A quick cleaning structure and a mosquito-killing lamp applying the same, the quick cleaning structure includes a lamp holder and a high-voltage support, the high-voltage support includes a plurality of high-voltage tubes and a sliding cleaning member provided with a plurality of sliding through-holes, at least one ends of the high-voltage tubes are fixedly mounted on the lamp holder and are disposed in parallel with each other, each high-voltage tube passes through the sliding through-hole provided at a corresponding position, the sliding cleaning member slides along an outer wall of the high-voltage tubes. The sliding cleaning member of the quick cleaning structure slides along the high-voltage tubes under an external force, and the sliding through-holes provided in the sliding cleaning member are in contact with the outer wall of the high-voltage tubes to clear mosquito bodies adhered on the outer wall of the high-voltage tubes.

An insect killing system has a blower drawing air entraining insects from below a vacuum machine, impelling the air upward, a flange oriented horizontally at an outlet to the blower, and a killing assembly affixed to the flange. The system is characterized in that the killing assembly comprises a plurality of panels of a common width, having an upper edge, a lower edge, and opposite side edges defining an area for each panel, the area closed by a relatively thin perforated sheet material exhibiting a matrix of through holes, individual panels affixed by the bottom edge to the flange on opposite sides, with each panel oriented by a steep angle from vertical, with each panel in the plurality parallel to and spaced apart from one or more adjacent panels, such that the area defined by an inside diameter of the flange is covered by the plurality of adjacent parallel panels.

A solar powered lighting element with a simulated flame and an electric insect eliminator includes a lighting portion with a conducting grid and a light portion that simulates a flickering flame which are powered by a rechargeable battery that is recharged using a solar panel. One or more UV light elements are provided in addition to the flickering flame to attract insects.

A solar powered lighting element with a simulated flame and an electric insect eliminator includes a lighting portion with a conducting grid and a light portion that simulates a flickering flame which are powered by a rechargeable battery that is recharged using a solar panel. One or more UV light elements are provided in addition to the flickering flame to attract insects.

The present disclosure provides for a composition and method for attracting bed bugs to a trap or to a location where an insecticide or pesticide is present, or to a trap or a location where a bed bug infestation can be detected. The present disclosure provides for a composition for attracting bed bugs that includes one or more of methyl diethanolamine (MDEA), monoethanolamine (MEA), diethanolamine (DEA), triethanolamine (TEA), and dimethyl trisulfide (DMTS); a carrier; and optionally one or more amides selected from oleamide, octanamide, nonanamide, and laurylamide; urea, biuret, or triuret; and one or more aliphatic fatty acids. The present disclosure further provides for a method for treating an article by applying the composition to the article, where the article comprises a device for trapping or detecting bed bugs or a device for treating a bed bug infestation.

Mosquito control systems and devices are described herein. The devices include a connector positioned at a first end of the device, the connector configured to couple to a light bulb socket to provide power to the device; an LED light source positioned at a second end of the device; an electrocuting mechanism disposed between the connector and the LED light source, the electrocuting mechanism configured to electrocute the mosquitos upon the mosquitos upon contact; a carbon dioxide generating device configured to generate and release carbon dioxide to attract the mosquitos to the device; and a heater configured to generate and release heat to attract the mosquitos to the device.

A device for detecting a group of offending objects and determining that the number of offending objects is above a predetermined threshold of offending objects. The device uses an image capturing system to scan areas to detect flying objects such as flying insects to detect a presence of a swarm of such flying objects. An action head on the device is configured to automatically respond once a swarm of objects is identified. The action head may disperse the swarm by expelling a substance such as a mist, smoke, repellant or insecticide.

A device for detecting a group of offending objects and determining that the number of offending objects is above a predetermined threshold of offending objects. The device uses an image capturing system to scan areas to detect flying objects such as flying insects to detect a presence of a swarm of such flying objects. An action head on the device is configured to automatically respond once a swarm of objects is identified. The action head may disperse the swarm by expelling a substance such as a mist, smoke, repellant or insecticide.

An electric shock system for a bird feeding device includes a main body having a top wall, a side wall, and a bottom wall with an opening. A battery holder is disposed within the main body and retains a battery. A conductor array is positioned between the battery holder and the side wall and is connected to the battery.

An induction heating system a base and an electromagnetic radiation source configured to generate an emission area in the base. The emission area comprises a portion of the base that receives electromagnetic radiation from the electromagnetic radiation source. The system also includes a ferromagnetic element and an element controller configured to move the ferromagnetic element into and out of the emission area.