Disclosed is a method of incapacitating a target pest species. The method having the steps of providing a trap enclosure, the trap enclosure having an entry point for the target pest species into an interior of the trap enclosure, and a bait station to attract the target pest species. Provided also is a kill engine, at least in part mounted from the trap enclosure, to at least in part deliver incapacitating energy to the target species, whereby the kill engine does not require electricity, the kill engine using an inflammable gas charge, the kill engine when triggered actuates and then resets itself. A source of compressed inflammable gas is connected to and supplies the kill engine. Present is a species adapter connected at least in part to the trap enclosure to adapt the trap enclosure to the target pest species, the species adapter based on the size, habits or travel, nature of the target pest species. A kill zone is defined within an interior of the trap enclosure and or the species adapter. A trigger mechanism actuates the kill engine when triggered by the target pest species when in the kill zone. A force delivery hammer, driven by the kill engine, delivers the incapacitating energy, such that when the target pest species enters the apparatus and the kill zone it triggers the trigger mechanism to in turn actuate the kill engine to deliver the incapacitating energy by impacting the pest.

A pest control device comprising a capacitive sensor array including a plurality of sensor pads, the capacitive sensor array being configured to generate an electrical output signal indicating the state of each sensor pad, and an electronic controller electrically connected to the capacitive sensor array, the electronic controller including a processor and a memory including a plurality of instructions, which, when executed by the processor, causes the processor to: receive the electrical output signals from the capacitive sensor array, determine a measured capacitance value for each sensor pad based on each electrical output signal, calculate a baseline for each sensor pad based on the measured capacitance value of the sensor pad, determine whether a difference between the measured capacitance value of at least one sensor pad and its corresponding baseline exceeds a first predetermined threshold, update a counter when the first predetermined threshold is exceeded, and record an event indicative of a presence of a pest when the counter exceeds a predetermined limit.

A pest control device comprising a capacitive sensor array including a plurality of sensor pads, the capacitive sensor array being configured to generate an electrical output signal indicating the state of each sensor pad, and an electronic controller electrically connected to the capacitive sensor array, the electronic controller including a processor and a memory including a plurality of instructions, which, when executed by the processor, causes the processor to: receive the electrical output signals from the capacitive sensor array, determine a measured capacitance value for each sensor pad based on each electrical output signal, calculate a baseline for each sensor pad based on the measured capacitance value of the sensor pad, determine whether a difference between the measured capacitance value of at least one sensor pad and its corresponding baseline exceeds a first predetermined threshold, update a counter when the first predetermined threshold is exceeded, and record an event indicative of a presence of a pest when the counter exceeds a predetermined limit.

A rodent trap is disclosed comprising a base and a kill bar, wherein the kill bar is pivotably connected to the base, a trigger member pivotably connected to the base and arranged between the base and the kill bar such that when the trigger member is activated the kill bar is released and traps or kills a rodent, the rodent trap further comprises a sensor configured to detect at least three different distances between the trigger member and the base. A rodent trap system is disclosed and a related method for determining a ready state, a sprung empty state and a caught state of a rodent trap.

A rodent trap is disclosed comprising a base and a kill bar, wherein the kill bar is pivotably connected to the base, a trigger member pivotably connected to the base and arranged between the base and the kill bar such that when the trigger member is activated the kill bar is released and traps or kills a rodent, the rodent trap further comprises a sensor configured to detect at least three different distances between the trigger member and the base. A rodent trap system is disclosed and a related method for determining a ready state, a sprung empty state and a caught state of a rodent trap.

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.

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.

A smart micro-mouse trap is disclosed herein which can be used to trap and kill the mouse, rat, rodent, etc. instantly. The embodiment comprises an enclosure for the mouse, a beam to detect the mouse, a trap, a latch and a solenoid powered by an electrical circuit to activate the tripping mechanism as the mouse enters the trap and breaks the beam. The smart micro-mouse trap is advantageous and useful as it is inexpensive, easy to operate, durable and allows for sanitary disposal of the dead mice, rats, rodents without contact to human.

A smart micro-mouse trap is disclosed herein which can be used to trap and kill the mouse, rat, rodent, etc. instantly. The embodiment comprises an enclosure for the mouse, a beam to detect the mouse, a trap, a latch and a solenoid powered by an electrical circuit to activate the tripping mechanism as the mouse enters the trap and breaks the beam. The smart micro-mouse trap is advantageous and useful as it is inexpensive, easy to operate, durable and allows for sanitary disposal of the dead mice, rats, rodents without contact to human.

A strike trap with improved reliability and ease of setting. In a preferred configuration the improved trap is in the form of a tunnel or tube trap. In a preferred embodiment the strike bar moves upward from a low position to strike against an interior wall or equivalent structure of the tube. The strike bar is set by pressing it downward to become automatically latched near a floor or bottom of the tube. With the downward set action a single hand or foot can provide the set motion wherein the ground or other support surface exclusively provides a reaction force. A two stage retention system provides reliable low force, low travel trip action. The strike bar therefore can pivot adjacent to a wall with the bar extending away there from. This compact arrangement ensures the tube entrances in the tube embodiment are adjacent to the wall.