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.

Exemplary embodiments of a flashlight having an electronic insect control system are provided. In some exemplary embodiments, a flashlight apparatus is provided, having a head portion comprising a first light source, a tail portion, and a body portion between the head portion and tail portion, the body portion comprising an electronic insect control system, the electronic insect control system comprising a frame portion, a second light source provided within the frame portion, and an electrical grid provided within the frame portion and surrounding the second light source, wherein the electrical grid is configured to generate a voltage.

Methods, systems, and apparatus, including computer programs encoded on computer-storage media, for a calibration target for ultrasonic removal of ectoparasites from fish. In some implementations, the calibration target includes a fish-shaped structure, sensors positioned at different locations of the fish-shaped structure, a processor that receives sensor values from the sensors, and a transmitter that outputs sensor data from the calibration target based on the sensor values.

The present invention provides an electrified garbage container cover that destroys insects that may attempt to access, or escape from a garbage container. The electrified garbage container cover includes a silicone cover configured to fit the opening of a garbage container, said cover having an opening; and an electrified top. The electrified top comprises a mesh frame portion, which supports an electrified mesh and is configured cover the opening; and an electrified mesh capable of electrifying insects; and a power source; wherein the electrified mesh comprises: a central mesh having a first side and a second side, the central mesh electrically connected to the power source and supported by the mesh frame portion; a first ground mesh located adjacent and spaced apart from the first side of the central mesh and electrically connected to the power source and supported by the mesh frame portion; a second ground mesh located adjacent and spaced apart from the second side of the central mesh and electrically connected to said power source and supported by the mesh frame portion.

A portable insect control trap has, in a single portable device, two modes of attracting insects, including a first mode adapted to attract flying insects (e.g. insect-attracting light) and a second mode adapted to attract crawling insects (e.g., bait). The same device has two modes of killing insects, including a first mode adapted to kill flying insects (e.g. an electrified grid) and a second mode adapted to kill crawling insects (e.g. an electric heating element). The first mode of attracting is associated with the first mode of killing, the second mode of attracting is associated with the second mode of killing.

One embodiment provides a system, including: a first end that screws into a light bulb socket; an internal light source; an electric insect control mechanism disposed around and proximate to the internal light source; and a visible light source disposed at an opposite end with respect to the first end. Other embodiments are described and claimed.

The present invention is about turning the gaseous envelope that encoats, protects certain arthropods from their external environment against them. It teaches to apply radiation to the arthropods body in order to dysfunction the exacting geometry needed to maintain this protective envelope. This absorbed radiation thus makes the arthropod vulnerable to pesticides and other chemical agents. It also interferes with the arthropods ability to adequately breathe through their plastron covering by forcing it to increase its rate of metabolism via this absorbed radiation.

Disclosed is an insect repulsion and/or barrier system (10) and a method for repelling insects (2) and/or for preventing insects (2) from passing through a defined opening (12) or surface (9). The barrier system (10) is equipped with devices (16) for preventing insects from passing through an opening (12) or for repelling insects when approaching the opening (12) and/or the devices (16). The devices (16) have at least two electrodes (18), whereby different electrical potentials are applied to or can be applied to the at least two electrodes (18). The at least two electrodes (18) are arranged within or on the edge of or outside the opening such that an electrical field (28) is formed between the at least two electrodes (18). The electrical field (28) rejects and/or repels insects approaching the electrical field (28) or prevents insects approaching the electrical field (28) from passing through the opening (12).

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.

An insect elimination device has an outer grid with an inner grid disposed within the outer grid. A voltage source powers the inner grid, the outer grid or both. A warming tube is disposed within the inner grid and provides a thermal lure. A UV light source is disposed within the warming tube to provide a first optical lure. A control circuit controls the duty cycle, which is greater than 0% and less than 100%, of the UV light source while the voltage source is powering the elimination zone of the inner grid and the outer grid to keep the thermal lure within a predetermined temperature range.