The present document relates to an insect trap using an ultraviolet light-emitting diode (UV LED) lamp, and more particularly, to an insect trap using, in place of a conventional UV light source lamp, a UV LED lamp that significantly increases the insect trapping efficiency. One example implementation of the insect trap includes: a UV LED lamp disposed in an air inlet portion of the duct, and including a printed circuit board (PCB) that has a UV LED chip mounted thereon; an installing portion for installing the UV LED lamp on; and a trapping portion provided near the installing portion.

A vortex insect trap includes an insect trapping container, a fan and an insect-killing device. The insect trapping container internally defines an air flowing space, in which the insect-killing device is disposed. The air flowing space is enclosed in at least one flow-guiding wall surface and communicable with external environment via an air suck-in port and an air exit port of the vortex insect trap. The fan is mounted to the air exit port for sucking in external air via the air suck-in port and discharging air inside the air flowing space from the insect trapping container via the air exit port. When the fan operates, air sucked into the air flowing space flows along the flow-guiding wall surface to form a spiral air flow that flows toward a bottom of the air flowing space while carries insects sucked into the air flowing space to the insect-killing device.

A mosquito trap device includes a housing having an air inlet and an air outlet. A wind channel is formed between the air inlet and the air outlet. An ultraviolet light module is mounted in the housing and is located adjacent to the air inlet. A wind module is mounted in the wind channel of the housing. A mosquito detaining device includes a tube and a net. The tube is mounted in the wind channel and is coupled to the wind module. The net is mounted to and covers an end of the tube adjacent to the air inlet. A controller is electrically connected to the ultraviolet light module and the wind module. The controller is configured to output a pulse width modulation signal to the ultraviolet light module. The pulse width modulation signal has a frequency of 25-512 Hz.

A mosquito trap device includes a housing having an air inlet and an air outlet. A wind channel is formed between the air inlet and the air outlet. An ultraviolet light module is mounted in the housing and is located adjacent to the air inlet. A wind module is mounted in the wind channel of the housing. A mosquito detaining device includes a tube and a net. The tube is mounted in the wind channel and is coupled to the wind module. The net is mounted to and covers an end of the tube adjacent to the air inlet. A controller is electrically connected to the ultraviolet light module and the wind module. The controller is configured to output a pulse width modulation signal to the ultraviolet light module. The pulse width modulation signal has a frequency of 25-512 Hz.

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.

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.

Provided is an insect monitoring device including a tube. An attractor is positioned at an entrance to the tube, and an imaging device is configured for producing data associated with a monitored insect, wherein the data being usable in machine learning.

A light, in particular, a light having a fly killing function that can be used for lighting and killing flies including at least one LED chip, a fly storage means, a negative pressure fan, a fan hanger, a ventilation net, a power supply; wherein the fly storage means is connected to the fan hanger, the LED chip is secured to an lower end of the fly storage means, the fly storage means including an air inlet and a fly storage groove, the negative pressure fan is mounted onto the fan hanger above the fly storage means, a gap is provided between the blades of the negative pressure fan and an upper end of the fly storage means to allow flies to go through; the ventilation net includes a plurality of ventilation holes having a size that is able to stop flies from passing therethrough, and the ventilation net is provided circumferentially between the outside wall of the fan hanger and the outside wall of the fly storage means, and the fan hanger, the ventilation net and the fly storage means form a substantially closed space except the ventilation holes and the air inlet.

A light, in particular, a light having a fly killing function that can be used for lighting and killing flies including at least one LED chip, a fly storage means, a negative pressure fan, a fan hanger, a ventilation net, a power supply; wherein the fly storage means is connected to the fan hanger, the LED chip is secured to an lower end of the fly storage means, the fly storage means including an air inlet and a fly storage groove, the negative pressure fan is mounted onto the fan hanger above the fly storage means, a gap is provided between the blades of the negative pressure fan and an upper end of the fly storage means to allow flies to go through; the ventilation net includes a plurality of ventilation holes having a size that is able to stop flies from passing therethrough, and the ventilation net is provided circumferentially between the outside wall of the fan hanger and the outside wall of the fly storage means, and the fan hanger, the ventilation net and the fly storage means form a substantially closed space except the ventilation holes and the air inlet.

A trap for catching insects may include a back housing, a plurality of lights and a cover. The trap may be adapted for ease of servicing and jet cleaning via a plurality of shields. Each of the plurality of shields may sealably protect, from water ingress, the plurality of lights at a position where the plurality of lights connect to a plurality of electrical fittings.