The invention relates to a composition for the production of CO.sub.2, the use of a composition for the production of CO.sub.2 for an insect trap, in particular for an insect trap for attracting blood-sucking insects and arthropods, and a method for the production of CO.sub.2. The composition comprises a component a), a component b), and a component c). Component a) comprises at least a first yeast strain, which has a low tolerance of less than 100 g of alcohol per liter. Component b) comprises at least one second yeast strain, which has a high tolerance of greater than 100 g of alcohol per liter. Component c) comprises at least one nutrient source for the at least one first yeast strain and/or for the at least one second yeast strain, wherein component c) is being formed by a turbo yeast or by a yeast extract.

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.

A system for detecting the presence of pests, the system comprising: at least one remote camera system, each of the at least one remote camera system comprising an image capture device coupled to a processor and a wireless transmitter, each of the at least one remote camera system having a pest detection surface and being configured to: capture one or more image of the pest detection surface; process the captured one or more image to recognise the potential presence of a target pest on the pest detection surface; and transmit data from the captured one or more image in response to recognising the potential presence of one or more target pests; and a server configured to: receive the transmitted data; process the transmitted data to verify the potential presence of the target pest on the pest detection surface; and provide an output indicating the verification.

A carpenter bee trap includes a plurality of walls surrounding a trap cavity, at least one entrance opening formed through at least one of the plurality of walls, a bottom wall coupled to a bottom of the plurality of walls, an exit opening formed through one of the walls or the bottom wall, a container disposed within the trap cavity and extending through the exit opening and into the external environment, and a funnel disposed within the cavity to direct carpenter bees into the container.

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 mosquito control device includes a connector positioned at a first end of the device. The connector couples to a light bulb socket to provide power to the device. The device also includes an LED light source positioned at a second end of the device and an electrocuting mechanism disposed between the connector and the LED light source. The electrocuting mechanism electrocutes the mosquitos upon contact. The device also includes a carbon dioxide generating device that generates and releases carbon dioxide to attract the mosquitos to the device. The device also includes a heater that generates and releases heat to attract the mosquitos to the device.

An adhesive-type insect trap includes a main body having an adhesive sheet insertion hole; a light source mounting unit disposed on the main body; a cover which is detachably mounted on the main body and has a through-hole in at least a part thereof; an adhesive sheet including a sticky substance and a sheet. The main body includes a guide unit by which the adhesive sheet is guided, and an adhesive sheet support unit for supporting the adhesive sheet.

A device for controlling at least one insect bait station (100), in particular for insects harmful to humans, animals and plants, in which the bait station is provided with: at least one container (3, 5) provided with an insect entrance opening, the container containing bait and being at least partially transparent or translucent, a lighting device (10) lighting the inside of the container but located outside same, a telecommunication module (23, 25) and a printed circuit comprising, inter alia, a memory and a processor connected to said telecommunication means. The device comprises an optical sensor essentially opposite the lighting device, and connected to the printed circuit (12), which measures the general opacity caused by the insect(s) in the container, the corresponding value being transmitted for processing and analysis of the status of the bait station.

A discrete and safe automated insect monitoring system includes a housing, an interior chamber within the housing, and a light source arranged within the housing to illuminate at least a portion of a floor surface of the interior chamber. A multi-pixel optical sensor is arranged within the housing so that a field of view of the sensor comprehends a substantial portion of the floor surface. A processing circuit arranged within the housing receives optical data from the multi-pixel optical sensor, analyzes the optical data to detect the intrusion of an insect or other object into the interior chamber by comparing most recently received optical data to previously received optical data, and generates an indication in response to detecting the intrusion of an insect or other object. Detection and/or classification results can be wirelessly forwarded to another device, to alert appropriate personnel.

An apparatus includes a portable housing with a cavity, a heater disposed within the cavity of the housing, a temperature buffering device coupled to the heater and disposed within the cavity of the housing, a non-biological skin substitute substrate coupled to the temperature buffering device and disposed within the cavity of the housing, and a carbon dioxide delivery device coupled to the housing. The non-biological skin substrate simulates a surface property of human skin.