.

The high-potential conductive net 1.1 and the low-potential conductive net 1.3 are formed by splicing wires 1.4, and the insulating net 1.2 is formed by weaving and splicing insulating ropes 1.5.

The high-potential conductive net 1.1, the insulating net 1.2 and the low-potential conductive net 1.3 are arranged in a warp shape, the high-potential conductive net 1.1 and the low-potential conductor 1.3 are in a line shape, the insulating net 1.2 is in a net shape, and the high-potential conductive net 1.1, the insulating net 1.2 and the low-potential conductive net 1.3 are alternately arranged and sequentially connected.

Example 5

Fig. 1 is a schematic structural view of the throwing type mesh electric stunner of the present invention. Fig. 6a to 6d are schematic structural diagrams of the high potential conductive net, the insulating net, the low potential conductive net and the mesh-shaped electric shock device according to embodiment 5 of the present invention. Fig. 7 is a schematic diagram of the high potential output end structure of the electric shock high voltage generator of the throwing type mesh electric stunner of the present invention. Fig. 8 is a schematic view of the structure of the bottom potential output end of the electric shock high voltage generator of the throwing type mesh electric stunner of the present invention. Fig. 9 is a side view of the electric shock high voltage generator of the tossing-type mesh stunner of the present invention. Fig. 10 is a schematic view of the connection state between the electric shock high voltage generator and the mesh electric shock device of the throwing type mesh electric shock device of the present invention. Fig. 11 is a circuit diagram of the electric shock pulse high voltage generation of the electric shock high voltage generator of the throwing type mesh electric stunner of the present invention. Fig. 12 is a front view of the emitter of the throwing type mesh electric stunner of the present invention. Fig. 13 is a top view of the emitter of the throwing type electric stunner. Fig. 14 is a schematic diagram of a state to be sent of the throwing type mesh electric stunner of the present invention. Fig. 15 is a schematic block diagram of the transmitter quick interface of the tossing-type mesh stunner of the present invention. Fig. 16 is a schematic structural view of a launcher of a throwing type mesh electric stunner according to the present invention.

As shown in fig. 1, 6a to 6d, 7, 10 to 16, the throwing-type mesh stunner includes a high-voltage shock generator 2, a mesh stunner 1 connected to the high-voltage shock generator 2, a mesh stunner-emitting retractor 3 connected to the mesh stunner 1, and a transmitter 4;

the mesh-shaped electric shock device 1 comprises a high-potential conductive net 1.1, an insulating net 1.2 and a low-potential conductive net 1.3, wherein the high-potential conductive net 1.1 is connected to the low-potential conductive net 1.3 through the insulating net 1.2, so that the mesh-shaped electric shock device 1 is in a spider-web shape;

wherein, the electric shock high voltage generator 2 comprises a high potential output end 2.1 and a bottom potential output end 2.2, the high potential output end 2.1 is electrically connected with the high potential conductive net 1.1, the bottom potential output end 2.1 is electrically connected with the low potential conductive net 1.3, an insulating layer 1.6 is arranged at the joint of the net-shaped electric shock device 1 and the electric shock high voltage generator 2

Wherein, netted electric shock ware transmission tractor 2 sets up on the outer peripheral edge of spider-web shape, including haulage rope 3.1 and tractor, haulage rope 3.1 one end connect in the tractor, the other end connect in netted electric shock ware 1, haulage rope 3.1 with the junction of netted electric shock ware 1 is haulage rope knot rope point 3.2.

Wherein the mesh electric stunner 1, the electric stunning high voltage generator 2 and the mesh electric stunner emitting retractor 3 are arranged in the emitter 4.

Wherein, transmitter 4 includes that transmitter trunk line 4.1, a plurality of tractor launching tube 4.2, transmitter quick-operation interface 4.3, trunk line seal board 4.4 and tractor launching tube seal end cap 4.5, tractor launching tube 4.2 is located transmitter trunk line 4.1's outer edge, transmitter quick-operation interface 4.3 connect in transmitter air flue 4.11, transmitter air flue 4.11 communicate in transmitter trunk line 4.1 reaches tractor launching tube 4.2, trunk line seal board 4.4 is used for sealing transmitter trunk line 4.1, tractor launching tube seal end cap 4.5 is used for sealing tractor launching tube 4.2.

Wherein, transmitter quick interface 4.3 includes lock sleeve 4.6, adapter main part 4.7, locking steel ball 4.8, locking reset spring 4.9 and sealing washer 4.10, adapter main part 4.7 sets up the one end of lock sleeve 4.6, locking reset spring 4.9 sets up adapter main part 4.7 with between the lock sleeve 4.6, locking steel ball 4.8 sets up on the interior edge of lock sleeve 4.6, semicircular groove has been seted up on the outer wall of transmitter air flue 4.11, locking steel ball 4.8 can the joint be in the semicircular groove, sealing washer 4.10 sets up adapter main part 4.7 is close to the one end of lock sleeve 4.6.

