A flip function assembly, applied to an electronic device, where the electronic device includes an installation base, and the flip function assembly includes a driving mechanism, a connecting rod transmission mechanism, and a functional module, where the driving mechanism includes a first driving component, and the connecting rod transmission mechanism includes a first connecting rod and a second connecting rod, where a first end of the first connecting rod is connected to the first driving component, and a second end of the first connecting rod is hinged to the functional module, a first end of the second connecting rod is hinged to an installation base, a second end of the second connecting rod is hinged to the functional module, and the first driving component drives the first connecting rod to move, so that the second connecting rod drives the functional module to rotate.

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.

A rotary to linearly reciprocating motion converter includes a case, a closure member engaging an opening of the case to dispose a pinion gear rotatably coupled to the closure member, the pinion gear having half the diameter as an interior ring gear of the case, and further includes a pinion shaft connected to the pinion gear on a first side of the closure member and to an inboard end of a crank arm on a second side of the closure member, the outboard end of the crank arm having a force transfer member aligned with a point on the periphery of the pinion gear. Rotation of the closure member relative to the case results in the force transfer member moving in a linearly reciprocating mode. The force transfer member may be coupled to a conveyor to reciprocate the conveyor as the closure member rotates.

A knife drive assembly for use in a harvesting header may be mounted near the center line of the cutter bar of the header. Mechanical power from the power unit behind the header (typically the combine power output shaft) may be translated for application to two knife assembly sections in the cutter bar at the front of the cutter table. Movement of the two knife assembly sections with this apparatus can be fully synchronized and 180 degrees out of phase, to maximize cutting effectiveness and minimize vibration of the header. The unitary drive assembly may allow for rapid repair and manufacture, and the size and weight of the knife drive assembly may represent a significant weight and balance advantage over the prior art.

A mechanical device includes a worm and two swing units disposed in a housing. Each swing unit has a pivot member and a swing member meshing with the worm. The swing member has an arcuate cam slot that has a first end and a second end. A rail is fixed to the housing above the swing units and the worm. Two sliders are connected to the swing units. Each slider has a slide block engaging the rail, an extension arm, and a protrusion protruding from the extension arm and inserted into the arcuate cam slot to slide between the first and second ends of the arcuate cam slot when the worm drives the swing member to swing.

A planetary roller screw drive for an actuator of a rear-axle steering system of a motor vehicle, including a planetary roller support which accommodates the planetary rollers and is connected to a drive sleeve for rotation therewith, which drive sleeve is driven rotatably about the screw spindle and is mounted rotatably on a machine part by an axial angular contact roller bearing which is arranged coaxially with respect to the drive sleeve and of which the rollers are in rolling contact with angled-bearing raceways which are inclined with respect to a plane arranged transversely with respect to the axis of rotation of the drive sleeve.

A gear assembly is disclosed for driving a ram arranged in a pressing channel of a square baler so as to be movable between end positions. The gear assembly comprises at least one side gear, which may be driven indirectly by a power take-off shaft of an agricultural production machine, and at least one reduction gear which is connected downstream from the at least one side gear and may be connected on the output side to a crankshaft on which the ram is mounted. The gear assembly further includes at least one flywheel that is connected between the at least one side gear and the at least one reduction gear, and at least one shiftable clutch device that is connected between the at least one flywheel and the at least one reduction gear.

A mechanical device includes a worm and two swing units disposed in a housing. Each swing unit has a pivot member and a swing member meshing with the worm. The swing member has an arcuate cam slot that has a first end and a second end. A rail is fixed to the housing above the swing units and the worm. Two sliders are connected to the swing units. Each slider has a slide block engaging the rail, an extension arm, and a protrusion protruding from the extension arm and inserted into the arcuate cam slot to slide between the first and second ends of the arcuate cam slot when the worm drives the swing member to swing.

A knife drive assembly for use in a harvesting header may be mounted near the center line of the cutter bar of the header. Mechanical power from the power unit behind the header (typically the combine power output shaft) may be translated for application to two knife assembly sections in the cutter bar at the front of the cutter table. Movement of the two knife assembly sections with this apparatus can be fully synchronized and 180 degrees out of phase, to maximize cutting effectiveness and minimize vibration of the header. The unitary drive assembly may allow for rapid repair and manufacture, and the size and weight of the knife drive assembly may represent a significant weight and balance advantage over the prior art.

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.