An autonomous drone integrated with wide bandwidth, high energy acoustic wave generators sent to evict and eradicate agricultural pests within a patrolling area. The drone hovering close to a plant bombards its leaves and fruits with high energy acoustic waves via frequency and tone determined by an onboard synthesizer through acoustic power amplified to drive the sideways and bottom mounted acoustic wave generators. Agricultural pests such as caterpillar, beetle and the like are bombarded with powerful acoustic waves causing their bodies to vigorously vibrate and resonate with synthesizer frequency to dislodge or kill the pests. Other insects such as moths are forced airborne by a propeller's strong downdraft and are electrocuted by integrated high voltage screens. Inside a hotel room, the drone hovers close to a surface of a bedding mattress, bombarding the surfaces with powerful acoustic waves tuned to frequencies that cause bed bugs to resonate and die.

A bladeless fan with mosquito killing function, having a base and a wind chamber; the base has an air blower inside; the wind chamber is in communication with an inner cavity of the base; a wall of the wind chamber is provided with an air outlet gap for blowing out an air stream; an electric mosquito killing device is provided in the base below the air blower; through holes are provided on the base (1) for inlet of mosquitos and insects as well as the air stream into the base.

A bug zapper includes a body, a fan and a light source. The body has a compartment, an opening, a channel arranged between the compartment and the opening, and a coupling portion arranged between the compartment and the channel. The channel is formed by an enclosed reflection wall and gradually expands from the coupling portion towards the opening. The fan is coupled with the coupling portion. The light source is mounted on a location of the body adjacent to the fan and irradiates light in the channel. As such, the efficiency in attracting the mosquitoes is outstanding, and the negative effect to the human is reduced.

A bug-removal vacuum machine has a horizontal deck, and a structure providing a trapezoidal-shaped air passage directing insects drawn by vacuum-induced air flow through an electrified killing matrix, and into a collection tray

An insect elimination device has an outer grid with an inner grid disposed within the outer grid. A voltage source powers the inner grid, the outer grid or both. A warming tube is disposed within the inner grid and provides a thermal lure. A UV light source is disposed within the warming tube to provide a first optical lure. A control circuit controls the duty cycle, which is greater than 0% and less than 100%, of the UV light source while the voltage source is powering the elimination zone of the inner grid and the outer grid to keep the thermal lure within a predetermined temperature range.

A bug zapper includes a housing assembly, a bug killing assembly, an LED circuit board, and a collection box. The housing assembly includes a main housing and a base. The main housing defines an accommodating space therein. Through holes communicated with the accommodating space are defined on the main housing. The base is annularly disposed and defines a central through hole and is connected to a bottom portion of the main housing. The base defines an inner side surface facing the central through hole. The bug killing assembly is disposed in the accommodating space. The LED circuit board is disposed on the base. The collection box is detachably mounted on the inner side surface of the base. The collection box defines a collection cavity disposed below the bug killing assembly. The bug zapper is able to illuminate while killing bugs.

Illustrative embodiments of integrated pest management (IPM) systems and electronic insect monitoring devices (EIMDs) are disclosed. In some embodiments, the EIMDs may each comprise a lure for attracting at least one target insect species, one or more sensors configured to generate one or more output signals in response to an individual insect approaching the lure, and an electronic controller configured to count a number of individual insects approaching the lure. In some embodiments, the IPM system may comprise a plurality of EIMDs configured to communicate over a wireless network shared by the plurality of EIMDs.

A method for the management of a soil pest or pathogen is disclosed and which 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 invention provides an electric shock insecticidal device reducing noise and light pollution emitted to an outside. The electric shock insecticidal device converts output voltage and output current supplied to a grid electrode into AC voltage and AC current or into DC voltage and DC current selectively; controls levels of the converted output voltage and current; adjusts an amount of light of the ultraviolet lamp emitted to an outside by using a light blocking layer or an adjusting unit adjusting illumination of an ultraviolet lamp; and easily separates the grid electrode having high voltage from a body unit to remove electrocuted flying insects from the grid electrode.

The present disclosure discloses an LED tube of a mosquito killer lamp and a mosquito killer lamp. The LED tube includes a lamp panel. The lamp panel is provided with several LEDs; the LEDs adopt LEDs with a wavelength of 365 to 380 nm and LEDs with a wavelength of 380 to 400 nm . . . . The LED tube further includes a scattering structure and a transparent tube body. The present disclosure also provides a mosquito killer lamp, which includes a power supplying module. The power supplying module configured to output a power supplying signal. A boost module electrically connected to the power supplying module and configured to receive the power supplying signal and output a boost driving signal. A mosquito killer unit is electrically connected to the boost module and a first light-emitting unit electrically connected to the power supplying module.