An insect trapping unit that is provided with an adhesive sheet that includes a fluorescent brightening agent and that can transmit ultraviolet rays, and with a reflective member that reflects ultraviolet rays that have been transmitted through the adhesive sheet. The adhesive sheet is provided with an adhesive surface and with a rear surface that is on the opposite side from the adhesive surface. The reflective member faces the rear surface of the adhesive sheet.

A system for sterilizing a physical space, such as a hotel room. The system generates and distributes heated air to the physical space to elevate the temperature of the space to a level sufficient to achieve a desired sterilization effect of eradicating insects and microoganisms. The system is portable and self-contained. The system includes a hydrogen fuel cell that generates electrical power. An electrical system conditions and stores the electrical power and supplies stored electrical power to the system components and peripherals. System components include a source of hydrogen, a heater, an air distributor, and a filter. Peripherals include a UV light source and an aerosol dispenser. The combination of heat, UV light and aerosol disinfectant effectively eradicates insects, microorganisms, allergens, and odors in the physical space.

A real-time counting insecticidal lamp includes a rainproof cover, a LED lamp body, an insect receiver, and a high-voltage grid; the rainproof cover is arranged above the lamp body, the insect receiver is arranged below the lamp body, and the high-voltage grid is arranged at the periphery of the lamp body; the high-voltage grid includes a high-voltage direct current power supply and N-1 wires, and the N-1 wires are arranged in parallel in each interval to form a circle, wherein, N is no less than 10; top ends of the wires are all connected to the power supply end of the power supply, but one of two adjacent wires is electrically connected to the positive end of the power supply while the other is electrically connected to the negative end; the real-time counting insecticidal lamp also includes a counting unit.

An aerial drone includes a pest sensor, an environmental sensor, a drone on-board computer, and a pest abatement mechanism. The pest sensor senses a pest based on emissions from the pest. The environmental sensor detects an environment of the pest. The drone on-board computer identifies a pest type of the pest based on the emission from the pest, and establishes a risk level posed by the presence of the pest based on the pest type and the environment of the pest. The pest abatement mechanism performs a pest abatement of the pest based on the pest type and the risk level posed by the presence of the pest.

An apparatus includes a base, a body coupled to the base and having slopped sidewalls, and imprinted glass marbles carried by the body. Each imprinted glass marble is configured to transmit terahertz frequencies from 300 GHz to 3 THz. The slopped sidewalls direct the transmitted terahertz frequencies above the body.

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.

This invention allows safe and easy capture, secure containment, visual examination and release or other disposition of small invertebrate specimens. It interfaces with a vacuum cleaner or other source of negative air pressure and is comprised of three main parts or segments: A collection segment used in capturing and containing insect specimens and the like, an attachment segment used in attaching the apparatus to a vacuum cleaner or similar suctioning device, and an intermediate screen segment used to attach these two segments and keep the specimens from being sucked into the suctioning device.

Method for pest treatment of a plantation field, controlling device for controlling a pest treatment of a plantation field and a treatment device having said controlling device, wherein the treatment considers a pest insect population and a beneficial insect population.

A device, system, and method of controlling pests are disclosed. The system includes an active infrared sensor including infrared emitters and photodetectors. The active infrared sensor is configured to determine an active infrared signature for a monitored space, determine whether the active infrared signature is outside a predetermined window in relation to a baseline signature, and activate a controller in response to determining that the active infrared signature is outside the window. The controller is configured to perform a pest control action in response to activation. The pest control action may include notifying a remote system. The active infrared sensor may be included in a housing having a first opening, a second opening, and a passage sized to receive an insect. The active infrared sensor may be coupled to the housing such that the active infrared sensor is positioned to illuminate part of the passage.

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.