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.

A base assembly has an upward plate, a downward plate, a side wall, a front, a back, and laterally spaced sides. A drive assembly has drive wheels extending downwardly from the downward plate, a caster wheel, and proximity sensors. A vacuum assembly has a vacuum slit in the downward plate between the lateral sides and a vacuum-generating source capable of pulling a vacuum through the vacuum slit. A tower assembly is adapted to attract and kill insects while the base assembly and the tower assembly are being optionally driven by the drive assembly and the vacuum assembly is vacuuming up insects.

An insect trap includes an exothermic body, and a layered body. The exothermic body is configured to include exothermic powder enclosed in an inner bag that is air permeable; the exothermic powder contains iron powder that releases heat when oxidized. The layered body is configured with layers of plate-like elements and includes gaps as a pathway of entry for an insect pest. A housing space to house the exothermic body is arranged inside the layered body. The layered body and the inner bag are made of a biodegradable raw material.

A drone with a high-voltage trap seeks, identifies, pursues and destroys flying insects within a patrolling area. During its passive attracting mode, the drone lands on a designated ground site and attracts insects with light, sound, and scents. Once insects are lured, the high voltage screens trap will immediately electrocute targeted insects. In its active offensive mode, the drone hovers closer to insect nests using its high-velocity propellers, producing strong downdraft jet streams to disturb the nest and force insects, such as mosquitoes and the like, to evacuate their nest. Once insects are airborne, the drone pursues fleeing insects from below or behind, making use of its propellers and vacuuming the fleeing insects. Slow flying insects that come in contact with the high-voltage electrified screens are immediately electrocuted. Insects that are vacuumed into the fast-spinning propellers blades are knocked down and killed. A rectified charging pad recharges the drone batteries.

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.

In an embodiment, as insect trap is disclosed including: a trap portion including a frame and a membrane having an adhesive surface, wherein the membrane is at least partially contained within the frame and is configured to adhere to an insect; and a base portion including a lighting element and a housing portion, wherein the housing portion is configured to receive and retain the trap portion when engaged therewith.

The disclosure provides for a bed bug monitor that allows for detection and capture of bed bugs, and uses thereof.

Devices are embodied that eliminate flying insect pests in quite a different way than others devices have used in the past. If insects are attracted to a surface large enough to accommodate their numbers and allowed to gather for a time without being restrained or bothered, it is possible by way of these embodiments at a single location to eliminate insects in very large number on a daily basis. Depending on a device's size and embodiment, from several hundred to far in excess of one hundred thousand flying insects per twenty-four hour period can be eliminated.

The current subject matter relates to controlling insects and includes a trap that can vary operation based at least on a target insect. For example, different insects are attracted to and/or repelled by different things, such as gases, orders, lights, and sounds. In general, things that attract a given insect are referred to as attractants and things that repel a given insect are referred to as repellents. By varying the operation of the trap, different attractants and repellants can be used to attract and/or repel specific insects. In addition, these attractants and repellants and/or characteristics thereof can these be varied dynamically based on, for example, time of day, proximity of individuals to the trap, proximity of insects to the trap, geographic location, and the like. Related apparatus, system, articles, and techniques are also described.