Improved devices for the capture, detection, or quantification of insect vectors such as gravid female insects, are provided. The devices include surface coloration, design, and dimension that improved their ability to attract and/or capture target insect vectors. The traps are used in process for detection or control of insect vectors in indoor and outdoor environments.

One embodiment provides a system, including: a first end that screws into a light bulb socket; an internal light source; an electric insect control mechanism disposed around and proximate to the internal light source; and a visible light source disposed at an opposite end with respect to the first end. Other embodiments are described and claimed.

One embodiment provides a system, including: a first end that screws into a light bulb socket; an internal light source; an electric insect control mechanism disposed around and proximate to the internal light source; and a visible light source disposed at an opposite end with respect to the first end. Other embodiments are described and claimed.

An inflatable flying insect trap that serves also serves as a light source. The insect trap is formed of an inflatable globe that, once inflated, forms a curved wall upon which a glue trap may be mounted. One or more LEDs positioned within the cavity of the globe emits light that passes through the globe and through the attached glue trap. Insects attracted to the light will become adhered to the external surface of the glue trap.

The present invention consists of a collapsible trap for insects, particularly male and female Aedes aegypti mosquitoes, the trap preferably being made of card and designed for use in a domestic or commercial environment. Specifically, the present invention discloses a foldable trap for insects, particularly male and female Aedes aegypti mosquitoes, the trap being formed by a hollow, prismatic main body which comprises an upper cover and a lower cover. The hollow, prismatic main body also comprises a translucent window in one of the sides, the internal surface of which translucent window is impregnated with an adhesive for insects. An attractive mosquito bait is located inside the hollow main body. The mosquitoes, attracted by the bait, enter the trap through at least one curved interior conduit which is located inside the hollow main body and has an entrance in the upper cover and an exit inside the trap.

The device for trapping insects comprises an adhesive surface (4) for trapping insects; and a light source (2) for attracting the insects to said adhesive surface (4), which also comprises a chamber (1) provided with one or several holes (3), said light source (2) being placed inside said chamber (1) and said adhesive surface (4) is placed inside said chamber (1) or forms one of the inner walls of said chamber (1).

The presence of the chamber magnifies the light emitted by a light source and since the adhesive surface is located inside the chamber, the trapped insects remain concealed.

An insect elimination device has an outer grid with an inner grid disposed within the outer grid. A voltage source powers the inner grid, the outer grid or both. A warming tube is disposed within the inner grid and provides a thermal lure. A UV light source is disposed within the warming tube to provide a first optical lure. A control circuit controls the duty cycle, which is greater than 0% and less than 100%, of the UV light source while the voltage source is powering the elimination zone of the inner grid and the outer grid to keep the thermal lure within a predetermined temperature range.

An insect elimination device has an outer grid with an inner grid disposed within the outer grid. A voltage source powers the inner grid, the outer grid or both. A warming tube is disposed within the inner grid and provides a thermal lure. A UV light source is disposed within the warming tube to provide a first optical lure. A control circuit controls the duty cycle, which is greater than 0% and less than 100%, of the UV light source while the voltage source is powering the elimination zone of the inner grid and the outer grid to keep the thermal lure within a predetermined temperature range.

Insect capture is improved by providing a glue board having an adhesive coating on its front surface and forming a pattern of insect attractant. UV light on that front surface. That pattern includes areas of bright UV light generated by light-emitting diodes behind and visible through the glue board by flying insect, dimmer areas of UV light that bounces off other portions of the device onto the glue board, and areas of shadow on the glue board where no or little UV light is present.

Insect capture is improved by providing a glue board having an adhesive coating on its front surface and forming a pattern of insect attractant. UV light on that front surface. That pattern includes areas of bright UV light generated by light-emitting diodes behind and visible through the glue board by flying insect, dimmer areas of UV light that bounces off other portions of the device onto the glue board, and areas of shadow on the glue board where no or little UV light is present.