An enclosure-type electronic rat trap having an interior accessed through a trap entrance and a rat pathway that leads from the entrance to a baited end opposite the entrance is provided. At least three killing plates coupled to a high voltage circuit are positioned along the pathway in spaced relationship and a barrier extends into and constricts the pathway at a specified distance from a center plate in order to reduce the ability of the rat to escape the trap once the rat has traveled along the pathway sufficiently to initiate a killing cycle.

An enclosure-type electronic rat trap having an interior accessed through a trap entrance and a rat pathway that leads from the entrance to a baited end opposite the entrance is provided. At least three killing plates coupled to a high voltage circuit are positioned along the pathway in spaced relationship and a barrier extends into and constricts the pathway at a specified distance from a center plate in order to reduce the ability of the rat to escape the trap once the rat has traveled along the pathway sufficiently to initiate a killing cycle.

A trap has a housing including an entrance. Internally, the trap has a trigger structure including a trigger plate and a latch mechanism, coupled with the housing; and a pivoting structure pivotally coupled with the housing and adapted to releasably engage with the latch mechanism of the trigger structure. When the trap is triggered by a rodent, the pivoting structure disengages from the latch mechanism and the pivoting structure pivots towards a rear wall of the housing and the trigger plate, and the trigger plate pivots toward the pivoting structure, moving the rodent against towards the rear wall of the housing and trapping the rodent between the pivoting structure and the rear wall. Once the trap is triggered, the rodent is contained and in most cases, killed, within the trap.

Lethal wildlife traps comprising a trap compartment with an external entrance, an automatically-resetting lethal killing mechanism attached to or located within the trap container, a triggering device to actuate the lethal killing mechanism when the wildlife is positioned properly in the trap container, and an exit at the bottom of the trap container for allowing killed wildlife to fall out of the trap container to the ground or into a separate enclosure, provide economical, humane, and discreet traps for attracting and discretely killing pest species including, for example, nesting birds, rodents, and snakes; other small animals; or invertebrate species.

Lethal wildlife traps comprising a trap compartment with an external entrance, an automatically-resetting lethal killing mechanism attached to or located within the trap container, a triggering device to actuate the lethal killing mechanism when the wildlife is positioned properly in the trap container, and an exit at the bottom of the trap container for allowing killed wildlife to fall out of the trap container to the ground or into a separate enclosure, provide economical, humane, and discreet traps for attracting and discretely killing pest species including, for example, nesting birds, rodents, and snakes; other small animals; or invertebrate species.

Disclosed are various embodiments for a trap monitor. The trap monitor can detect when a trap is triggered using a magnetic interlock attached to the trap and a magnetic flux sensor. The trap monitors may forward trap events and other information to a central hub for communication to a server. The trap monitors and hub can be configured using infrared transmissions from a mobile device.

Disclosed are various embodiments for a trap monitor. The trap monitor can detect when a trap is triggered using a magnetic interlock attached to the trap and a magnetic flux sensor. The trap monitors may forward trap events and other information to a central hub for communication to a server. The trap monitors and hub can be configured using infrared transmissions from a mobile device.

A trap for capturing a plurality of animals is provided. The trap can comprise an enclosure having an opening through which the at least one animal can pass to enter the enclosure. A gate, movable between an open position and a closed position, is positioned therein the at least one opening and can be selectively moved from the open position to the closed position when desired. Methods are also provided for capturing at least one animal by providing a trap with a gate, positioning the gate in an open position, monitoring the trap until at least one animal has entered the trap, and remotely triggering the gate to move from the open position to a closed position.

A trap for capturing a plurality of animals is provided. The trap can comprise an enclosure having an opening through which the at least one animal can pass to enter the enclosure. A gate, movable between an open position and a closed position, is positioned therein the at least one opening and can be selectively moved from the open position to the closed position when desired. Methods are also provided for capturing at least one animal by providing a trap with a gate, positioning the gate in an open position, monitoring the trap until at least one animal has entered the trap, and remotely triggering the gate to move from the open position to a closed position.

A remotely activated door-opening mechanism is provided for a cage trap having an animal enclosure, preferably a cage trap as disclosed in U.S. Publ. No. US2008/0115405. The mechanism is mounted outside the enclosure of the trap and is preferably remotely activated by an IR or RF transmitter to open a door of the trap and release a trapped animal when the operator is at a safe distance away. The mechanism may also be manually set with a time delay and may be associated with either a main entry door to the trap or with a secondary escape door located at an opposite end of the trap.