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).

A bug trap apparatus suited for trapping and killing lanternflies is presented. More specifically, the present invention traps and kills lanternflies, specifically emplacing the present invention in nesting areas, feeding areas, or any other areas where lanternflies congregate. The bug trap apparatus comprises an enclosure, a mounting frame, and at least one capturing element. The at least one capturing element each comprises a trap body, a trap entrance, and a trap reservoir. The at least one capturing element is distributed about the mounting frame. The mounting frame is positioned within the enclosure. The trap entrance and the trap base are positioned terminally opposite to each other along the trap body. The trap reservoir is positioned within the trap body. The trap entrance traverses within the trap reservoir.

An insect trapping device for trapping insects and shielding them from view includes a housing, which defines an interior space. The housing has a top, which is open. A panel is selectively insertable through the top into the interior space. A fastener engaged to a back of the housing can engage a substrate so that the housing is mounted thereto. An adhesive compound and an attractant are positioned upon a surface of the panel. The attractant attracts insects into the interior space and the adhesive compound traps insects landing upon the panel.

A trap for flying insects includes a housing having a plurality of housing apertures and a tank located interior of the housing. The tank has an insect killing agent within an interior of the tank and a plurality of tank apertures adjacent an upper portion of the tank in communication with the interior of the tank for access of flying insects into the interior of the tank. The tank apertures are located proximate the housing apertures to provide a path for flying insects to travel from locations exterior of the housing to the tank apertures and into the tank. The trap also includes an insect attractive illumination located proximate the tank apertures.

The present invention relates to an ovitrap (10) and novel method of controlling mosquito populations comprising the use of light (20) to create a photo stimulus, causing mosquito larvae (102) to move from a location (Va), where gravid mosquitoes have deposited their eggs, in a direction away from the light, to a location (Vb). where they are trapped and killed. The ovitrap utilises this behaviour to more effectively capture and kill larvae. The ovitrap comprises a container (12), a cover (14), and a means (16) for dividing the container (12) into two regions (101; 102), which in use are filled with water, and which communicate via an opening (26) such that a volume (Vb) below the means (16) defines a larvae (102) trapping region, and a volume (Va) above the means (16) defines an egg (101) receiving region. A light source (20) is mounted above the container (12) and is positioned to direct light downwards at a water surface (92), such that when the light is turned on, it creates a photo stimulus, and the larvae (102) respond by moving in a direction away from the light, from the volume above (Va) into the volume below (Vb) via opening (26). A gating mechanism (18) opens and closes the opening (26) when the light is respectively turned on and off, such that the larvae are trapped in the volume below

An insect trap includes a combination of one or more components used to classify the insect according to a genus and species. The trap includes an imaging device, a digital microphone, and passive infrared sensors at the entrance of the trap to sense wing-beat frequencies and size of the insect (to identify entry of a mosquito). A lamb-skin membrane, filled with an insect attractant such as carbon dioxide mixed with gas air inside, mimics human skin so that the insect can rest on the membrane and even pierce the membrane as if a blood meal is available. An imaging device such as a passive infrared sensor or a camera gathers image data of the insect. The insect may be a mosquito.

A system and method for a free-standing device that uses a pool of stagnant water to attract female mosquitoes to deposit their eggs in a container whereby the device automatically self-flushes periodically the eggs from the container through a valve into its self-contained reservoir which then replenishes the container after the eggs have been discarded.

The present disclosure relates generally to an arthropod trapping device, more particularly, to a compact and portable trapping device comprising a housing and an insert.

The invention refers to a Carousel-Type Insect Trap, in order to control or monitor insects through different types of bait mounted on a carousel, thus facilitating the handling of baits used in traps for the monitoring of insects, which is of great economic importance, with uniformity and consistency, thus establishing a world-wide monitoring system for plague control, which will allow us to compare capture results with no variables in the handling and placement of baits and retention substrates inside the traps.

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.