An intelligent Forcipomyia taiwana monitoring and management system comprises: a catching mechanism grabbing a to-be-identified target; a database storing a datum comprising pictures of a flying insect category; a model training module using the pictures to establish a training model; an image capture module shooting an image including the target; an identifying module selecting a first segmented region including the target by using YOLO detection framework technology, extracting a first identification feature from the target, and inputting the feature into the training model for deep learning to identify a flying insect category to which the target belongs and produce an identification result; a counting module recording a number of the target into the database; and a predictive tracking module obtaining a marked object based on the result marked with the target identified in the image, and using a Monte-Carlo category algorithm to track and predict the object.

An insect vacuum and trap attachment system can include a tubular member having an elongate channel that extends along an outer surface of the tubular member. The system can also include a suction member that slideably receives the tubular member. The suction member can have a narrowed open tip that receives insects and a stem that extends along at least an outer surface of the suction member. The stem can be slideably received by the elongate channel to enable the suction member to slide with respect to the tubular member. The system can include a catch that protrudes from the stem. The catch may be arranged and configured to receive a portion of an insect filter pod and thereby couple the insect filter pod between the tubular member and the suction member.

The present application provides a negative pressure boosting net cover and an electric fan mosquito swatter. The negative pressure boosting net cover comprises a bracket and a negative pressure boosting assembly, wherein the bracket is connected to the negative pressure boosting assembly, and the negative pressure boosting assembly is fixed at the air inlet of the fan cover shell. The negative pressure boosting assembly is composed of at least one negative pressure boosting body, which are fixed at the air inlet of the fan cover shell through brackets. Gaps between the negative pressure boosting body and the negative pressure boosting body/fan cover shell forms the ventilation openings and air passages. The technical solution of the present application expands the mosquito trapping range, enhances the suction force, and improves the mosquito trapping efficiency; on the premise that the limited power of the fan is not increased.

A base assembly has an upward plate, a downward plate, a side wall, a front, a back, and laterally spaced sides. A drive assembly has drive wheels extending downwardly from the downward plate, a caster wheel, and proximity sensors. A vacuum assembly has a vacuum slit in the downward plate between the lateral sides and a vacuum-generating source capable of pulling a vacuum through the vacuum slit. A tower assembly is adapted to attract and kill insects while the base assembly and the tower assembly are being optionally driven by the drive assembly and the vacuum assembly is vacuuming up insects.

An insect trapping device traps, kills and facilitates disposal of an insect. The device includes a handle which is hollow defining a conduit extending between a first end and a second end. A fan coupled to the handle in the conduit such that the fan provides suction into the first end of the handle. A cup is coupled to the first end of the handle for directing an insect into the first end of the handle. A receptacle is coupled to the second end of the handle and vented end such that the fan urges air flow out through the receptacle wherein the receptacle receives and holds the insect sucked through the first end of the handle.

This invention allows safe and easy capture, secure containment, visual examination and release or other disposition of small invertebrate specimens. It interfaces with a vacuum cleaner or other source of negative air pressure and is comprised of three main parts or segments: A collection segment used in capturing and containing insect specimens and the like, an attachment segment used in attaching the apparatus to a vacuum cleaner or similar suctioning device, and an intermediate screen segment used to attach these two segments and keep the specimens from being sucked into the suctioning device.

The flying insect vacuum device removes annoying insects, and particularly flying insects such as flies, from inside or outside of the home or anywhere else they might show up. The flying insect vacuum device is a portable handheld unit with a handle, battery, and eject battery button on the backside of the device. The power button turns the vacuum motor on and off. On the front of the invention is a large grill over a funnel that sucks the flies into a storage compartment in the center of the device. The device has strong vacuum suction, an adjustable front suction tool, an insect trapping compartment, and a quick release on and off button.

An insect vacuum device includes a housing having an inlet end opposite a rear end. A grip portion extends from a lower side of the housing. A barrel is affixed to the inlet end, wherein the barrel is in fluid communication with an interior volume of the housing. A reservoir is removably securable to the lower side between the grip portion and the inlet end. A motor is within the housing at the rear end, wherein the motor generates suction between the inlet end and the reservoir when the motor is activated. A trigger is disposed on the lower side, wherein the trigger activates the motor when the trigger is actuated. An inlet valve and a motor valve are disposed within the housing and move to an open position while the trigger is actuated.

The invention relates to an active insect capturing device, comprising a capture opening having an opening edge, preferably at least one receiving chamber having at least one chamber wall, at least one glare light source, and an insect trap, wherein the insect capturing device comprises at least one carrying handle and is portable. The invention further relates to an active insect capturing device, comprising a capture opening having an opening edge, preferably at least one receiving chamber having at least one chamber wall, at least one glare light source, wherein the insect capturing device is an, in particular removable, vacuum cleaner attachment for a vacuum cleaner having a carrying handle.

An insect vacuum device is provided. The device includes a housing having an inlet end opposite a rear end. A grip portion extends from a lower side of the housing. A barrel is affixed to the inlet end, wherein the barrel is in fluid communication with an interior volume of the housing. A reservoir is removably securable to the lower side between the grip portion and the inlet end. A motor is within the housing at the rear end, wherein the motor generates suction between the inlet end and the reservoir when the motor is activated. A trigger is disposed on the lower side, wherein the trigger activates the motor when the trigger is actuated. An inlet valve and a motor valve are disposed within the housing and move to an open position while the trigger is actuated.