A Honeybee Swarm Trap to provide an inexpensive but sturdy bee box for keeping bees that is flexible in its application. To propagate beehives a beekeeper commonly uses a swarm catcher. These swarm catchers are placed near existing beehives, typically those naturally occurring, a swarm trap may be placed near the location of original beehive. Scout bees can visit the swarm trap and assess the trap for a swarm or propagated swarm to take up residence. Once the honeybee swarm take up residence in the swarm trap, the beekeeper can move the swarm to another location to house the honeybee colony.

Certain aspects of the present disclosure provide an insect trap for trapping insects, the insect trap comprising one or more serviceable parts, the insect trap being movable between a first configuration for trapping insects, and a second configuration for servicing of the one or more serviceable parts. The insect trap is arranged so that the position of the one or more serviceable parts in the first configuration differs from the position of the one or more serviceable parts in the second configuration.

Certain aspects of the present disclosure provide an insect trap for trapping insects, the insect trap comprising one or more serviceable parts, the insect trap being movable between a first configuration for trapping insects, and a second configuration for servicing of the one or more serviceable parts. The insect trap is arranged so that the position of the one or more serviceable parts in the first configuration differs from the position of the one or more serviceable parts in the second configuration.

A flying insect light trap monitoring device and related methods and systems. The flying insect light trap monitoring device includes a housing, camera, controller, and communications module. The housing includes a mounting structure configured to couple with a flying insect light trap. The camera generally includes a wide angle lens. The camera and wide angle lens are secured to the housing and take a digital photograph image of a glue board in the flying insect light trap. The controller, including a processor and a memory, is secured within the housing and is communicatively coupled to the camera. The controller receives the digital photograph image. The communications module is operatively coupled with the controller and sends data packets, including the digital photograph image, to a remote server. Further, an image processing engine that processes the image and generates an insect count can be included.

A trap for certain insect pests may be configured to be particularly suitable for bedbugs and take the form of a foldable pitfall bedbug trap. The pitfall trap walls extend vertically upwardly at an angle and are sufficiently rough to permit bedbugs to climb to an upper edge of the trap, whereas the inner surfaces of the pitfall trap walls have been treated with a smooth material, such as being laminated, causing bedbugs at the upper edge to fall upon initiating contact with the inner pitfall walls and their smooth characteristics. The resultant foldable pitfall bedbug trap is relatively inexpensive to produce and easily user-deployable.

A water movement system and method configured to eradicate and/or control mosquito or insect populations that lay eggs in treated, stagnant water environments. The system is comprised of a water pump configured to function in cooperation with an underwater insect attractant device. The insect attractant device is suitably constructed to generate carbon dioxide for attracting insects to a water extermination zone or trap. In one embodiment, the underwater insect attractant device contains organisms such as mycelia for generating the carbon dioxide. Insects are attracted by the carbon dioxide generation device to reproduce in the water extermination zone, using the treated water to lay eggs, and grow larvae and pupae for the subject insects. A solar-powered water pump device is configured to direct the flow of water from the water extermination zone toward filters of the water pump device to trap and kill insect progeny including eggs, larvae, and pupae.

A water movement system and method configured to eradicate and/or control mosquito or insect populations that lay eggs in treated, stagnant water environments. The system is comprised of a water pump configured to function in cooperation with an underwater insect attractant device. The insect attractant device is suitably constructed to generate carbon dioxide for attracting insects to a water extermination zone or trap. In one embodiment, the underwater insect attractant device contains organisms such as mycelia for generating the carbon dioxide. Insects are attracted by the carbon dioxide generation device to reproduce in the water extermination zone, using the treated water to lay eggs, and grow larvae and pupae for the subject insects. A solar-powered water pump device is configured to direct the flow of water from the water extermination zone toward filters of the water pump device to trap and kill insect progeny including eggs, larvae, and pupae.

It is important to trap and identify mosquitos to ensure the safety of the population where mosquitos gather. The classification of a type of mosquito is typically accomplished by a unique wingbeat signature that is characteristic of different types of mosquitos. One of the goals of the trap is to quickly identify the mosquito and then quickly release the mosquito. This application will allow the user to obtain an approximate population so that the appropriate type and amount of insecticide can be applied to control the population to insure the health of the human and animal population while at the same time minimizing danger to the environment or surrounding ecosystem.

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.

Disclosed is an insect trap, which includes a trap assembly and a trapping box provided with an opening in the upper end thereof, wherein a killing component is arranged in the trapping box; the trapping box is arranged below the trap assembly, and the bottom of the trapping box is connected to the trap assembly; and a space for insects to pass through is maintained between the trap assembly and the upper edge of the trapping box. The insect trap can lure insects moving around the insect trap into the trapping box, and can effectively prevent insects from climbing onto the trap assembly.