Disclosed are devices for eliminating airborne and crawling insect pests including a base carrying a membrane ring and insect feeding pool; a stem mounted to the base having a lower portion that covers the membrane ring; a reservoir positioned atop the stem, the reservoir adapted to contain liquid bait; stress duct openings disposed in the stem for metering flow of the liquid bait from the reservoir to the insect feeding pool; and a cover positioned atop the reservoir and extending radially outward therefrom to span and cover the base, the cover housing at least one of a metered bioattractant dispenser, a metered biopathogen dispenser, a light source, and a solar panel. Also disclosed are pest control device cover assemblies configured for attachment to existing pest control device(s) that allow for enhanced elimination airborne and crawling insect pests.

The present disclosure 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. The insect trap according to the present disclosure includes: a duct including a suction fan therein; a UV LED lamp disposed in the air inlet portion of the duct and comprising a printed circuit board (PCB) that has a UV LED chip mounted thereon; and a trapping portion provided in the air outlet portion of the duct.

The present disclosure 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. The insect trap according to the present disclosure includes: a duct including a suction fan therein; a UV LED lamp disposed in the air inlet portion of the duct and comprising a printed circuit board (PCB) that has a UV LED chip mounted thereon; and a trapping portion provided in the air outlet portion of the duct.

The present disclosure 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. The insect trap according to the present disclosure 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 disclosure 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. The insect trap according to the present disclosure 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.

An insect trap comprises a housing defining an insect intake opening. A receptacle is removably attached to a bottom of the housing and is in communication with the intake opening. A rotating fan assembly is arranged within the housing and is adapted to draw air in through the intake opening in a direction toward the receptacle. An insect screen is removably attached over the intake opening and defines a plurality of first openings sized to prevent insects of a predetermined average size from entering the intake opening.

An aromatherapy mosquito killer includes a shell with a light chamber, a fan chamber and a mosquito killing chamber provided therein, a light module arranged in the light chamber for emitting light outwardly, a fan arranged in the fan chamber, and an aromatherapy box arranged in the mosquito killing chamber for collecting mosquitoes and storing aromatherapy. Airflow holes are defined in top and bottom sides of a chamber wall of the fan chamber. Ventilation holes are defined in a side wall and a top wall of the aromatherapy box. Air inlets and air outlets are defined in the shell. The air inlets, the airflow holes and the ventilation holes in the top wall of the aromatherapy box cooperatively form a mosquito-killing air duct for sucking in mosquitoes; and the ventilation holes in the side wall of the aromatherapy box cooperatively form an exhaust air duct.

An aromatherapy mosquito killer includes a shell with a light chamber, a fan chamber and a mosquito killing chamber provided therein, a light module arranged in the light chamber for emitting light outwardly, a fan arranged in the fan chamber, and an aromatherapy box arranged in the mosquito killing chamber for collecting mosquitoes and storing aromatherapy. Airflow holes are defined in top and bottom sides of a chamber wall of the fan chamber. Ventilation holes are defined in a side wall and a top wall of the aromatherapy box. Air inlets and air outlets are defined in the shell. The air inlets, the airflow holes and the ventilation holes in the top wall of the aromatherapy box cooperatively form a mosquito-killing air duct for sucking in mosquitoes; and the ventilation holes in the side wall of the aromatherapy box cooperatively form an exhaust air duct.

An insect eliminating device includes a body including a top portion and a bottom portion provided below the top portion; a light portion mounted in the body and including: a UV light element mounted in an open space provided in the top portion; a flickering light portion mounted in the bottom portion; a central conduit providing fluid communication between the open space in the top portion and the bottom portion of the body; a fan, mounted in the bottom portion to direct air from the open space in the top portion, through the central conduit and into the lower portion; and a grid mounted at a bottom end of the central conduit including a plurality of openings sized to allow air and insects to pass downward into the bottom portion of the base and prevent insects from passing upwards into the central conduit.

An insect eliminating device includes a body including a top portion and a bottom portion provided below the top portion; a light portion mounted in the body and including: a UV light element mounted in an open space provided in the top portion; a flickering light portion mounted in the bottom portion; a central conduit providing fluid communication between the open space in the top portion and the bottom portion of the body; a fan, mounted in the bottom portion to direct air from the open space in the top portion, through the central conduit and into the lower portion; and a grid mounted at a bottom end of the central conduit including a plurality of openings sized to allow air and insects to pass downward into the bottom portion of the base and prevent insects from passing upwards into the central conduit.