CN214385682U - Mosquito killing device - Google Patents

Abstract

The utility model discloses a mosquito eradication device, including the shell and accept in kill mosquito module in the shell, kill mosquito module includes the lamp shade, locates mosquito lures the mosquito lamp in the lamp shade, locates electric shock net circuit board and the control circuit board of lamp shade and ring are located lamp shade outlying electric shock net, electric shock net circuit board with the control circuit board electricity is connected, electric shock net circuit board with electric shock net welded connection, be equipped with on the shell and trap the passageway, mosquito lures the mosquito lamp and is used for sending the light of luring the mosquito and passes through the lamp shade is outwards shone, follows with luring the mosquito lure the mosquito the passageway flies into quilt in the shell the electric shock net kills. The control circuit board is electrically connected with the electric shock net circuit board to control the voltage intensity of the electric shock net, and the electric shock net is connected with the electric shock net circuit board in a welding mode, so that the stability of electric connection of the electric shock net and the electric shock net circuit board can be enhanced, and the electric shock net is guaranteed to have stable electric shock performance.

Description

Mosquito killing device

Technical Field

The utility model discloses mosquito prevention and cure technical field especially relates to a kill mosquito device.

Background

In summer, mosquitoes are easy to breed in hot weather, and the mosquitoes have certain toxicity and carry a large amount of bacteria. Known mosquito killing methods mainly include mosquito incense, mosquito killer lamps and the like. The smoking generated by burning the mosquito incense can play a role in killing mosquitoes, but can also cause certain influence on human bodies; the mosquito killer lamp usually attracts mosquitoes to approach a light source by adding some trapping agents, and the mosquito attracting effect is poor, so that the mosquito killing effect is limited.

SUMMERY OF THE UTILITY MODEL

In order to solve the existing technical problem, the utility model provides a more effective and safe mosquito eradication device for killing mosquitoes.

In order to achieve the above object, the embodiment of the present invention provides a technical solution that:

the utility model provides a mosquito eradication device, includes the shell and accept in kill mosquito module in the shell, kill mosquito module includes the lamp shade, locates mosquito lures the lamp in the lamp shade, locates electric shock net circuit board and the control circuit board of lamp shade and ring are located lamp shade outlying electric shock net, electric shock net circuit board with the control circuit board electricity is connected, electric shock net circuit board with electric shock net welded connection, trap the passageway on the shell, mosquito lures the lamp and is used for sending the light of luring the mosquito and passes through the lamp shade is outwards shone, in order to lure the mosquito to follow it flies into to trap the passageway quilt in the shell the electric shock net kills.

The lampshade comprises an annular wall and fixing walls extending outwards from two ends of the annular wall, and the upper end and the lower end of the electric shock net are respectively fixed on the fixing walls and are connected with the electric shock net circuit board in a welding mode.

The mosquito killing module further comprises a mosquito-lured lamp circuit board accommodated in the lampshade, and the mosquito-lured lamp is arranged on the mosquito-lured lamp circuit board.

Wherein, the lamp shade includes that inner cover and cover are located the dustcoat outside the inner cover, the annular wall with the fixed wall is located on the dustcoat, mosquito-lured lamp circuit board accept in the dustcoat and be located the below of inner cover.

The electric shock net circuit board is arranged at the upper end of the outer cover, and a through hole for the inner cover to penetrate through is formed in the electric shock net circuit board.

The control circuit board is contained in the inner cover, and the mosquito-lured lamp circuit board is electrically connected with the control circuit board.

The inner cover comprises an accommodating part and an installation part extending outwards from the accommodating part, the control circuit board is accommodated in the accommodating part, and the installation part is located above the outer cover and fixedly installed on the outer shell.

The electric shock net comprises positive electrode wires and negative electrode wires which are alternately arranged along the circumferential direction, and the circuit board of the electric shock net is provided with through holes which are respectively used for the positive electrode wires and the negative electrode wires to correspondingly penetrate through.

The anode electrode wire and the cathode electrode wire are both straight strips and extend along the vertical direction.

