An insect capture device is provided. The insect capture device has a housing having a cover with a plurality of openings through which insects enter the housing. A light assembly is mounted to the housing and adapted to attract the insects. A bait container is mounted on the housing to hold insect bait. A fan is disposed within the housing oriented to pull insects through the cover and into the housing. A removable tray cooperates with the housing. The tray configured to hold an adhesive pad for capturing insects that entered the housing.

Problems associated with the use of fluorescent tubes in insect traps are resolved by providing a replacement lamp array employing multiple sets of light emitting diodes that each emit light at different specific wavelengths and are positioned within a one or more translucent sleeves having a surface coated with an environmentally safe light diffusion material creating a pattern comprising areas of more intense light dominated by the light cast by a single LED separated by areas of less intense light.

Problems associated with the use of fluorescent tubes in insect traps are resolved by providing a replacement lamp array employing multiple sets of light emitting diodes that each emit light at different specific wavelengths and are positioned within a one or more translucent sleeves having a surface coated with an environmentally safe light diffusion material creating a pattern comprising areas of more intense light dominated by the light cast by a single LED separated by areas of less intense light.

A flying insect trap formed of an ingress chamber having a light source to attract flying insects and a fan to create an air stream to direct insects into a capture chamber. The trap has an upper illumination chamber to project light upward in order to enhance the trap's attractiveness to flying insects. The upper illumination chamber is formed of a plate containing light emitting devices that face upward and project light through a translucent cover.

A flying insect trap formed of an ingress chamber having a light source to attract flying insects and a fan to create an air stream to direct insects into a capture chamber. The trap has an upper illumination chamber to project light upward in order to enhance the trap's attractiveness to flying insects. The upper illumination chamber is formed of a plate containing light emitting devices that face upward and project light through a translucent cover.

An insect suppression device, and further relates to a self-moving device, a charging station, and an automatic working system that are mounted with the insect suppression device are provided. The self-moving device moves in a working area, performs a working task, and includes: a body and a movement module that is mounted on the body and drives the self-moving device to move. The self-moving device includes: an insect suppression device, mounted to the body, and a control module, controlling the movement module to move and controlling the insect suppression device to work. The beneficial effects of the present invention are as follows: The self-moving device can move autonomously in the working area and perform an insect suppression task, and has a wide coverage area, flexible work, and high efficiency, so that automatic control can be implemented, thereby freeing a user from the harassment of insects.

An insect trap useful for trapping flying insects, the insect trap comprising an upper housing including at least one horizontal row of light emitting diodes extending across an outer surface of a curved front wall such that light from each of the light emitting diodes is projected outwardly from the upper housing at a different angle than adjacent light emitting diodes in the horizontal row of light emitting diodes, a base housing including an opening through which insects can enter an interior of the base housing, and an insect trapping element facing the opening in the base housing.

An insect trap useful for trapping flying insects, the insect trap comprising an upper housing including at least one horizontal row of light emitting diodes extending across an outer surface of a curved front wall such that light from each of the light emitting diodes is projected outwardly from the upper housing at a different angle than adjacent light emitting diodes in the horizontal row of light emitting diodes, a base housing including an opening through which insects can enter an interior of the base housing, and an insect trapping element facing the opening in the base housing.

Systems, devices, and methods for using insect traps with combinations of dual multi-colored lights combining blue/green LED (light emitting diodes) with UV (ultraviolet) LEDs (light emitting diodes) for attracting insects to the lights and capturing the insects. The blue/green LED can emit at a wavelength of approximately 450 nm to approximately 550 nm in an approximately 180 degrees spread therefrom, and each side UV LED can emit at a wavelength of approximately 365 nm in an approximately 180 degrees spread therefrom. The combinations of multi-color lights can be mounted on one side of a module/fixture, and/or be mounted on opposite side faces of a module fixture. The combinations can use one centrally located blue/green LED with at least one right UV LED to a right side of the centrally located blue/green LED, and at least one left UV LED to a left side of the centrally located blue/green LED. Embodiments can include use on a sticky paper/card, in a housing with fan, and collection tray, and in an electrical gride of wires having a collection tray and sand mesh bag with an approximately 340 micron mesh screen. Embodiments include a plurality of UV (ultraviolet) LEDs (light emitting diodes) greater than the plurality of blue-green LEDs (light emitting diodes).

Systems, devices, and methods for using insect traps with combinations of dual multi-colored lights combining blue/green LED (light emitting diodes) with UV (ultraviolet) LEDs (light emitting diodes) for attracting insects to the lights and capturing the insects. The blue/green LED can emit at a wavelength of approximately 450 nm to approximately 550 nm in an approximately 180 degrees spread therefrom, and each side UV LED can emit at a wavelength of approximately 365 nm in an approximately 180 degrees spread therefrom. The combinations of multi-color lights can be mounted on one side of a module/fixture, and/or be mounted on opposite side faces of a module fixture. The combinations can use one centrally located blue/green LED with at least one right UV LED to a right side of the centrally located blue/green LED, and at least one left UV LED to a left side of the centrally located blue/green LED. Embodiments can include use on a sticky paper/card, in a housing with fan, and collection tray, and in an electrical gride of wires having a collection tray and sand mesh bag with an approximately 340 micron mesh screen. Embodiments include a plurality of UV (ultraviolet) LEDs (light emitting diodes) greater than the plurality of blue-green LEDs (light emitting diodes).