CN215957918U - Airborne electric mosquito swatter - Google Patents

Abstract

An airborne electric mosquito swatter comprises an electric mosquito swatter and an unmanned aerial vehicle; the electric mosquito swatter comprises an electric mosquito swatter main frame, and a safety isolation net, a high-voltage negative electrode power grid, a high-voltage positive electrode power grid, a solar cell panel and a high-voltage conversion circuit board are sequentially arranged on the electric mosquito swatter main frame; the solar cell panel is arranged at the top of the unmanned aerial vehicle and is hermetically connected with the main frame of the electric mosquito swatter; the unmanned aerial vehicle comprises a multi-flying-wing unmanned aerial vehicle, a control circuit board, a battery, a lithium battery charging circuit and a high-voltage conversion circuit. The airborne electric mosquito swatter is used for replacing the traditional electric mosquito swatter, so that time and labor are avoided when people hold the electronic mosquito swatter all the time; utilize the suction that unmanned aerial vehicle high speed motor produced, can kill in certain distance can inhaling the electric mosquito bat with the mosquito, labour saving and time saving has just enlarged the space of electric mosquito bat kill mosquito. Through controlling the positive and negative rotation of the wings of the unmanned aerial vehicle, the garbage on the point net can be timely and efficiently removed, and the efficiency and the service life of the electric mosquito swatter are improved.

Description

Airborne electric mosquito swatter

Technical Field

The utility model relates to the technical field of mosquito killing devices, in particular to an airborne electric mosquito swatter.

Background

The electric mosquito swatter is a household small electric appliance, has the advantages of good mosquito killing effect, simple and convenient use, no odor, no toxicity, no harm, no chemical pollution and the like, is popular with people, and gradually becomes an indispensable tool for killing mosquitoes in summer.

The traditional electric mosquito swatter is handheld, the electric net needs to be in close contact with the mosquito when the mosquito is swatted, and the design has the defects that time and labor are wasted when the mosquito is swatted, the mosquito easily escapes, and the electric mosquito swatter is limited by space and is difficult to really play the whole net.

And present electric mosquito swatter is using the back, does not have the part of taking certainly that clears up the electric mosquito swatter electric wire netting, needs to clear up with other article in addition, has remaining rubbish can pollute the desktop of placing on the electric wire netting when not clearing up in time, also can make the effect variation of electric wire netting damage even.

Therefore, further improvements to the existing electric mosquito swatter are needed.

SUMMERY OF THE UTILITY MODEL

The technical scheme adopted by the utility model is as follows: an airborne electric mosquito swatter comprises an electric mosquito swatter and an unmanned aerial vehicle; the electric mosquito swatter comprises an electric mosquito swatter main frame, wherein a safety isolation net, a high-voltage negative electrode power grid, a high-voltage positive electrode power grid, a solar cell panel and a high-voltage conversion circuit board are sequentially arranged on the electric mosquito swatter main frame, the high-voltage conversion circuit board is electrically connected with the safety isolation net, the high-voltage negative electrode power grid, the high-voltage positive electrode power grid and the solar cell panel, and the solar cell panel is used for acquiring solar energy and converting the solar energy into electric energy for the use of the electric mosquito swatter. The solar cell panel is arranged at the top of the unmanned aerial vehicle and is hermetically connected with the main frame of the electric mosquito swatter, so that all air required by wings of the unmanned aerial vehicle comes from meshes of a power grid, and mosquitoes can be conveniently sucked into the electric mosquito swatter; the unmanned aerial vehicle comprises a multi-flying-wing unmanned aerial vehicle, a control circuit board, a battery, a lithium battery charging circuit and a high-voltage conversion circuit.

Further, the high-voltage conversion circuit board comprises a high-frequency oscillation circuit and a triple voltage rectification circuit.

Further, control circuit board includes MCU controller, unmanned aerial vehicle control circuit, high-pressure converting circuit, wireless receiver, lithium battery charging circuit, the USB interface that charges.

Further, the multi-flying-wing unmanned aerial vehicle is at least four flying-wing unmanned aerial vehicles.

Furthermore, the safety isolation net is made of an insulating material, so that electric shock cannot occur even if a human body is in contact with the safety isolation net during use.

Furthermore, the voltage of the high-voltage conversion circuit is 1800V at the lowest.

Furthermore, the capacity of the lithium battery is 2600mAh at least.

Further, the control circuit board is a microprocessor of model STM32F103C8T 6.

Furthermore, the wings of the multi-winged unmanned aerial vehicle can rotate forwards and backwards, so that corpses and other dirt on the power grid can be conveniently cleaned.

Has the advantages that: compared with the prior art, the airborne electronic mosquito swatter is used for replacing the traditional electronic mosquito swatter, so that the situations of space limitation, time waste and labor waste of mosquito eradication are avoided. The electric mosquito swatter can suck mosquitoes into the electric mosquito swatter for killing at a certain distance by utilizing the suction force generated when the high-power wing of the unmanned aerial vehicle runs, and time and labor are saved. The unmanned aerial vehicle high-speed motor can rotate forward and backward, can timely and effectively remove garbage on a power grid, and improves the efficiency and the service life of the electric mosquito swatter.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a schematic structural view of the present invention;

FIG. 3 is a partial structural schematic diagram of the present invention.

In the figure, (1) an electric mosquito swatter main frame, (2) an unmanned aerial vehicle, (3) a solar panel, (4) a high-voltage positive grid, (5) a high-voltage positive grid, and (6) a safety isolation grid.

