A removeable, adhesive wrapper used to augment any existing rodent trap by affixation to the top, side and bottom faces of the rodent trap's operating platform. It is folded about the operating platform and connected to itself, leaving an adhesive layer facing up in the region of the bait station. When the rodent steps on it and stops to take the bait, they are no longer capable of quickly moving when they activate the trap's trigger and the kill bar of the rodent trap is released. Even if the rodent does not reach the bait station, their jiggling efforts to extricate their feet and/or lower body from the adhesive wrapper will activate the trigger. Once dead, the adhesive wrapper may be unfolded and wrapped around the dead rodent for disposal.

A motion sensing rodent killing apparatus includes a housing that has a bottom wall and a perimeter wall. The perimeter wall includes a front wall. A motion sensor is directed outwardly away from the front wall. A ram is mounted on the housing and is movable toward or away from the front wall. A driving system is mounted to the housing and is engaged with the ram. The driving system retains the ram in a set position having the panel positioned adjacent to the front wall. When the motion sensor detects motion, the driving system drives the panel away from the housing to a deployed position with sufficient force such that a rodent positioned between the panel and a facing surface is killed by the panel.

Disclosed herein is a retaining assembly for an animal trap. The retaining assembly includes a housing configured to be mounted to a base of the animal trap. A drawer is slidably coupled to the housing between a first position and a second position. A retaining feature is coupled to the drawer. The retaining feature is configured to engage with a retaining arm of the animal trap in the first position and disengage from the retaining arm in the second position.

A device for receiving a rodent trap includes a first planar portion for receiving the trap and a second planar portion operably connected to and extending from the first planar portion. The device also includes electronic components configured to be housed within one or more of the first planar portion or the second planar portion. The electronic components include a sensor configured to detect motion of an object located on one or more of the first planar portion or the second planar portion, a battery configured to provide power to the device; and a communications system configured to provide data from the sensor to a computing device.

A snap style vermin trap disposed on a planar platform having a concave bait box with a vertical trigger. The bait box is centrally located on the front face of the trigger and positioned at a distance above the top face of the platform so as orientate the vermin into a physical posture that greatly enhances the probability of a kill or capture. The trap may be oriented with the platform beneath or above the rapid actuation means of the snap trap and it may use an optional housing to cover the rapid actuation means.

An animal trap sensor includes a base having a distal end and a proximal end, a switch having a first metallic element and a second metallic element, and a signal unit, in which, when the first metallic element contacting the second metallic element, thereby forming a closed circuit, such that the signal unit transmits a signal to an off-site receiver. Or, an animal trap sensor includes a first portion and a second portion electrically connected with a signal unit including a power supply, in which, when the first and the second portions are disposed at a first distance between each other, thereby generating an output property, in which, when the first and the second portions are disposed at a second distance between each other, which is different from the first distance, thereby changing the output property and causing the signal unit to transmit a signal to an off-site receiver.

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 herein is a retaining assembly for an animal trap. The retaining assembly includes a housing configured to be mounted to a base of the animal trap. A drawer is slidably coupled to the housing between a first position and a second position. A retaining feature is coupled to the drawer. The retaining feature is configured to engage with a retaining arm of the animal trap in the first position and disengage from the retaining arm in the second position.

In one embodiment, an animal trap comprises an outer housing configured as a hollow shell with one or more side openings in a lower end portion of the housing; a moveable plunger member; and an inner cartridge removably coupled to an interior of the housing. The cartridge supports therein: the plunger member configured to move axially between a raised position and a lowered position relative to the housing and the cartridge; and a retaining mechanism configured to selectively retain the plunger member in the raised position.

A motion sensing rodent killing apparatus includes a housing that has a bottom wall and a perimeter wall. The perimeter wall includes a front wall. A motion sensor is directed outwardly away from the front wall. A ram is mounted on the housing and is movable toward or away from the front wall. A driving system is mounted to the housing and is engaged with the ram. The driving system retains the ram in a set position having the panel positioned adjacent to the front wall. When the motion sensor detects motion, the driving system drives the panel away from the housing to a deployed position with sufficient force such that a rodent positioned between the panel and a facing surface is killed by the panel.