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.

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.

A moving assembly has a base with a base bottom, a side wall, a rectangular conduit formed in the base bottom, and a fan with a motor mounted on the base bottom, and a collector box for collecting mosquitos. The fan functions to create a vacuum for drawing in mosquitos. A killing assembly has an upper dish and a lower dish. The upper dish has electrically charged wires. A pool in the lower dish constitutes a container for standing water. Air tubes are laterally spaced and vertically oriented. The air tubes have upper ends disposed above the pool to draw in mosquitos entering the vicinity of the upper ends and lower ends received in the rectangular conduit.

A vortex insect trap includes an insect trapping container, a fan and an insect-killing device. The insect trapping container internally defines an air flowing space, in which the insect-killing device is disposed. The air flowing space is enclosed in at least one flow-guiding wall surface and communicable with external environment via an air suck-in port and an air exit port of the vortex insect trap. The fan is mounted to the air exit port for sucking in external air via the air suck-in port and discharging air inside the air flowing space from the insect trapping container via the air exit port. When the fan operates, air sucked into the air flowing space flows along the flow-guiding wall surface to form a spiral air flow that flows toward a bottom of the air flowing space while carries insects sucked into the air flowing space to the insect-killing device.

An autonomous drone integrated with wide bandwidth, high energy acoustic wave generators sent to evict and eradicate agricultural pests within a patrolling area. The drone hovering close to a plant bombards its leaves and fruits with high energy acoustic waves via frequency and tone determined by an onboard synthesizer through acoustic power amplified to drive the sideways and bottom mounted acoustic wave generators. Agricultural pests such as caterpillar, beetle and the like are bombarded with powerful acoustic waves causing their bodies to vigorously vibrate and resonate with synthesizer frequency to dislodge or kill the pests. Other insects such as moths are forced airborne by a propeller's strong downdraft and are electrocuted by integrated high voltage screens. Inside a hotel room, the drone hovers close to a surface of a bedding mattress, bombarding the surfaces with powerful acoustic waves tuned to frequencies that cause bed bugs to resonate and die.

Provided is an insect monitoring device including a tube. An attractor is positioned at an entrance to the tube, and an imaging device is configured for producing data associated with a monitored insect, wherein the data being usable in machine learning.

The invention relates to an ultraviolet mosquito-killing lamp with an electric shock protection function. The ultraviolet mosquito-killing lamp includes a shell, a power line, and an ultraviolet lamp circuit, a high-voltage switching circuit, a high-voltage net and a switch gear which are located in the shell, wherein the ultraviolet lamp circuit is connected with the high-voltage switching circuit, and the high-voltage switching circuit is connected with the high-voltage net; the switch gear is a double-pole switch, and the double-pole switch is electrically connected with the power line. When the ultraviolet mosquito-killing lamp is powered off, both the live wire and the neutral wire are cut off, and thus the electric shock risk caused by the possibility that the live wire is not cut off when a single-pole switch is turned off is avoided.

A method and apparatus for the management of a soil pest is disclosed and which includes a source of high voltage electricity; at least one capacitor for storing the high voltage electricity; a multiplicity of electrodes inserted into a soil location having a soil pest to be managed, and an electrical switch which is controllably opened and closed so as to form a pulse of electricity which is passed through the soil location and between the electrodes so as to effect the management of the soil pest.

Systems and methods for minimizing phorid fly infestation in cemetery mausoleum buildings are provided. An insecticide can be applied to electrostatically charged screens, which can be shaped to fit various openings in mausoleum buildings, including openings comprised by windows, crypt vents, roof vents, and floor drains. Standalone units can also be installed having insecticide applied electrostatically charged screens. The screens can be placed to interrupt the phorid fly mating and egg-laying process to limit or prevent phorid fly infestation in mausoleum buildings.

A vacuum suction adapter device equipped with an electric shock module includes an adapter main body comprising an air inlet and an air outlet, the air outlet being detachably connected with a suction main body, negative pressure being formed inside the adapter main body, and the air inlet being detachably connected with a suction nozzle, air flows into the adapter main body from the air inlet and to be expelled from the air outlet. The electric shock module is disposed in the adapter main body for electrical discharge under high electric voltages for generating electric arc sparks. The electric voltage boost module is electrically connected with the electric shock module to electrically power the electric shock module for electrical discharge under the high electric voltages.