A mosquito-trapping light source module, an electric mosquito swatter and a mosquito killer are disclosed, the mosquito-trapping light source module includes two or more LED chips with different wavelengths, the wavelengths of the LED chips range from 360 nm to 400 nm. By configuring the two or more LED chips with different wavelengths, the mosquito-trapping light source module has a wide spectral range, so that mosquitoes in different types and regions are trapped, the mosquitoes are trapped under different environmental conditions, and a good mosquito-trapping effect is achieved. By setting the wavelengths of the LED chips to range from 360 nm to 400 nm, an appropriate wavelength range is selected according to currently common mosquitoes and actual environmental conditions of use to reduce power waste and maintain a good mosquito-trapping effect.

A zapper includes an insect-inducing wick, an electric shock coil, a power supply module, a lamp housing, and a cleaning brush. The lamp housing includes a plurality of lateral ribs spaced apart, a plurality of longitudinal ribs spaced apart and intersecting the lateral ribs, and a plurality of openwork portions formed between the lateral ribs and the longitudinal ribs. At least one of the longitudinal ribs is formed with a longitudinal track in openwork-shaped thereon. The cleaning brush includes a brush body disposed around the insect-inducing wick and selectively contacting the electric shock coil, and at least one operation member connected to the brush body and operable to move along the longitudinal track. The at least one operation member includes a connection portion extending through the longitudinal track into the lamp housing to connect to the brush body, and an operation portion exposed outside the lamp housing.

A telescopic multifunctional mosquito killing lamp is provided, which includes a base, a mosquito killing module, and a lamp. The mosquito killing module is provided on the base, the lamp is provided on one end of a telescopic rod. The other end of the telescopic rod runs through the mosquito killing module and is connected to the base; the base is provided with a battery and a PCB board, the mosquito killing module includes a shielding cover, a power grid and a UV light source. The lamp is provided with a lamp board with light beads, and the PCB board is electrically connected to the battery, the power grid, the UV light source, and the lamp board. The lamp uses the telescopic rod and a T-shaped swivel head, the lamp can be extended and rotated for lighting and stored on a top of the shielding cover.

A trap for immobilizing, killing, or containing arthropods comprises a housing having walls and at least one opening, where the walls define an interior space; and a light source comprising a directional light source mounted in the interior space. The light source is constructed to emit light at one or more wavelengths ranging from 350 to 500 nm. The light source is positioned so that a majority of the light emitted from the light source is directed at one or more surfaces in the interior space. The trap also comprises a suppression element mounted in the interior space and constructed to immobilize, kill, or contain arthropods.

Exemplary embodiments of a flashlight having an electronic insect control system are provided. In some exemplary embodiments, a flashlight apparatus is provided, having a head portion comprising a first light source, a tail portion, and a body portion between the head portion and tail portion, the body portion comprising an electronic insect control system, the electronic insect control system comprising a frame portion, a second light source provided within the frame portion, and an electrical grid provided within the frame portion and surrounding the second light source, wherein the electrical grid is configured to generate a voltage.

An electric insect eliminator including a light portion and a conducting grid with a transparent cage surrounding the conducting grid to prevent contact while allowing light to pass therethrough and also amplifying the light emitted from the device.

An anti-pest device for fruit trees and the like that prevents trees from being affected by crawling insect pests includes a rectangular sheet of electrical insulating material, which can adopt the shape of an inverted truncated cone or a cylindrical configuration around the trunk of the tree; a band of low-density foam under the sheet that adapts to the physiognomy of the bark, and deforms with the growth of the trunk, whereas the sheet includes a sector that is superimposed thereon and slides on it to adapt to said growth; a pair of parallel conducting wires, separated a distance according to the size of the body of the insect to be exterminated, subjected to a high difference in electrical potential by means of a power supply circuit, such that when an insect tries to get past them, it is automatically electrocuted.

Method and apparatus for mechanical sex-sorting of mosquitoes by extracting a class of mosquitoes from unsorted mosquitoes comprises obtaining unsorted mosquitoes, obtaining images of individual mosquitoes in a stationary phase, electronically classifying the individuals from the images into male mosquitoes and/or female mosquitoes, and possibly also unclassified objects; obtaining co-ordinates of individuals of at least one of the male mosquito and female mosquito classifications, and using a robot arm to reach an individual identified by the obtained coordinates to store or remove the individuals, thereby to provide sex-sorted mosquitoes.

A method for the management of a soil pest or pathogen includes a source of high voltage electricity; at least one capacitor for storing the high voltage electricity; a multiplicity of electrodes inserted into a soil location having a soil pest and/or pathogen to be managed; and an electrical switch which is controllably opened and closes so as to form a pulse of electricity which is passed through the soil location and between the electrodes so as to effect the management of the soil pest and/or pathogen.

The present disclosure relates to a cleaner station including a suction flow path having an inlet end configured to communicate with a dust bin of a cleaner, a dust collecting part connected to an outlet end of the suction flow path and configured to capture dust in the dust bin of the cleaner, and a spray module disposed at one side of the dust collecting part and configured to spray at least any one of the sterilization gas and particulates into the dust collecting part to kill insects existing in the dust collecting part, in which the spray module sprays the sterilization gas, which contains ozone or ion particles, into the dust collecting part, to kill insects existing in the dust collecting part.