Detailed Description

In order that the utility model may be more fully understood, reference will now be made to the accompanying drawings. The utility model may be embodied in different forms and is not limited to the embodiments described herein. Rather, the embodiments are provided so that this disclosure will be thorough and complete.

As shown in the attached drawing, the airborne electric mosquito swatter comprises an electric mosquito swatter and an unmanned aerial vehicle 2; the electric mosquito swatter comprises an electric mosquito swatter main frame 1, wherein a safety isolation net 6, a high-voltage negative electrode power grid 5, a high-voltage positive electrode power grid 4, a solar cell panel 3 and a high-voltage conversion circuit board which are made of insulating materials are sequentially arranged on the electric mosquito swatter main frame 1, the high-voltage conversion circuit board is electrically connected with the safety isolation net 6, the high-voltage negative electrode power grid 5, the high-voltage positive electrode power grid 4 and the solar cell panel 3, and the solar cell panel 3 is used for acquiring solar energy and converting the solar energy into electric energy for being used by the electric mosquito swatter. The solar cell panel 3 is arranged at the top of the unmanned aerial vehicle 2 and is hermetically connected with the main frame 1 of the electric mosquito swatter, so that all air required by the wings of the unmanned aerial vehicle 2 comes from meshes of a power grid, and mosquitoes can be conveniently sucked into the electric mosquito swatter; unmanned aerial vehicle 2 includes many flying wing unmanned aerial vehicle, control circuit board, battery, lithium battery charging circuit and high-voltage transformation circuit. The high-voltage conversion circuit board comprises a high-frequency oscillation circuit and a triple voltage rectifying circuit; the control circuit board comprises an MCU controller, an unmanned aerial vehicle control circuit, a high-voltage conversion circuit, a wireless receiver, a lithium battery charging circuit and a USB charging interface. The multi-flying-wing unmanned aerial vehicle is at least four-flying-wing unmanned aerial vehicle, and the wings can rotate forwards and backwards so as to conveniently clean corpses and other dirt on the power grid. The safety isolation net 6 is made of an insulating material, so that electric shock can not occur even if a human body is in contact with the safety isolation net. The voltage of the high-voltage conversion circuit is 1800V at least, and the capacity of the lithium battery is 2600mAh at least. The control circuit board is a microprocessor of model STM32F103C8T 6.

When the flying mosquito killer is used, the fully charged airborne electronic mosquito swatter is opened, the unmanned aerial vehicle 2 is remotely controlled to catch up mosquitoes, and the mosquitoes in a certain range are sucked into the electronic mosquito swatter to be killed by utilizing the suction force generated when the wings of the unmanned aerial vehicle 2 rotate at a high speed. The airborne electric mosquito swatter has more obvious advantages for the places with dense rural field mosquitoes.

When the electric net of electric mosquito swatter needs to be cleared up, only need with the wing of unmanned aerial vehicle 2 high-speed transportation in the opposite direction can.

When the electric mosquito swatter battery is dead, the solar panel 3 can be used for collecting solar energy and converting the solar energy into electric energy; or the charging wire is inserted into the USB interface for charging so as to be used next time.

The above examples are only intended to illustrate the technical solution of the present invention, but not to limit it; although the present invention has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some technical features may be equivalently replaced; and such modifications or substitutions do not depart from the spirit and scope of the corresponding technical solutions of the embodiments of the present invention.

Claims (9)

1. An airborne electric mosquito swatter is characterized in that: comprises an electric mosquito swatter and an unmanned aerial vehicle; the electric mosquito swatter comprises an electric mosquito swatter main frame, wherein a safety isolation net, a high-voltage negative electrode power grid, a high-voltage positive electrode power grid, a solar cell panel and a high-voltage conversion circuit board are sequentially arranged on the electric mosquito swatter main frame, and the high-voltage conversion circuit board is electrically connected with the safety isolation net, the high-voltage negative electrode power grid, the high-voltage positive electrode power grid and the solar cell panel; the solar cell panel is arranged at the top of the unmanned aerial vehicle and is hermetically connected with the main frame of the electric mosquito swatter; the unmanned aerial vehicle comprises a multi-flying-wing unmanned aerial vehicle, a control circuit board, a battery, a lithium battery charging circuit and a high-voltage conversion circuit.

2. An airborne electronic mosquito swatter according to claim 1 wherein the high voltage conversion circuit board comprises a high frequency oscillating circuit, a triple voltage rectifying circuit.

3. The airborne electronic mosquito swatter as recited in claim 1, wherein the control circuit board comprises an MCU controller, an unmanned aerial vehicle control circuit, a high voltage conversion circuit, a wireless receiver, a lithium battery charging circuit, and a USB charging interface.

4. An airborne electronic mosquito swatter, as claimed in claim 1, wherein said multiple-wing drone is at least a four-wing drone.

5. The airborne electronic mosquito swatter as recited in claim 1 wherein the safety isolating mesh is of an insulating material.

6. An airborne electronic mosquito swatter as recited in claim 1 wherein said high voltage transformation circuit has a voltage of 1800V minimum.

7. An airborne electronic mosquito swatter as recited in claim 1 wherein said lithium battery has a capacity of at least 2600 mAh.

8. An airborne electronic mosquito swatter according to claim 1 wherein the control circuit board is a microprocessor of type STM32F103C8T 6.

9. An airborne electronic mosquito swatter, as claimed in claim 4 wherein said multiple wing drone has wings that rotate in both forward and reverse directions.

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