The control circuit board is provided with a capacitor and a transformer for enhancing the voltage of the electric shock network, and the control circuit board is electrically connected with the electric shock network circuit board through a lead.

The mosquito killing device provided by the embodiment comprises a shell and a mosquito killing module contained in the shell, wherein the mosquito killing module comprises a lamp shade, a mosquito trapping lamp arranged in the lamp shade, an electric shock net circuit board arranged at one end of the lamp shade and an electric shock net annularly arranged on the periphery of the lamp shade, the electric shock net is welded with the electric shock net circuit board, trapping channels distributed around the circumference of the shell are arranged on the shell, the mosquito trapping lamp is used for emitting light for trapping mosquitoes and irradiating outwards through the lamp shade so as to induce the mosquitoes to fly to the mosquito trapping lamp from the trapping channels and touch the electric shock net to be killed, when the mosquito killing device is used, the mosquitoes are attracted by light trapped by the trapping lamp and fly to the trapping lamp, the mosquitoes touch the electric shock net to be effectively killed, and the purpose of killing pests more safely and effectively is realized; the control circuit board is electrically connected with the electric shock net circuit board to control the voltage intensity of the electric shock net, and the electric shock net is connected with the electric shock net circuit board in a welding mode, so that not only are wires for electrically connecting the electric shock net and the electric shock net circuit board saved, and therefore, the process requirement for connecting the electric shock net and the electric shock net is reduced, but also the stability of the electric connection of the electric shock net and the electric shock net can be enhanced, and the electric shock net is guaranteed to have stable electric shock performance.

Drawings

FIG. 1 is a perspective view of a mosquito eradication device according to an embodiment of the present application;

FIG. 2 is an exploded view of the mosquito eradication device of FIG. 1;

FIG. 3 is a partially exploded view of the mosquito eradication device of FIG. 1;

FIG. 4 is a cross-sectional view of a mosquito eradication device in an embodiment of the present application;

fig. 5 is another sectional view of the mosquito eradication device according to the embodiment of the present application.

Detailed Description

The technical solution of the present invention will be further described in detail with reference to the drawings and specific embodiments. Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used in the description of the invention herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. In the following description, reference is made to the expression "some embodiments" which describe a subset of all possible embodiments, but it should be understood that "some embodiments" may be the same subset or different subsets of all possible embodiments, and may be combined with each other without conflict.

It will also be understood that when an element is referred to as being "secured to" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. The terms "vertical," "horizontal," "inner," "outer," "left," "right," and the like as used herein are for illustrative purposes only and do not denote a unique embodiment.

Please refer to fig. 1 to 3 in combination, which is an embodiment of the present application, and the mosquito killing apparatus includes a housing 10 and a mosquito killing module 20 accommodated in the housing 10, wherein the mosquito killing module 20 includes a lampshade 21, a mosquito-luring lamp 214 disposed in the lampshade 21, an electric shock net circuit board 216 and a control circuit board 217 disposed in the lampshade 21, and an electric shock net 213 annularly disposed at the periphery of the lampshade 21, the electric shock net circuit board 216 is electrically connected to the control circuit board 217, the electric shock net circuit board 216 is welded to the electric shock net 213, a trapping channel 111 is disposed on the housing 10, and the mosquito-luring lamp 214 is used for emitting light for luring mosquitoes and irradiating outwards through the lampshade 21, so as to lure the mosquitoes to fly into the housing 10 from the trapping channel 111 and be killed by the electric shock net 213.

In the above embodiment, when the mosquito killing device is used, mosquitoes are attracted by the light of the trap lamp and fly to the trap lamp 214, and then touch the electric shock net 213 to be effectively killed, so as to achieve the purpose of killing pests more safely and effectively; moreover, the control circuit board 217 is electrically connected to the electric shock net circuit board 216 to control the voltage intensity of the electric shock net 213, and the electric shock net 213 is connected to the electric shock net circuit board 216 by welding, which not only saves the wires for electrically connecting the two, thereby reducing the process requirement for connecting the two, but also can enhance the stability of the electrical connection of the two, and effectively ensures that the electric shock net 213 has stable electric shock performance.

