A waterfowl motion simulation device for affecting the motion of waterfowl decoys in an aquatic terrain is disclosed. The waterfowl motion simulation device includes a winding unit configured to wind and unwind a line assembly. The line assembly includes a main line with a plurality of decoy attachment appendages provided at various points along its length. The winding unit includes a motor accommodated inside a winding unit housing, and a winding implement rotatably supported outside the winding unit housing by an output shaft of the motor. A control unit electrically connected to the motor is operable to control the rotation of the winding implement to wind and unwind the line assembly by controlling the motor according to a rotational speed and timing indicated by user input received through at least one user interface. A power supply unit is removably engaged with, and electrically connected to the control unit through, a power supply interface on an exterior surface of the winding unit housing. The waterfowl motion simulation device preferably also includes a mounting assembly configured to adjustably support at least in part the power supply unit, power supply interface, winding unit, and control unit above an aquatic terrain. A method of using the waterfowl motion simulation device to affect the motion of at least one waterfowl decoy in an aquatic terrain is also described.

An automatic duck decoy jerk string device 1 having an enclosure 2, a mounting pole 6, a lockable mount 8 for mounting the enclosure 2 at different heights on the mounting pole 6, an electric motor 10 in the enclosure 2, a battery 12 configured to power the electric motor 10, a speed control 13 to control a rotational speed of a motor drive shaft 16, an elongated slider 20 partially inside the enclosure 2 and partially outside the enclosure 2, the elongated slider 20 moves back-and-forth towards the inside of the enclosure and away from the inside of the enclosure, a gear system 14 connected to the motor drive shaft 16 to reduce the rotational speed of the motor drive shaft 16 and rotate a drive arm 18, and a link arm 28 is rotatably mounted to the drive arm 18 and rotatably mounted to the first slider end 22. A method of using the jerk string device to move duck decoys 48 on a jerk line 38 connected to the elongated slider 20.

An automatic duck decoy jerk string device 1 having an enclosure 2, a mounting pole 6, a lockable mount 8 for mounting the enclosure 2 at different heights on the mounting pole 6, an electric motor 10 in the enclosure 2, a battery 12 configured to power the electric motor 10, a speed control 13 to control a rotational speed of a motor drive shaft 16, an elongated slider 20 partially inside the enclosure 2 and partially outside the enclosure 2, the elongated slider 20 moves back-and-forth towards the inside of the enclosure and away from the inside of the enclosure, a gear system 14 connected to the motor drive shaft 16 to reduce the rotational speed of the motor drive shaft 16 and rotate a drive arm 18, and a link arm 28 is rotatably mounted to the drive arm 18 and rotatably mounted to the first slider end 22. A method of using the jerk string device to move duck decoys 48 on a jerk line 38 connected to the elongated slider 20.

The present disclosure is directed to motion waterfowl decoys and methods of attracting waterfowl using same. The waterfowl decoy mimics the feeding behavior of live waterfowl by moving its head toward a surface without the remainder of their body moving in the same motion. The feeding motion is provided by rotating a spherical ball breast of the decoy, to which the head is attached. When the ball breast rotates, the head moves toward the surface while the body remains in its initial position. Rotation is provided using manually-provided pressure or a battery-driven device, such as a bilge pump or a gear motor. When rotation of the ball breast ceases to be provided, a counterweight in the ball breast returns to its initial position, moving the ball breast and head back to an upright position.

The present disclosure is directed to motion waterfowl decoys and methods of attracting waterfowl using same. The waterfowl decoy mimics the feeding behavior of live waterfowl by moving its head toward a surface without the remainder of their body moving in the same motion. The feeding motion is provided by rotating a spherical ball breast of the decoy, to which the head is attached. When the ball breast rotates, the head moves toward the surface while the body remains in its initial position. Rotation is provided using manually-provided pressure or a battery-driven device, such as a bilge pump or a gear motor. When rotation of the ball breast ceases to be provided, a counterweight in the ball breast returns to its initial position, moving the ball breast and head back to an upright position.

A system for obtaining the attention of a game animal includes two speakers and a control unit. The two speakers may be placed a distance apart from one another and a hunter. The control unit is usable by the hunter to separately and independently control the speaker assemblies remotely, thereby providing the hunter with the ability to create sounds from different directions or locations to obtain a better shot at the game animal.

A system for obtaining the attention of a game animal includes two speakers and a control unit. The two speakers may be placed a distance apart from one another and a hunter. The control unit is usable by the hunter to separately and independently control the speaker assemblies remotely, thereby providing the hunter with the ability to create sounds from different directions or locations to obtain a better shot at the game animal.

A wind-aided game decoy system that allows for multiple decoys moving independently on a single support. The system comprises multiple pivot arms holding multiple decoys. The pivot arms are attached to pivot channels on a wheel hub. The wheel hub is rotatably mounted to a support. The wheel hub may further comprise pin bores along the peripheral edge of the wheel hub allowing a user to adjust the swing of the pivot arms with insertion and removal of pins. The support of the wheel hub can be a stake with one end inserted into a ground and another end connected to the wheel hub. Alternatively, the wheel hub may be moved away from the stake by using an extension arm that connects to a bearing case and runs to the wheel hub, wherein the bearing case is connected to the stake.

A wind-aided game decoy system that allows for multiple decoys moving independently on a single support. The system comprises multiple pivot arms holding multiple decoys. The pivot arms are attached to pivot channels on a wheel hub. The wheel hub is rotatably mounted to a support. The wheel hub may further comprise pin bores along the peripheral edge of the wheel hub allowing a user to adjust the swing of the pivot arms with insertion and removal of pins. The support of the wheel hub can be a stake with one end inserted into a ground and another end connected to the wheel hub. Alternatively, the wheel hub may be moved away from the stake by using an extension arm that connects to a bearing case and runs to the wheel hub, wherein the bearing case is connected to the stake.

A support pole system for supporting articles above the ground or earth includes a support pole formed from at least two elongated pole sections that are movably coupled together so that the pole sections can be moved relative to one another between collapsed and extended positions to shorten and lengthen the support pole. An article head piece is coupled to an upper end of the support pole for attaching articles to the support pole. A base assembly couples to the lower end of the support pole and has a stake configured for insertion into the ground or earth for supporting the support pole in an upright position. The stake has projecting members that engage the ground or earth when the stake is inserted therein to prevent rotation of the stake about the longitudinal axis of the stake. A cross member is positioned at an upper end of the stake to form a footrest to facilitate insertion of the stake into the ground or earth.