A selective access system, and methods of making and using such a selective access system, whereby the selective access system includes a container including an interior space defined by a side wall disposed between opposing top and bottom walls; an opening disposed within the side wall, the opening communicating with the interior space; a cover slidably engaged with the container, the cover configured to slide upward and downward between a first position and a second position; whereby in the first position, the cover overlays the opening; and whereby in the second position, the cover disposes away from at least a portion of the opening to permit access to the interior space; and a force generator coupled to the cover, the force generator generating a pre-selected force amount which when unopposed, provides the first position of the cover.

A bait rack including a mounting leg and a bait support portion is provided. The mounting leg has a bottom free edge and at least one mounting slot formed therein. The bait support portion includes an intermediate portion, an upward extending portion and a trough portion. The intermediate portion is connected to the mounting leg by a bent region formed between the mounting leg and the intermediate portion. The intermediate portion extends relative to the mounting leg in a non-parallel and non-perpendicular manner. The trough portion connects and is interposed between the upward extending portion and the intermediate portion. The intermediate portion, trough portion and upward extending panel portion forming a bait holding trough therebetween. A plurality of slots provide access to the bait holding trough from a location external of the bait holding trough. A bait station including the bait rack is also provided.

Compositions attractive to mice include one or more long-range volatiles and one or more short-range volatiles. The long-range volatiles can include butyric acid, 2-methylbutyric acid, and 4-heptanone. Devices and methods of using the compositions are also disclosed.

The present invention discloses a waterfowl trapping device, comprising a trapping base and a trapping main body, wherein the trapping base comprises an upper seat and a lower seat, and the exterior of the trapping base is connected with a floating device; spread trapping wings are arranged on two sides of the trapping main body; a battery, a controller, a water pump and a deceleration motor which are electrically connected with each other are arranged in the trapping base; a switch is arranged between the battery and the controller; a plurality of nozzles are arranged outside the trapping base, and the nozzles are connected with the water pump by pipes; the floating device is composed of floating balls installed by a plurality of floating cross rods; and the present invention is practical, low in production cost and vivid in trapping when floating on water; and can be folded in nonuse.

A hunting decoy apparatus, wherein the decoy exhibits lifelike movements controlled mechanically by a user. The apparatus comprises an outer sleeve member and a movable slidable member slidably engaged within the outer sleeve member. The outer sleeve member attaches to the ground. The decoy stand is inserted into the movable sliding member and extends perpendicular from the outer sleeve member in an upward direction with a decoy on top. The distal ends of the slidable inner sleeve member and the outer sleeve member are connected by an extension limiting biasing element such as a spring or elastic cord. A tether is attachable to the proximal end of the movable slidable member. To activate movement of the decoy, the tether is pulled and released by the user causing the decoy and decoy stand to move within the slot forward and backwards. Small tugs on the tether by the user causes the decoy to move in lifelike movements creating the appearance the decoy is bobbing and pecking like a wild bird.

A system and methods for trapping animals including an enclosure adapted to be suspended above a trap area. The enclosure may be movable from the suspended position to a lowered position to enclose a trap area. The system further includes a user-directed control system to remotely control the position of the enclosure in order to trap animals within the enclosure.

An electronic rodent trap includes an outer housing forms a trap body having two entrances defined on opposite sides thereof and creates a tunnel therebetween extending longitudinally between the entrances. A high voltage killing circuit is arranged within the trap body, and includes a plurality of killing plates and a triggering element separate from the plurality of killing plates and spaced inwardly from the entrance. A removable tunnel module is received within the outer housing and includes opposed entrances in alignment with the two entrances of the trap body. A removable electronics module is received within the outer housing, the electronics module contains the voltage circuit operatively connected to the plurality of killing plates.

An electronic rodent trap and monitoring method is provided. Each trap has at least one entrance, and preferably two entrances in opposed relationship to create a longitudinal tunnel, with a pair of lower plates extending longitudinally and oriented in spaced substantially parallel relationship, and a triggering element, such as a third plate, positioned above the lower plates, and preferably adjacent the ceiling of the trap on a center baffle that also shields a bait cup. The trap is activated when the rodent, with its left and right feet on the parallel lower plates, which are preferably raised above the floor, contacts the triggering element on the center baffle. The trap is preferably modular in design with an electronics module and a tunnel module removably secured within and protected by an outer housing. The trap also has improved features for more accurate remote monitoring of rodent dispatch and kill verification.

A selective access system for permitting selective access to ingestible matter disposed within a feeder, and methods of making and using such a selective access system, whereby the selective access system includes a cover having opposing cover first and second ends, the cover first end configured to rotatably couple to the feeder to allow the cover to rotate about a rotation axis between a first position and a second position. In the first position, the cover overlays a feeder opening in which the ingestible matter is disposed. In the second position, the cover disposes away from the feeder opening to permit access to the ingestible matter. The selective access system further includes a force generator coupled to the cover, wherein the force generator generates a pre-selected force amount which when unopposed, provides the first position of the cover.

A system and method for eradicating burrowing rodents uses an internal combustion engine running at high speed and zero mechanical load to convert gasoline and air into pressurized carbon monoxide entrained in an inert gas mixture consisting mostly of nitrogen and water vapor. A heat exchanger cools the exhaust gas and provides it to one or more outputs. Respective hoses are coupled to the outputs, with each hose coupled to an injector tube adapted for insertion into a subterranean tunnel in which a rodent may be present. The engine is preferably mounted on a wheeled tubular frame which may be part of a hand truck or a trailer frame, with the frame serving as both structural member and as heat exchanger. The system pumps gas into the tunnel, replacing the existing atmosphere with oxygen poor, CO rich gas that causes the rodents to succumb to a combination of CO poisoning and hypoxia.