In some embodiments, the lampshade 21 includes an inner cover 211 and an outer cover 212 sleeved outside the inner cover 211, the inner cover 211 includes a receiving portion and an installation portion extending outward from the receiving portion, the installation portion is located above the outer cover 212 and is fixed to the housing 10, specifically, the installation portion extends outward from two opposite sides of the upper end of the receiving portion. The outer cover 212 comprises an annular wall 2121 and a fixed wall 2122 extending outwards from two ends of the annular wall 2121, the mosquito killing module 20 further comprises a mosquito-lured lamp circuit board 215 accommodated in the outer cover 212, the mosquito-lured lamp circuit board 215 is located below the inner cover 211, the mosquito-lured lamp 214 is arranged on the mosquito-lured lamp circuit board 215, and the upper end and the lower end of the electric shock net 213 are respectively fixed on the fixed wall 2122 and are connected with the electric shock net circuit board 216 in a welding manner. Through the design of inner cover 211 and dustcoat 212, can be with mosquito-lured lamp circuit board 215 and electric shock net circuit board 216 mutual isolation, and easily installing of mosquito-lured lamp 214 and electric shock net 213 optimizes mosquito eradication device's inside overall arrangement. Optionally, the fixing wall 2122 may be provided with a plurality of positioning holes along the circumferential direction, so that the electrode wires in the shielding net 213 are respectively and correspondingly inserted into the positioning holes and then welded and fixed. The shape of the electric shock net circuit board 216 may be the same as that of the fixed wall 2122, and the electric shock net circuit board 216 may also be provided with through holes for the electrode wires in the electric shock net 213 to penetrate through correspondingly.

Optionally, the electric shock net circuit board 215 is disposed at the upper end of the outer cover 212, a through hole for the inner cover 211 to pass through is disposed on the electric shock net circuit board 215, and the electric shock net circuit board 215 may be disposed on a fixed wall at the upper end of the outer cover 212, so that the overall structure of the electric shock net circuit board 215, the outer cover 212, and the inner cover 211 is more compact.

Optionally, the control circuit board 217 is accommodated in the installation portion of the inner cover 211, and the mosquito-lured lamp circuit board 215 and the electric shock net circuit board 216 are electrically connected to the control circuit board 217 through wires (not shown). The control circuit board 217 can be provided with a capacitor, a transformer 218 and other circuits, the capacitor and the transformer 218 are used for enhancing the voltage of the electric shock net 213, and the circuit on the mosquito-lured lamp circuit board 215 for controlling the mosquito-lured lamp 214 to work and the circuit on the electric shock net circuit board 216 for controlling the electric shock net 213 to work are respectively connected with the circuits on the control circuit board 217. Optionally, the shape and size of the mosquito-lured lamp circuit board 215 can be substantially the same as the cross section of the inner cover 212, the mosquito-lured lamp 214 can be arranged on the mosquito-lured lamp circuit board 215 and kept away from the lower surface of the inner cover 211, the inner cover 211 separates the control circuit board 217 and the mosquito-lured lamp circuit board 215 from top to bottom, and the influence of heat generated in the work of the mosquito-lured lamp 214 on the work of the control circuit board 217 can be avoided.

In some embodiments, the electric shock net 213 includes positive electrode wires and negative electrode wires alternately arranged along a circumferential direction, the positive electrode wires and the negative electrode wires are straight and extend along an up-and-down direction, and the electric shock net circuit board 216 is provided with through holes for the positive electrode wires and the negative electrode wires to correspondingly penetrate through. The anode electrode wires and the cathode electrode wires can be arranged in a single layer and are alternately arranged along the circumferential direction; or the cathode electrode wire and the anode electrode wire are arranged in an inner layer and an outer layer, and the cathode electrode wire on the outer layer and the anode electrode wire on the inner layer are alternately arranged along the circumferential direction. The two ends of the positive electrode wire electrode and the negative electrode wire electrode are respectively connected with the fixing walls 2122 at the two ends of the outer cover 212 to form a net structure surrounding the axial direction of the lampshade 21, so that the mosquito killing lamp has a comprehensive and effective killing effect on mosquitoes attracted by the mosquito trapping lamp 214 and flying to the mosquito trapping lamp 214.

