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.

An insect catching device may include at least two insect capture surfaces, a first surface including a first color, and a second surface including a second, lighter color relative to the first color of the first surface. The second color of the second surface may highlight the presence of insects captured thereon facilitating at least one of ease of counting and ease of identification of captured insects. The insect catching device may also include a line of weakening disposed between the first surface and the second surface. The line of weakening may include at least one perforation. The second surface may be detachable from the first surface along the line of weakening. The first color may be configured to decrease visibility of captured insects on the first surface observable by a viewer through an insect trap cover.

An insect catching device may include at least two insect capture surfaces, a first surface including a first color, and a second surface including a second, lighter color relative to the first color of the first surface. The second color of the second surface may highlight the presence of insects captured thereon facilitating at least one of ease of counting and ease of identification of captured insects. The insect catching device may also include a line of weakening disposed between the first surface and the second surface. The line of weakening may include at least one perforation. The second surface may be detachable from the first surface along the line of weakening. The first color may be configured to decrease visibility of captured insects on the first surface observable by a viewer through an insect trap cover.

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.

An apparatus and associated method of use is described for attracting and trapping mosquitos and other biting insects using a vapor cloud of atomized carbon dioxide (CO2) gas as an insect attractant. The apparatus also employs other insect attractants as adjunct attractants to the vapor cloud of atomized carbon dioxide (CO2) gas. In an embodiment, atomized water vapor is generated to be combined with 2 chemical ingredients to create the atomized vapor cloud of carbon dioxide (CO.sub.2) which is dispersed into the interior of the device to maintain a level above 2000 parts per million (ppm).

An insect trap is adapted to attract and collect insects with UV light. The insect trap includes: a main body; an insect filter disposed on the main body and allowing insects to pass therethrough; a motor disposed below the insect filter; a suction fan disposed under the motor and rotated by the motor; a plate-shaped UV LED installation unit disposed above the insect filter and provided with a UV LED module; a buttress supporting the UV LED installation unit above the main body while separating the UV LED installation unit above the main body so as to allow insects to be suctioned into a space between the main body and the UV LED installation unit; and an insect collector disposed under the main body and collecting insects.

An insect trap is adapted to attract and collect insects with UV light. The insect trap includes: a main body; an insect filter disposed on the main body and allowing insects to pass therethrough; a motor disposed below the insect filter; a suction fan disposed under the motor and rotated by the motor; a plate-shaped UV LED installation unit disposed above the insect filter and provided with a UV LED module; a buttress supporting the UV LED installation unit above the main body while separating the UV LED installation unit above the main body so as to allow insects to be suctioned into a space between the main body and the UV LED installation unit; and an insect collector disposed under the main body and collecting insects.

An insect trapping apparatus includes a source of carbon dioxide for emission into the atmosphere, a chamber housing a catalyst to ignite the source of carbon, a cartridge containing a chemical attractant, the emission containing the chemical attractant, a trap for holding captured insects, and a vacuum capable of drawing the insects into the trap through a collar, the collar including a light-emitting diode (LED) fixture.

An insect trapping apparatus includes a source of carbon dioxide for emission into the atmosphere, a chamber housing a catalyst to ignite the source of carbon, a cartridge containing a chemical attractant, the emission containing the chemical attractant, a trap for holding captured insects, and a vacuum capable of drawing the insects into the trap through a collar, the collar including a light-emitting diode (LED) fixture.