RU207814U1 - INSECT TRAP - Google Patents

Abstract

An insect trap containing a cover, mutually perpendicular plates, a light emitter based on superbright LEDs located along the axis of intersection of the plates, a cone attached to the plates, a cylinder with an additional light emitter in the lower part located on a transverse bar fixed on the walls of the cylinder, and an insect collector, attached to the cylinder from below by a bandage, characterized in that a radiator with a lower cover is attached to the light emitter, and the insect collector is made of fine-mesh material, in the lower part of which the size of the cells is determined by the size of the target species of captured insects.

Description

The utility model relates to agriculture and forestry, in particular, to the technique of trapping insects using LED emitters and can be used for phytosanitary monitoring of crops, forests and forest parks, as well as for plant protection by mass capture of large, economically significant phytophages.

Known insect trap containing a cover, mutually perpendicular plates, a light emitter based on superbright LEDs located along the axis of intersection of the plates, a cone attached to the plates and a cylinder with an additional light emitter in the lower part (RU 129363 U1). The disadvantage of this trap is the small volume of the collection and partial loss of insects during the day.

The closest to the proposed utility model is an insect trap containing a cover, mutually perpendicular plates, a light emitter based on superbright LEDs located along the axis of intersection of the plates, a cone attached to the plates, and a cylinder with an additional light emitter in the lower part, with a cylinder in the upper The part is equipped with an axial fan, a mesh ring filter located at the level of the lower opening of the cone, and an elastic windproof transparent insect collector (RU 186343 U1). An additional light emitter in the lower part of the cylinder is placed on a transverse bar fixed to the walls of the cylinder, and the insect collector is attached to the bottom of the cylinder by a band. The disadvantage of this trap is its high energy consumption due to the presence of a fan in the device, and the use of a windproof, closed insect collector leads to the capture and destruction of all attracted insects, including beneficial insects.

The technical result to be achieved by the claimed utility model is to reduce energy consumption, which increases the battery life of the device, increases the service life of LEDs and, accordingly, the device as a whole, as well as capture of target insects and release from the insect collector into the agroecosystem of representatives of useful and indifferent entomofauna.

The achievement of the specified technical result is provided by an insect trap containing a trap cover, mutually perpendicular plates, a light emitter based on superbright LEDs located along the axis of intersection of the plates, a cone attached to the plates, a cylinder with an additional light emitter in the lower part, placed on a transverse bar fixed on the walls of the cylinder, and an insect collector attached to the bottom of the cylinder by a bandage, while a radiator with a lower cover is attached to the light emitter, and the insect collector is made of fine-mesh material, in the lower part of which the size of the cells is determined by the size of the target species of captured insects.

The drawing shows a general view of an insect trap.

The insect trap contains a cover 1 located on mutually perpendicular plates 2, a light emitter based on superbright LEDs 3 located along the axis of intersection of the plates 2, a radiator 4 with a lower cover 5, a cone 6 attached to the plates 2, a cylinder 7 with an additional light emitter 8, placed on the transverse bar 9, and an insect collector 10 made of fine-mesh material, attached to the cylinder 7 from below by a bandage 11.

The operation of the device is as follows. The device starts working at dusk. The flow of light attracts insects at night to the light emitter 3. The luminous LEDs generate a lot of heat energy, which is evenly dissipated by the radiator 4, and the bottom cover 5 helps to cool the radiator faster, which increases the life of the LEDs and, accordingly, the device. Some insects collide with plates 2, temporarily immobilize, under the influence of gravity fall on the inner surface of the cone 6 and fall into the cavity of the cylinder 7, and then into the insect collector 10. When insects enter the cavity of the insect collector, insects have the opportunity to leave it if their size is smaller or commensurate with the mesh size of the collector 10, the size of which is selected so that the target species of insects cannot penetrate through them. An additional light emitter 8 located on a transverse bar 9 attached to the walls of the cylinder 7 allows insects to be kept in the cylinder 7 and the insect collector 10 at night. In the daytime, insects concentrate in the lower part of the collector 10 or on the inner side between the band 11 and the outer walls of the cylinder 7. This solution makes it possible to leave insects with obviously smaller sizes in the habitat in comparison with the target species, for which traps are set. The proposed model does not use a fan, which makes it less energy consuming.

Comparative tests have shown that the number of captured small insects when using the proposed model of the trap decreases 50 times without a significant decrease in the number of captured economically significant species. Table 1 shows the results of comparative tests of the proposed trap for insects and a light trap that collects in the cavity of the insect collector all attracted insects on vegetable crops during the mass summer of aquatic beetles (family Heteroceridae, Hydrophilidae), cottonworm and other economically significant representatives of the family Noctuidae. The traps were compared in terms of the number of captured insects in the same period (August 6-18).

On perennial pome crops in the 1st-2nd ten-day period of August, the effect of the proposed utility model was tested on mass capture of such a large butterfly as corrosive arboreal (Zeuzera pyrina L.). As a result of tests during the mass capture of females and males of arboreal trees in the proposed model of the trap, significantly fewer small ground beetles (Coleoptera / Carabidae) and ladybirds (Coleoptera / Coccinellidae) were caught in comparison with the prototype in the same period. At the same time, the number of captured individuals of arboretum did not significantly decrease (Table 2).

Claims (1)

An insect trap containing a cover, mutually perpendicular plates, a light emitter based on superbright LEDs located along the axis of intersection of the plates, a cone attached to the plates, a cylinder with an additional light emitter in the lower part located on a transverse bar fixed on the walls of the cylinder, and an insect collector, attached to the cylinder from below by a bandage, characterized in that a radiator with a lower cover is attached to the light emitter, and the insect collector is made of fine-mesh material, in the lower part of which the size of the cells is determined by the size of the target species of captured insects.

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