In some embodiments, the mosquito killing apparatus further includes a fan 22 housed in the housing 10, a working circuit for controlling the mosquito-lured lamp 214, the electric shock net 213 and the fan 22, and a mosquito-luring agent 16 located on an air outlet path of the fan 22, the housing 10 includes an upper housing 11 and a lower housing 12 detachably connected, the mosquito killing module 20 further includes a driving switch 143 for controlling the on-off of the working circuit, a pushing member 151 is disposed inside one of the upper housing 11 and the lower housing 12, when the upper housing 11 and the lower housing 12 are assembled with each other, the pushing member 151 presses the driving switch 143 to turn on the working circuit, so that the mosquito-lured lamp 214, the electric shock net 213 and the fan 22 can work, when the upper housing 11 is separated from the lower housing 12, the pushing member 151 releases the pressing of the driving switch 143 to disconnect the working circuit, the mosquito-lured lamp 214, the electric shock net 213 and the fan 22 are controlled to stop working.

The mosquito-attracting agent 16 comprises a container and a mosquito-attracting material arranged in the container, wherein the mosquito-attracting material can be liquid or solid, has volatility and can emit odor capable of attracting mosquitoes. The mosquito attractant 16 is arranged on the air outlet path of the fan 22, the air flow blown out by the fan 22 can accelerate the diffusion of the mosquito attractant 16, and can also enlarge the diffusion range of the odor diffused by the mosquito attractant 16, so as to realize the effect of attracting mosquitoes more effectively. The pushing element 151 is disposed inside one of the upper case 11 and the lower case 12, and may be the pushing element 151 disposed on the upper case 11 or on another element inside the upper case 11 and relatively fixedly connected to the upper case 11, or the pushing element 151 disposed on the lower case 12 or on another element inside the lower case 12 and relatively fixedly connected to the lower case 12, so as to ensure that the pushing element 151 can form a pushing force on the driving switch 143 when the upper case 11 and the lower case 12 are assembled together, and the pushing element 151 presses the driving switch 143 to conduct the working circuit. When the upper shell 11 is separated from the lower shell 12, the pushing element 151 releases the pressing of the driving switch 143 to break the working circuit, so as to control the fan 22 to stop working, the fan 22 can normally work when a user assembles the upper shell 11 and the lower shell 12, and when the upper shell 11 and the lower shell 12 are disassembled and separated, the fan 22 stops working, so that the user is prevented from being scratched by the fan 22 in a working state when disassembling and separating the upper shell 11 and the lower shell 12 to clean mosquitoes in the shell 10, and the purpose of killing pests more safely and effectively is achieved. Wherein, the working circuit can be arranged on the control circuit board 217.

The lamp housing 21 is located inside the upper case 11, and an opening portion and an upper cover 13 detachably attached to the opening portion are formed at a top end of the upper case 11. The opening part is larger than the cross section size of the lampshade 21, so that the lampshade 21 can be conveniently placed in or taken out and installed through the opening part. Wherein, the surface of upper cover 13 can also be equipped with convenience of customers and take handle 131 of kill mosquito device.

