Disclosed herein is an insect trap adapted to entice and collect insects with UV light. The insect trap includes: a main body; a cross-fan mounted inside the main body; an insect collector detachably provided to a lower side of the cross-fan and collecting insets; and a decoy UV LED installation unit coupled to a buttress above the main body and provided with a decoy UV LED module, wherein the main body has an inlet port defined by a space open at an upper side thereof, and a cross-section of the main body corresponding to a facet of the cross-fan on which fan blades of the cross-fan move upwards with reference to a rotation direction of the cross-fan defines a first flow channel and a second flow channel extending perpendicularly from the first flow channel to the insect collector, in which the first flow channel is composed of an inclined shape gradually narrowed downwards from the inlet port and a curved shape extending in an arc shape from a lower end of the inclined shape.

Our invention combines a disposable dual walls lampshade in a specific arrangement to create a space to accommodate the attracting, killing, holding and disposing of insects on a light device. It separates the catching space from the lighting area for keeping a clean lighting. The disposable dual walls lampshade comprises of an internal wall and an external wall, the two walls sealed in bottom edges and has a small open in the top, it forms a one workable piece. All insects will always be caught inside by applied sticky material or chemical agent, insect dead body is trapped in the space between inside of the external wall and outside of the internal wall. Since the dead insects always kept inside the cavity, there is no directly way to touch dead insect, it is safe for children and pets because the special arrangement of the double walls.

An insect trap useful for trapping flying insects, the insect trap comprising an upper housing including at least one horizontal row of light emitting diodes extending across an outer surface of a curved front wall such that light from each of the light emitting diodes is projected outwardly from the upper housing at a different angle than adjacent light emitting diodes in the horizontal row of light emitting diodes, a base housing including an opening through which insects can enter an interior of the base housing, and an insect trapping element facing the opening in the base housing.

An insect trap useful for trapping flying insects, the insect trap comprising an upper housing including at least one horizontal row of light emitting diodes extending across an outer surface of a curved front wall such that light from each of the light emitting diodes is projected outwardly from the upper housing at a different angle than adjacent light emitting diodes in the horizontal row of light emitting diodes, a base housing including an opening through which insects can enter an interior of the base housing, and an insect trapping element facing the opening in the base housing.

The current subject matter relates to controlling insects and includes a trap that can vary operation based at least on a target insect. For example, different insects are attracted to and/or repelled by different things, such as gases, orders, lights, and sounds. In general, things that attract a given insect are referred to as attractants and things that repel a given insect are referred to as repellents. By varying the operation of the trap, different attractants and repellants can be used to attract and/or repel specific insects. In addition, these attractants and repellants and/or characteristics thereof can these be varied dynamically based on, for example, time of day, proximity of individuals to the trap, proximity of insects to the trap, geographic location, and the like. Related apparatus, system, articles, and techniques are also described.

Disclosed embodiments relate to a combination axial fan, LED lighting system and electric blue killer. The disclosed systems may include a housing forming an air chamber and an axial fan. The fan may include a fan cavity having an air diversion mechanism to direct air from the fan cavity toward the lighting, fan and electric bug killing components. The inventions include an airflow surface to direct air existing the fan cavity along an LED light fixture. The LED light fixture emits a blue or light blue light which attracts bugs. Moreover, disclosed embodiments include one or more electric bug killing devices to kill any bugs as air flows through the air chamber. The present invention may also include grow light fixture in the housing.

Disclosed embodiments relate to a combination axial fan, LED lighting system and electric blue killer. The disclosed systems may include a housing forming an air chamber and an axial fan. The fan may include a fan cavity having an air diversion mechanism to direct air from the fan cavity toward the lighting, fan and electric bug killing components. The inventions include an airflow surface to direct air existing the fan cavity along an LED light fixture. The LED light fixture emits a blue or light blue light which attracts bugs. Moreover, disclosed embodiments include one or more electric bug killing devices to kill any bugs as air flows through the air chamber. The present invention may also include grow light fixture in the housing.

A compact insect trap providing a liquid attractant to lure insects and a fan to draw insects into a container. The container is detachable for ease of cleaning and filling with the attractant. Insects converge near the fumes at a narrow annular passage on the perimeter of the device. An internal fan is activated by a timing circuit and provides intermittent bursts of air directed inside and towards the container. Airflow continues upwards through a screen, the fan, and expelled past a unidirectional valve near the top of the device. Nearby insects are suctioned into the container and are retained within due to the screen, thus preventing contamination of moving parts. As airflow is paused, insects are released from the screen where they fall or fly into the attractant. Other embodiments are described and shown.

A compact insect trap providing a liquid attractant to lure insects and a fan to draw insects into a container. The container is detachable for ease of cleaning and filling with the attractant. Insects converge near the fumes at a narrow annular passage on the perimeter of the device. An internal fan is activated by a timing circuit and provides intermittent bursts of air directed inside and towards the container. Airflow continues upwards through a screen, the fan, and expelled past a unidirectional valve near the top of the device. Nearby insects are suctioned into the container and are retained within due to the screen, thus preventing contamination of moving parts. As airflow is paused, insects are released from the screen where they fall or fly into the attractant. Other embodiments are described and shown.

Object detection systems are provided herein. An example system includes an enclosure formed by a sidewall to define an interaction volume, at least one light source for illuminating the interaction volume with a light, at least one light sensor that senses disturbances in light intensity due to scattering, reflection, or absorption of the light by objects within the interaction volume, and a controller that is configured to detect an object or object behavior within interaction volume based on the disturbances in the light intensity.