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.

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 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.

An electronic flying insect trap apparatus having a housing topped by an aperture with sufficient openings as to allow flying insects to pass through it and side apertures of the apparatus and a bottom plate, the housing and bottom plate having sufficient openings as to allow air to pass therethrough and disseminate a scent. At least one light positioned below the top aperture. A truncated conical collar below the light. At least one fan positioned below the collar. A tray containing sticky adhesive disposed on the upper surface of a disposable sheet positioned below the fan. At least one motion detector is in communication with the fan.

An electronic flying insect trap apparatus having a housing topped by an aperture with sufficient openings as to allow flying insects to pass through it and side apertures of the apparatus and a bottom plate, the housing and bottom plate having sufficient openings as to allow air to pass therethrough and disseminate a scent. At least one light positioned below the top aperture. A truncated conical collar below the light. At least one fan positioned below the collar. A tray containing sticky adhesive disposed on the upper surface of a disposable sheet positioned below the fan. At least one motion detector is in communication with the fan.

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 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

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 monitoring system (ISM) and related e-commerce system are provided. The ISM includes an insect attracting light, an intake, an exhaust, an airflow conduit between intake and exhaust, an insect collecting mesh in the conduit, a fan for generating airflow in the airflow conduit, and one or more cameras pointed on the insect collecting mesh. The insect attracting light and the fan are activated such that insects are drawn into the intake and trapped against the insect collecting mesh. The images of the insect collecting mesh are processed and analyzed using a machine learning algorithm to recognize a type and number of insects. Recommendations are provided based on the analysis. In some aspects, the insect monitoring system is connected to electronic client devices over a communication network. The electronic devices are provided with an e-commerce application for sale of products and services responsive to the recommendations.