In some embodiments, please refer to fig. 4 and 5 in combination, the mosquito killing module 20 includes a mounting frame 15 for carrying the fan 22 and an inner housing 14 located on one side of the mounting frame 15, the driving switch 143 is located on the inner housing 14, the pushing element 151 is located on the mounting frame 15, the pushing element 151 has a push rod capable of moving up and down relative to the mounting frame 15, and the driving switch 143 is located on a moving path of the push rod, so that the push rod presses the driving switch 143 or releases the pressing of the driving switch 143. The mosquito killing module 20 is installed in a space formed by the upper shell 11 and the lower shell 12, when the upper shell 11 and the lower shell 12 are assembled and connected, the pushing piece 151 correspondingly approaches to the driving switch 143 to form pushing force on the driving switch 143, and the pushing piece 151 pushes the driving switch 143 to switch the driving switch 143 to an on state; on the contrary, when the upper shell 11 and the lower shell 12 are separated from each other, the pushing member 151 is correspondingly away from the driving switch 143 to cancel the pushing force on the driving switch 143, and the driving switch 143 is switched to the off state. In this embodiment, when the upper housing 11 and the lower housing 12 are assembled and connected, the top end of the lower housing 12 forms a pushing force on the pushing member 151 disposed on the mounting frame 15, so that the pushing member 151 applies a pushing force to the driving switch 143, and the driving switch 143 is switched to an on state.

In some embodiments, the mounting frame 15 is located in the upper shell 11, the pushing element 151 includes an elastic sheet further fixed to the mounting frame 15, the push rod is connected to the elastic sheet and can move up and down along the direction of elastic deformation of the elastic sheet, the inner shell seat 14 is located in the upper shell 11 and above the mounting frame 15, and the driving switch 143 is located on a moving path of the push rod, so that the push rod presses the driving switch 143 or releases the pressing of the driving switch 143. Wherein, the shell fragment that supports and pushes away piece 151 can be the bar slice, is fixed in on the mounting bracket 15, the one end of push rod with the shell fragment is connected, when the push rod was kept away from the one end of shell fragment and drive switch 143 butt, because the effect of shell fragment, the push rod can extrude the shell fragment and move the certain distance towards the direction at shell fragment place, and the push rod can resume the pressure of supporting that the acting force of deformation trend can last drive switch 143 formation under the shell fragment. In an alternative embodiment, the actuation switch 143 is a microswitch.

Optionally, the center of the mounting bracket 15 is provided with a mounting post 153 and a mounting seat located below the mounting post 153, the fan 22 is installed on the mounting post 153, two opposite ends of the mounting seat are respectively provided with an opening, one of the openings faces the air inlet 150 of the fan 22, the other opening faces the air outlet of the mosquito storage chamber 122 located in the lower shell 12, and the mounting seat is used for placing the mosquito attractant 16. The opening of the mounting seat surface facing the lower shell 12 is provided with a buckling arm which can play an auxiliary fixing role for the mosquito trapping agent 16 contained in the mounting seat to prevent the mosquito trapping agent 16 from separating from the mounting seat.

The entire housing 10 is substantially cylindrical, and a mosquito storage chamber 122 is formed at the bottom of the lower housing 12, so that mosquitoes attracted into the mosquito killing device can be collected in the mosquito storage chamber 122 after being killed. Mounting bracket 15 is located be close to in the upper shell 11 the one end of inferior valve 12 provides the erection column 153 of fan 22 installation and the mount pad that is used for placing mosquito luring agent 16 and all forms in on mounting bracket 15, can ensure that the air current of fan 22's air outlet outflow can blow to mosquito luring agent 16 at first concentratedly, and the air current can promote the volatilizing of mosquito luring agent 16, and the air current that lures mosquito agent 16 of flowing through carries the smell flow direction air-out passageway 121 on the inferior valve 12 that mosquito lures agent 16 and give off, and follow air-out passageway 121 flows out the mosquito killing device, mounting bracket 15's setting not only makes 20 overall structure of kill mosquito module compacter, and can ensure that fan 22's air current concentrates the flow direction and lures mosquito agent 16 and obtain better mosquito effect of luring. Optionally, a partition portion 152 is disposed on a side of the mounting seat surface facing the fan 22, and the air inlet 150 facing the fan 22 is circumferentially disposed on a periphery of the partition portion 152. The size of the partition 152 is smaller than the size of the opening. The partition portion 152 is disposed to shield a portion of the opening of the mounting seat facing the air outlet of the fan 22, so that the air flow of the fan 22 can flow to the mosquito repellent 16 in the mounting seat through the space between the partition portion 152 and the mounting seat, and meanwhile, the odor volatilized by the mosquito repellent 16 in the mounting seat can be reduced from flowing to the inside of the fan 22, thereby generating a corrosion effect on the motor in the fan 22.

