Provided is an air blowing device that makes it possible to safely improve insect trapping performance. The air blowing device 1 is provided with: a housing 2 comprising an inlet 20 and an outlet 5 for air; an air blower 10 arranged within the housing 2; a pre-filter 8 that is arranged in the inlet 20 and that collects dust within air; and a cover member 3 that comprises an air suction port 4, that is attached to the housing 2, and that forms an insect trap space 25 between the suction port 4 and the inlet 20. Insects that enter the insect trap space 25 via the suction port 4 are trapped. The outer surface of the cover member 3 is formed so as to have a dark color.

Provided is an air blowing device that makes it possible to safely improve insect trapping performance. The air blowing device 1 is provided with: a housing 2 comprising an inlet 20 and an outlet 5 for air; an air blower 10 arranged within the housing 2; a pre-filter 8 that is arranged in the inlet 20 and that collects dust within air; and a cover member 3 that comprises an air suction port 4, that is attached to the housing 2, and that forms an insect trap space 25 between the suction port 4 and the inlet 20. Insects that enter the insect trap space 25 via the suction port 4 are trapped. The outer surface of the cover member 3 is formed so as to have a dark color.

A device for trapping damaging flying insects, including a device for diffusing an attractive gaseous cocktail, of which the composition is suitable for attracting insects, a suctioning device having an orifice for suctioning an air flow containing the insects attracted by the attractive cocktail diffused, a trap arranged with the suctioning device, and a chassis containing a gas source, which gas is a component of the attractive gaseous cocktail, where the optical insect counter includes a series of parallel deflectors installed through the suctioning orifice, a luminous barrier composed of a light transmitter and a light receiver being installed in each interval between said deflectors.

A device for trapping damaging flying insects, including a device for diffusing an attractive gaseous cocktail, of which the composition is suitable for attracting insects, a suctioning device having an orifice for suctioning an air flow containing the insects attracted by the attractive cocktail diffused, a trap arranged with the suctioning device, and a chassis containing a gas source, which gas is a component of the attractive gaseous cocktail, where the optical insect counter includes a series of parallel deflectors installed through the suctioning orifice, a luminous barrier composed of a light transmitter and a light receiver being installed in each interval between said deflectors.

Disclosed are a system (10) and a method used for the detection and/or monitoring of insect populations (16), in which insects (16) of at least one defined genus are attracted, at least temporarily retained within a defined compartment (12), and sensed and/or analyzed with regard to definable features (14). The invention comprises: features or method steps, as appropriate: attracting the defined genus of insects (16) within a definable spatial vicinity (20) with an attracting stimuli (22); transferring the attracted insects (16) into a defined compartment interior (12) while preventing, at least for a definable time interval, an inadvertent escape, at least of a large number of the insects (16); detecting specific features (14) of the insects (16) with a sensor unit (26); transmitting sensor signals (30) supplied by the sensor unit (26) to an electronic analysis device and/or evaluation device (28) disposed downstream from the sensor unit (26).

Systems, devices, and methods for using insect traps with combinations of dual multi-colored lights combining blue/green LED (light emitting diodes) with UV (ultraviolet) LEDs (light emitting diodes) for attracting insects to the lights and capturing the insects. The blue/green LED can emit at a wavelength of approximately 450 nm to approximately 550 nm in an approximately 180 degrees spread therefrom, and each side UV LED can emit at a wavelength of approximately 365 nm in an approximately 180 degrees spread therefrom. The combinations of multi-color lights can be mounted on one side of a module/fixture, and/or be mounted on opposite side faces of a module fixture. The combinations can use one centrally located blue/green LED with at least one right UV LED to a right side of the centrally located blue/green LED, and at least one left UV LED to a left side of the centrally located blue/green LED. Embodiments can include use on a sticky paper/card, in a housing with fan, and collection tray, and in an electrical gride of wires having a collection tray and sand mesh bag with an approximately 340 micron mesh screen. Embodiments include a plurality of UV (ultraviolet) LEDs (light emitting diodes) greater than the plurality of blue-green LEDs (light emitting diodes).

Systems, devices, and methods for using insect traps with combinations of dual multi-colored lights combining blue/green LED (light emitting diodes) with UV (ultraviolet) LEDs (light emitting diodes) for attracting insects to the lights and capturing the insects. The blue/green LED can emit at a wavelength of approximately 450 nm to approximately 550 nm in an approximately 180 degrees spread therefrom, and each side UV LED can emit at a wavelength of approximately 365 nm in an approximately 180 degrees spread therefrom. The combinations of multi-color lights can be mounted on one side of a module/fixture, and/or be mounted on opposite side faces of a module fixture. The combinations can use one centrally located blue/green LED with at least one right UV LED to a right side of the centrally located blue/green LED, and at least one left UV LED to a left side of the centrally located blue/green LED. Embodiments can include use on a sticky paper/card, in a housing with fan, and collection tray, and in an electrical gride of wires having a collection tray and sand mesh bag with an approximately 340 micron mesh screen. Embodiments include a plurality of UV (ultraviolet) LEDs (light emitting diodes) greater than the plurality of blue-green LEDs (light emitting diodes).

According to an aspect of the invention, a method for trapping indoor adult Phycitinae, which is an adult moth belonging to Phycitinae subfamily includes: emitting attracting light at a predetermined photon flux density for a predetermined period of time or longer; forming a guide path to guide the adult Phycitinae to a vicinity of an emission end of the attracting light in a region having a photon flux density lower than the predetermined photon flux density on a side lower than a height of the emission end; and trapping the adult Phycitinae attracted by the attracting light in the guide path.

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 catching device may include at least two insect capture surfaces, a first surface including a first color, and a second surface including a second, lighter color relative to the first color of the first surface. The second color of the second surface may highlight the presence of insects captured thereon facilitating at least one of ease of counting and ease of identification of captured insects. The insect catching device may also include a line of weakening disposed between the first surface and the second surface. The line of weakening may include at least one perforation. The second surface may be detachable from the first surface along the line of weakening. The first color may be configured to decrease visibility of captured insects on the first surface observable by a viewer through an insect trap cover.