Disclosed are devices for eliminating airborne and crawling insect pests including a base carrying a membrane ring and insect feeding pool; a stem mounted to the base having a lower portion that covers the membrane ring; a reservoir positioned atop the stem, the reservoir adapted to contain liquid bait; stress duct openings disposed in the stem for metering flow of the liquid bait from the reservoir to the insect feeding pool; and a cover positioned atop the reservoir and extending radially outward therefrom to span and cover the base, the cover housing at least one of a metered bioattractant dispenser, a metered biopathogen dispenser, a light source, and a solar panel. Also disclosed are pest control device cover assemblies configured for attachment to existing pest control device(s) that allow for enhanced elimination airborne and crawling insect pests.

Disclosed are devices for eliminating airborne and crawling insect pests including a base carrying a membrane ring and insect feeding pool; a stem mounted to the base having a lower portion that covers the membrane ring; a reservoir positioned atop the stem, the reservoir adapted to contain liquid bait; stress duct openings disposed in the stem for metering flow of the liquid bait from the reservoir to the insect feeding pool; and a cover positioned atop the reservoir and extending radially outward therefrom to span and cover the base, the cover housing at least one of a metered bioattractant dispenser, a metered biopathogen dispenser, a light source, and a solar panel. Also disclosed are pest control device cover assemblies configured for attachment to existing pest control device(s) that allow for enhanced elimination airborne and crawling insect pests.

The invention relates to methods of trapping a pest, said method comprising providing ferromagnetic particles for ingestion by the pest, and trapping the pest using one or more magnets, wherein a trapped pest has ingested and internally accumulated an amount of the ferromagnetic particles sufficient to permit immobilization of the pest using said one or more magnets. Devices for use with the methods of the instant invention are also disclosed.

A remote insect monitor and associated method include a container configured to allow an insect attractant within the container to escape into ambient air proximate a landing area. At least one detection sensor generating sensor data of insects proximate the landing area, and a control module has a processor and a memory storing machine readable instructions executable by the processor to process the sensor data and count insects proximate the landing area. The remote insect monitor and associated method may also include an analyzer for analyzing an insect of interest to determine whether the insect carries a disease, wherein the control module sends an indication of whether the insect carries the disease to the remote server.

A remote insect monitor and associated method include a container configured to allow an insect attractant within the container to escape into ambient air proximate a landing area. At least one detection sensor generating sensor data of insects proximate the landing area, and a control module has a processor and a memory storing machine readable instructions executable by the processor to process the sensor data and count insects proximate the landing area. The remote insect monitor and associated method may also include an analyzer for analyzing an insect of interest to determine whether the insect carries a disease, wherein the control module sends an indication of whether the insect carries the disease to the remote server.

Disclosed herein is an insect trapping device comprising an inner passageway structure defining an inner passageway which, when in an upright orientation, extends from an insect entry zone to an insect delivery zone, the inner passageway structure bordered by at least a pair of opposed insect-facing traction-reducing boundary surface regions to cause an insect to progress toward the insect delivery zone under gravity, with each boundary surface region including at least one of at least a pair of electrode surface regions, wherein each electrode surface region is configured for operative coupling with an electrode power supply to deliver electrical power thereto, the electrode surface regions configured to form an electrocution zone therebetween, with a designated spacing which is configured to initiate electrocution of an instance of the insect descending through the electrocution zone.

A light tube apparatus includes a tubular housing, a first light source, a second light source, a driver and a controller. The tubular housing having a first light passing window and a second light passing window. The first light source is for emitting a white light from the first light passing window in an illuminating mode. The second light source is for emitting an ultraviolet light from the second light passing window in a sanitizing mode. The driver is for converting an external power source to a first driving current to the first light source and a second driving current to the second light source. The controller is for determining when to enter the sanitizing mode or the illuminating mode based on a stored criterion.

A light tube apparatus includes a tubular housing, a first light source, a second light source, a driver and a controller. The tubular housing having a first light passing window and a second light passing window. The first light source is for emitting a white light from the first light passing window in an illuminating mode. The second light source is for emitting an ultraviolet light from the second light passing window in a sanitizing mode. The driver is for converting an external power source to a first driving current to the first light source and a second driving current to the second light source. The controller is for determining when to enter the sanitizing mode or the illuminating mode based on a stored criterion.

The present disclosure describes an apparatus, system, and method for trapping and exterminating arthropods, particularly red mites. The apparatus includes an opaque housing and a heat strip configured to have separate temperature zones. The method includes warming the heat strip to lure the mites into the trap, heating outer heat strip segments to drive the mites toward the center of the trap, and then raising the entire heat strip to a temperature sufficient to exterminate the mites. The system includes placing one or more of the traps in animal hold structures, including nesting boxes in poultry houses.

The present disclosure describes an apparatus, system, and method for trapping and exterminating arthropods, particularly red mites. The apparatus includes an opaque housing and a heat strip configured to have separate temperature zones. The method includes warming the heat strip to lure the mites into the trap, heating outer heat strip segments to drive the mites toward the center of the trap, and then raising the entire heat strip to a temperature sufficient to exterminate the mites. The system includes placing one or more of the traps in animal hold structures, including nesting boxes in poultry houses.