Optionally, an air outlet channel 121 is formed on the lower casing 12. Outside air can form the air current under fan 22's high-speed rotation and blow to luring mosquito agent 16 in getting into mosquito killing device through the passageway 111 that traps on the epitheca 11, promotes luring volatilizing of mosquito agent 16, carrying luring mosquito agent 16's smell follow the air-out passageway 121 of inferior valve 12 flows mosquito killing device the inside air current passageway that forms from epitheca 11 to inferior valve 12 of mosquito killing device avoids the inside turbulent flow that produces of mosquito killing device.

In some embodiments, the mosquito eradication module 20 further includes an anti-escape net 123 installed in the lower case 12, the anti-escape net 123 partitions the lower case 12 to form the mosquito storage chamber 122 and a containing chamber for containing the installation seat, and a hole for communicating the containing chamber and the mosquito storage chamber 122 is formed on the anti-escape net 123. Prevent escaping net 123's outline size with the cross sectional dimension of inferior valve 12 is roughly the same, prevents escaping net 123 can be the toper, the hole can include from preventing escaping net 123's the outside radial distribution in center bar hole, and each hole is following can be the slope form in the direction that the central axis of inferior valve 12 extends, so, can be in order to ensure to receive mosquito attractant 16 and lure and the mosquito that gets into mosquito eradication device can drop to storing up in the mosquito room 122 through the hole from mosquito-proof net's top, can prevent again that the mosquito that drops to storing up in the mosquito room 122 from passing through the hole is reverse to escape mosquito eradication device.

In some embodiments, the inner housing seat 14 includes a top wall and a side wall extending from the top wall and disposed in an annular shape, the top wall and the side wall jointly enclose a receiving cavity, the receiving cavity provides a space for placing the fan 22, and the operating circuit and the driving switch 143 are both disposed on the side wall. The inner casing seat 14 is located in the upper casing 11 and connected to the upper casing 11, one side of the inner casing seat 14 on which the side wall is formed faces the mounting frame 15, the end of the side wall far away from the top wall is abutted to the mounting frame 15, the side wall is annularly arranged on the periphery of the fan 22, an annular air flow channel is formed between the inner surface of the side wall and the end of the fan blade of the fan 22, and the function of guiding the air flow of the fan 22 to intensively flow to the mosquito-luring agent 16 in the mounting seat from the air outlet can be achieved. Optionally, a power button 112 may be further disposed on the upper case 11, the power button 112 may be electrically connected to the control switch 142 of the trap lamp and the electric shock net 213, and the trap lamp and the electric shock net 213 may be controlled to be turned on or off by the power button 112.

The mosquito eradication device that this application embodiment provided possesses following characteristics at least:

firstly, a mosquito-lured lamp 214 and an electric shock net 213 are arranged in the mosquito killing device, and the mosquito-lured lamp 214 and the trapping agent can play a double reinforcing role in trapping mosquitoes; the control circuit board 217 and the electric shock net circuit board 216 are arranged on the lampshade 21, the control circuit board 217 is electrically connected to the electric shock net circuit board 216 to control the voltage intensity of the electric shock net 213, and the electric shock net circuit board 216 is connected with the electric shock net 213 in a welding manner, so that not only are wires for electrically connecting the control circuit board 217 and the electric shock net circuit board 216 saved, but also the process requirement for connecting the control circuit board 217 and the electric shock net circuit board 216 is reduced, the stability of the electric connection of the control circuit board 217 and the electric shock net circuit board 216 is enhanced, and the electric shock net 213 is ensured to have stable electric shock performance;

secondly, a lampshade 21 is arranged in the mosquito killing device, the lampshade 21 is convenient for installing a mosquito-lured lamp 214 and an electric shock net 213 through the design of an inner cover 211 and an outer cover 212, the mosquito-lured lamp circuit board 215 and the electric shock net circuit board 216 are easy to assemble, and the internal layout of the mosquito killing device is optimized;

