Devices are embodied that eliminate flying insect pests in quite a different way than others devices have used in the past. If insects are attracted to a surface large enough to accommodate their numbers and allowed to gather for a time without being restrained or bothered, it is possible by way of these embodiments at a single location to eliminate insects in very large number on a daily basis. Depending on a device's size and embodiment, from several hundred to far in excess of one hundred thousand flying insects per twenty-four hour period can be eliminated.

An apparatus for concentrating then killing mosquito larvae, comprising: a mosquito larvae trap for containing a stagnant, stationary pool of water; and an electrical connection for enabling a power source attached to the electrical connection, to introduce an electrical current into the stagnant, stationary pool of water, with a voltage sufficient to electrocute mosquito larvae in the stagnant, stationary pool of water.

A system and method are provided to control the amplification of natural frequencies emanating from molecules, specifically insect sex pheromones. The pheromone molecules are deposited in a resonant cavity that allows the generation of coherent and/or semi-coherent radiation. The molecular emissions are amplified in the resonant cavity and allowed to escape through a small circular opening on top of the resonant cavity. The molecules and/or their emissions dissipate into the surroundings to attract insects towards the cavity. When the insect enters the resonant cavity, a trap door prevents the insect from exiting. The molecular emissions are produced by passive diffusion and passive amplification because no pumping radiation source is required. However pumping radiation can be integrated to assist the passive amplification or serve as a second attractant.

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 rapid method to detect and/or remove mobile insects inside granular material is presented. The core of this method is to heat grain samples to the desired temperatures (about 55 C) using microwave or radio frequency energy to force insects to move out of the granular material.

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.

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.

An apparatus and the associated method which includes means for controlling an invasive organism. The means including a trolling apparatus, for attachment to an associated vehicle. The trolling apparatus is pulled through a body of water in response to movement of the associated vehicle. The housing carries a plurality of UV-C light sources for producing UV-C light at a wavelength of substantially 254 nm, whereby invasive organisms proximate to light emanating from at least one of said UV-C light source whereby invasive organisms are exposed to UV-C light at a wavelength of substantially 254 nm resulting in controlling an invasive organism. Other embodiments, attract organisms such as mosquitos and then expose them to UV-C light. The invention facilitates reduced use of herbicide.

One aspect provides a system, including: a first end configured to attach to a light bulb socket; an internal light source; an electric insect control mechanism proximate to the first end and including electrified meshes disposed around and proximate to the internal light source; a visible light source disposed at an opposite end with respect to the first end; and circuitry configured to: operate both the internal light source and the visible light source after the system is attached to the light bulb socket; and responsive to user input, control the internal light source and the visible light independently.