An insect suppression device, and further relates to a self-moving device, a charging station, and an automatic working system that are mounted with the insect suppression device are provided. The self-moving device moves in a working area, performs a working task, and includes: a body and a movement module that is mounted on the body and drives the self-moving device to move. The self-moving device includes: an insect suppression device, mounted to the body, and a control module, controlling the movement module to move and controlling the insect suppression device to work. The beneficial effects of the present invention are as follows: The self-moving device can move autonomously in the working area and perform an insect suppression task, and has a wide coverage area, flexible work, and high efficiency, so that automatic control can be implemented, thereby freeing a user from the harassment of insects.

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.

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.

An insect suppression device, and further relates to a self-moving device, a charging station, and an automatic working system that are mounted with the insect suppression device are provided. The self-moving device moves in a working area, performs a working task, and includes: a body and a movement module that is mounted on the body and drives the self-moving device to move. The self-moving device includes: an insect suppression device, mounted to the body, and a control module, controlling the movement module to move and controlling the insect suppression device to work. The beneficial effects of the present invention are as follows: The self-moving device can move autonomously in the working area and perform an insect suppression task, and has a wide coverage area, flexible work, and high efficiency, so that automatic control can be implemented, thereby freeing a user from the harassment of insects.

Disclosed herein are robotic devices which traverse a pre-defined coverage area in order to capture and eradicate ticks in the area. A vacuum mechanism provides a suction force for pulling ticks into the device through a frontal opening, after which the ticks are captured in a receptacle and crushed by at least one rotating arm. In certain embodiments, the devices include heat strips near the frontal opening of the device that mimic the human body temperature. Additionally, the device can include carbon dioxide emitters that pass carbon dioxide to the receptacle or through the frontal opening to increase attraction of ticks.

Disclosed herein are robotic devices which traverse a pre-defined coverage area in order to capture and eradicate ticks in the area. A vacuum mechanism provides a suction force for pulling ticks into the device through a frontal opening, after which the ticks are captured in a receptacle and crushed by at least one rotating arm. In certain embodiments, the devices include heat strips near the frontal opening of the device that mimic the human body temperature. Additionally, the device can include carbon dioxide emitters that pass carbon dioxide to the receptacle or through the frontal opening to increase attraction of ticks.

Disclosed herein are robotic devices which traverse a pre-defined coverage area in order to capture and eradicate ticks in the area. A vacuum mechanism provides a suction force for pulling ticks into the device through a frontal opening, after which the ticks are captured in a receptacle and crushed by at least one rotating arm. In certain embodiments, the devices include heat strips near the frontal opening of the device that mimic the human body temperature. Additionally, the device can include carbon dioxide emitters that pass carbon dioxide to the receptacle or through the frontal opening to increase attraction of ticks.

Disclosed herein are robotic devices which traverse a pre-defined coverage area in order to capture and eradicate ticks in the area. A vacuum mechanism provides a suction force for pulling ticks into the device through a frontal opening, after which the ticks are captured in a receptacle and crushed by at least one rotating arm. In certain embodiments, the devices include heat strips near the frontal opening of the device that mimic the human body temperature. Additionally, the device can include carbon dioxide emitters that pass carbon dioxide to the receptacle or through the frontal opening to increase attraction of ticks.

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 bug-removal vacuum machine has a horizontal deck, and a structure providing a trapezoidal-shaped air passage directing insects drawn by vacuum-induced air flow through an electrified killing matrix, and into a collection tray.