thirdly, the mosquito killing device comprises a fan 22 arranged in the shell 10 and a trapping agent arranged on an air outlet path of the fan 22, the volatilization capacity and the diffusion range of the trapping agent can be improved by utilizing air flow generated by the fan 22, and the mosquito killing device plays a more effective role in trapping mosquitoes;

fourthly, the mosquito killing device comprises a driving switch 143 and a pushing part 151, when the upper shell 11 and the lower shell 12 are assembled, the pushing part 151 pushes the driving switch 143 to conduct a working circuit of the fan 22, the fan 22 can work normally, and when the upper shell 11 and the lower shell 12 are disassembled and separated from each other, the pushing part 151 is far away from the driving switch 143 to break the working circuit, so that a user is prevented from being scratched by the rotating fan 22 after the upper shell 11 and the lower shell 12 are disassembled, and the purpose of killing pests more safely and effectively is realized.

The above description is only for the specific embodiments of the present invention, but the protection scope of the present invention is not limited thereto, and any person skilled in the art can easily think of the changes or substitutions within the technical scope of the present invention, and all should be covered within the protection scope of the present invention. The protection scope of the present invention shall be subject to the protection scope of the claims.

Claims (10)

1. The utility model provides a mosquito eradication device, its characterized in that, include the shell and accept in kill mosquito module in the shell, kill mosquito module includes the lamp shade, locates mosquito lures the mosquito lamp in the lamp shade, locates electric shock net circuit board and the control circuit board of lamp shade and ring are located lamp shade outlying electric shock net, electric shock net circuit board with the control circuit board electricity is connected, electric shock net circuit board with electric shock net welded connection, be equipped with on the shell and trap the passageway, mosquito lures the mosquito lamp and is used for sending the light of luring the mosquito and passes through the lamp shade is outwards shone, with luring the mosquito and following it flies into to trap the passageway quilt in the shell the electric shock net kills.

2. The mosquito eradication apparatus according to claim 1, wherein the lamp housing includes an annular wall and fixing walls extending outward from both ends of the annular wall, and upper and lower ends of the electric shock net are respectively fixed to the fixing walls and are connected to the electric shock net circuit board by welding.

3. The mosquito eradication device according to claim 2, wherein the mosquito eradication module further comprises a mosquito-lured lamp circuit board accommodated in the lamp cover, and the mosquito-lured lamp is arranged on the mosquito-lured lamp circuit board.

4. The mosquito eradication apparatus according to claim 3, wherein the lamp cover includes an inner cover and an outer cover fitted over the inner cover, the annular wall and the fixing wall are provided on the outer cover, and the mosquito-lured lamp circuit board is accommodated in the outer cover and located below the inner cover.

5. The mosquito eradication apparatus according to claim 4, wherein the electric shock net circuit board is disposed at an upper end of the outer cover, and a through hole through which the inner cover is inserted is formed on the electric shock net circuit board.

6. The mosquito eradication apparatus according to claim 4, wherein the control circuit board is received in the inner cover, and the mosquito trap lamp circuit board is electrically connected to the control circuit board.

7. The mosquito eradication device according to claim 6, wherein the inner cover includes an accommodating portion and an installation portion extending outward from the accommodating portion, the control circuit board is accommodated in the accommodating portion, and the installation portion is located above the outer cover and is fixedly installed on the housing.

8. The mosquito eradication device according to any one of claims 1 to 7, wherein the electric shock net comprises positive electrode wires and negative electrode wires which are alternately arranged along a circumferential direction, and the electric shock net circuit board is provided with through holes through which the positive electrode wires and the negative electrode wires are correspondingly inserted respectively.

9. The mosquito eradication apparatus according to claim 8, wherein the positive electrode wire and the negative electrode wire are each formed in a straight strip shape and extend in an up-and-down direction.

10. The mosquito eradication apparatus according to any one of claims 1 through 7, wherein a capacitor and a transformer for increasing the voltage of the electric shock net are provided on the control circuit board, and the control circuit board and the electric shock net circuit board are electrically connected by a wire.

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