The present invention relates to an equipment for attracting, capturing, counting and monitoring flying insects of all species and is particularly applicable to those which cause damage to agricultural crops and are considered to be hazardous to public health and comprises a Ultra Violet lamp in the colorless plastic ring and a pheromone reservoir. The plate with the insect inlet channels houses the Infra-Red sensors and the photographic camera, which in turn is housed in a sealed housing, The upper part which fits in turn in the previously said watertight housing, houses the photovoltaic panel, the microprocessor, the Global Position System GPS receiver, the Global System for Mobile signal transmitter and receiver module, and the Wireless Fidelity—WIFI transmitter and receiver module, a rechargeable battery and a micro USB socket.

An adapter is provided that is specially designed for coupling to traps existing in the market, with no need for any change in them, including the dynamics of entry, perforations and physical structure. The adaptation includes automating the detection, continuous remote counting, and perimeter control of lepidopterans. Its application is in the agricultural sector within the most distinct crops and sectors, being the main ones: grain storage and, in agricultural production areas (cotton, soy, corn, beans, coffee, cocoa, orange, sugar cane, African palm, among others).

The device is a fan, similar to a typical rotary desk fan, but with the motor running in reverse to create inward airflow. An insect screen lines the rear of the blade housing ana a hinged door is located at the bottom of the housing. A small cup is mounted to the front of the fan to hold insect attractant.

When the insect approaches the attractant, it is drawn into the inward airflow and into the fan housing. Because the rear of the housing is lined with fine mesh screening, the insect cannot escape and will eventually die of dehydration. The hinged door at the bottom of the housing allows convenient removal of accumulated dead insects.

The present disclosure relates to a light, in particular, to a light having a fly killing function that can be used for lighting and killing flies comprising at least one LED chip, a fly storage means, a negative pressure fan, a fan hanger, a ventilation net, and a power supply; wherein the fly storage means is connected to the fan hanger, the LED chip is secured to a lower end of the fly storage means, the fly storage means comprises an air inlet and a fly storage groove, the negative pressure fan is mounted onto the fan hanger above the fly storage means, a gap is provided between the blades of the negative pressure fan and an upper end of the fly storage means to allow flies to go through; the ventilation net comprises a plurality of ventilation holes having a size that is able to stop flies from passing therethrough, and the ventilation net is provided circumferentially between the outside wall of the fan hanger and the outside wall of the fly storage means, and the fan hanger, the ventilation net, and the fly storage means form a closed space except the ventilation holes and the air inlet.

In some implementations, an insect trap includes a plurality of individual cells, with each of the cells being configured to trap very few, and in some instances a single flying insect. Each cell defines a cavity and may be provided with an independently operable door to selectively close the cavity. One or more sensors may sense the presence of an insect to be trapped.

A beehive pest trap includes a first surface, second surface, and side beams. The side beams are coupled to and support the second surface. The side beams are coupled to and positioned on the first surface. The second surface is coupled to and positioned on the side beams. The first surface, second surface, and side beams form a gate entrance. The second surface is positioned parallel to the first surface. The second surface is wider than the first surface. The gate entrance is positioned proximate to an insect trap. The second surface is L-shaped. The trap also includes a screen and a trap drawer. The first surface comprises a lateral side. The lateral side and the side beam form a cavity. The trap door is slidably positioned in the cavity. The insect trap includes the trap drawer. The second surface includes a pest door slidably coupled thereto.

A beehive pest trap includes a first surface, second surface, and side beams. The side beams are coupled to and support the second surface. The side beams are coupled to and positioned on the first surface. The second surface is coupled to and positioned on the side beams. The first surface, second surface, and side beams form a gate entrance. The second surface is positioned parallel to the first surface. The second surface is wider than the first surface. The gate entrance is positioned proximate to an insect trap. The second surface is L-shaped. The trap also includes a screen and a trap drawer. The first surface comprises a lateral side. The lateral side and the side beam form a cavity. The trap door is slidably positioned in the cavity. The insect trap includes the trap drawer. The second surface includes a pest door slidably coupled thereto.

A device for converting an ovi trap commonly used to capture mosquitos into a trap configured for trapping flies. The device includes an insert having a disc-shaped member that has holes on one end and channels extending from the holes on the other end. The insert is placed on a cylindrical capture chamber of an ovi trap such that the channels extend into the hollow of the capture chamber. Fly attractant is provided in the well of the ovi trap such that flies, attracted to the bait, will enter through the holes in the insert and fly down the channels into the capture chamber. Once in the capture chamber, they are unable to fly upwardly to escape.

Insect capture is improved by providing a glue board having an adhesive coating on its front surface and forming a pattern of insect attractant UV light on that front surface. That pattern includes areas of bright UV light generated by light-emitting diodes that generate light at different wavelengths behind and visible through the glue board by flying insects, dimmer areas of light generated by said light emitting diodes that bounces off other portions of the device onto the glue board, and areas of shadow on the glue board where no or little light from said light-emitting diodes is present.

A method and system for preparing a distribution program for insects comprises obtaining distribution data of a wild population of insects; obtaining distribution parameters including distribution resolution levels of at least one available distribution vehicle; generating a population density map at a resolution level consistent with the distribution resolution level of the vehicle; generating a release map by modifying the population density map in accordance with the distribution parameters; and generating a path using the release map, the path defining dosages of insects to be released at respective locations along the path.