Wherein the electric shock high voltage generator 2 is located at the center of the spider-web shape.

The high-potential conductive net 1.1 and the low-potential conductive net 1.3 are formed by splicing wires 1.4, and the insulating net 1.2 is formed by weaving and splicing insulating ropes 1.5.

The high-potential conductive net 1.1, the insulating net 1.2 and the low-potential conductive net 1.3 are arranged in a weft shape, and the insulating net 1.2 and the low-potential conductive net 1.3 are annular, so that the mesh-shaped electric shock device 1 is arranged layer by layer from inside to outside by taking the center as a starting point.

Finally, it should be noted that: although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments described in the foregoing embodiments, or equivalents may be substituted for elements thereof. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (10)

1. A throwing type mesh stunner, characterized in that, the throwing type mesh stunner includes: a high voltage shock generator, a mesh stunner connected to the high voltage shock generator, and a mesh stunner firing retractor connected to the mesh stunner;

the mesh-shaped electric shock device comprises a high-potential conductive net, an insulating net and a low-potential conductive net, wherein the high-potential conductive net is connected to the low-potential conductive net through the insulating net, so that the mesh-shaped electric shock device is in a spider-web shape;

the electric shock high-voltage generator comprises a high-potential output end and a bottom-potential output end, wherein the high-potential output end is electrically connected to the high-potential conductive net, and the bottom-potential output end is electrically connected to the low-potential conductive net;

wherein, netted electroshock ware transmission tractor sets up on the outer peripheral edge of spider-web shape, including haulage rope and tractor, haulage rope one end connect in the tractor, the other end connect in netted electroshock ware.

2. The tossing mesh stunner of claim 1 further comprising a transmitter, the mesh stunner, the high shock voltage generator, the mesh stunner-transmitting retractor for positioning within the transmitter.

3. The net electric shock of type of jettisoning of claim 2, characterized in that, the transmitter includes transmitter trunk line, a plurality of tractor transmitting tubes, the quick interface of transmitter, trunk line sealing plate and tractor transmitting tube sealing plug, the tractor transmitting tube is located the outer edge of transmitter trunk line, the quick interface of transmitter connect in the transmitter air flue, the transmitter air flue communicate in the transmitter trunk line reaches the tractor transmitting tube, the trunk line sealing plate is used for sealing the transmitter trunk line, the tractor transmitting tube sealing plug is used for sealing the tractor transmitting tube.

4. The throwing type mesh electric shock device according to claim 3, wherein the transmitter quick interface comprises a locking sleeve, an adapter body, a locking steel ball, a locking reset spring and a sealing ring, the adapter body is arranged at one end of the locking sleeve, the locking reset spring is arranged between the adapter body and the locking sleeve, the locking steel ball is arranged on the inner edge of the locking sleeve, a semicircular groove is formed in the outer wall of the transmitter air passage, the locking steel ball can be clamped in the semicircular groove, and the sealing ring is arranged at one end, close to the locking sleeve, of the adapter body.

5. The cast mesh stunner according to claim 1 wherein the high and low potential conductive nets are formed by splicing conducting wires or strips, and the insulating net is formed by weaving and splicing insulating rope materials.

6. The cast mesh stunner according to claim 1 wherein the high, insulating and low potential conductive meshes are arranged in a split configuration, the high and low potential conductive meshes being symmetrically disposed on opposite sides of the insulating mesh.

7. The cast mesh stunner according to claim 1 wherein the high, insulating and low potential conductive meshes are arranged in a multi-branch shape in a warp direction, the high, insulating and low potential conductive meshes being alternately spaced.

8. The cast mesh stunner according to claim 1 wherein the high, insulating and low potential conductive nets are arranged in a weft direction in multiple layers, the high, insulating and low potential conductive nets being arranged layer by layer from the inside to the outside starting from the center of the mesh stunner.

9. The cast mesh electric stunner according to claim 1, wherein the high potential conductive mesh, the insulating mesh and the low potential conductive mesh are arranged in a warp shape, the high potential conductive mesh and the low potential conductive mesh are in a line shape, the insulating mesh is in a mesh shape, and the high potential conductive mesh, the insulating mesh and the low potential conductive mesh are alternately arranged and connected in sequence.

10. The cast mesh stunner according to claim 1 wherein the high, insulating and low potential conductive nets are arranged in a weft pattern, the insulating and low potential conductive nets are in a ring shape and are arranged layer by layer from the inside to the outside starting from the center of the mesh stunner.

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