A multifunctional rotating element is usable as various parts of a powertrain. The multifunctional rotating element includes a body and a plurality of contact elements. The body has an axis of rotation and is configured to rotate about the axis of rotation, and defines a rim portion. The plurality of contact elements are arranged around the rim portion. Each of the contact elements is independently movable between a raised position and a depressed position and biased to the raised position. Each of the contact elements is configured to move to the depressed position when engaged with an object.

The invention provides an engagement method for engaging a first gear element with a second gear element, at least the second gear element being mounted to move between a meshing position and a disengaged position by means of an actuator. The engagement method including a step of driving at least one of the gear elements in rotation so as to establish a non-zero difference in speed of rotation between said gear elements, and a step of controlling the actuator to perform the following in succession: moving at least the second gear element towards the meshing position; on detecting contact between the gear elements, stopping the movement of the second gear element; and on detecting an ideal angular position for engaging said gear elements, moving the second gear element as quickly as possible into the meshing position.

A module bearing and a power transmission device including the module bearing. A module bearing includes a module outer wheel supported by and in contact with a side wall of a gear to guide rotational or linear motion of the gear, a bearing rotor rotatably disposed radially inward of the module outer wheel, and a part-assembly type module inner wheel disposed radially inward of the module outer wheel with the bearing rotor interposed therebetween and connected to the bearing rotor, in which a plurality of separate parts are manufactured and assembled into the part-assembly type module inner wheel to apply a preload to the bearing rotor.

A module bearing and a power transmission device including the module bearing. A module bearing includes a module outer wheel supported by and in contact with a side wall of a gear to guide rotational or linear motion of the gear, a bearing rotor rotatably disposed radially inward of the module outer wheel, and a part-assembly type module inner wheel disposed radially inward of the module outer wheel with the bearing rotor interposed therebetween and connected to the bearing rotor, in which a plurality of separate parts are manufactured and assembled into the part-assembly type module inner wheel to apply a preload to the bearing rotor.

The present invention provides a transmission roller, a pin-teeth cycloid reducer with the same and a bearing. The transmission roller comprises a hollow roller which is made by spirally and closely winding a steel strip or a steel wire, and the length of the hollow roller remains unchanged when both ends thereof distributed along the axial direction are squeezed. When the hollow roller is subjected to external pressure, the ends thereof will not be easily damaged, and will not extend to the middle part during use, thus having a long service life.

A differential transmission includes a pin-gear type main body unit with a pin-gear type main body housing in which input or output is performed through a plurality of pins rotatably coupled in a circumferential direction of an outer circumferential surface thereof, a high-speed shaft provided at one side of the pin-gear type main body housing and through which input or output of a relatively high speed is performed, a low-speed shaft provided at the other side of the pin-gear type main body housing and through which input or output of a speed that is less than the relatively high speed is performed, and a reduction portion inside the pin-gear type main body housing and reducing an input speed; and a high-speed shaft connection unit connected to the high-speed shaft of the pin-gear type main body unit and through which input or output is performed through the high-speed shaft.

A differential transmission includes a pin-gear type main body unit with a pin-gear type main body housing in which input or output is performed through a plurality of pins rotatably coupled in a circumferential direction of an outer circumferential surface thereof, a high-speed shaft provided at one side of the pin-gear type main body housing and through which input or output of a relatively high speed is performed, a low-speed shaft provided at the other side of the pin-gear type main body housing and through which input or output of a speed that is less than the relatively high speed is performed, and a reduction portion inside the pin-gear type main body housing and reducing an input speed; and a high-speed shaft connection unit connected to the high-speed shaft of the pin-gear type main body unit and through which input or output is performed through the high-speed shaft.

The present application provides a mechanical gearbox, comprising a wheel oriented vertically; a first set of teeth on a first face of the wheel defining a first gear; a second set of teeth on a second face of the wheel defining a second gear; an input gear operably engaged with the first set of teeth on the first gear; an output gear operably engaged with the second set of teeth on the second gear; wherein the input gear and the first gear have different circular pitches, and/or the second gear and the output gear have different circular pitches.

The present application provides a mechanical gearbox, comprising a wheel oriented vertically; a first set of teeth on a first face of the wheel defining a first gear; a second set of teeth on a second face of the wheel defining a second gear; an input gear operably engaged with the first set of teeth on the first gear; an output gear operably engaged with the second set of teeth on the second gear; wherein the input gear and the first gear have different circular pitches, and/or the second gear and the output gear have different circular pitches.

An energy transfer system is disclosed. The system (100) includes plurality of rotatable input shafts (108), each having a first end (110) and a second end (112). The first end (110) is coupled to a plurality of drive sources (102). A plurality of rotatable output shafts (120) are operatively coupled to a pinion (116). A plurality of rolling friction gears (114) are coupled to the second end (112) of the plurality of the rotatable input shafts (108). The plurality of rolling friction gears (114) have circular gear teeth that mesh with circular gear teeth of the pinion (116) for transferring rotating movements of the plurality of the rotatable input shafts into rotating movements of the plurality of the rotatable output shafts (120). Each of the plurality of the rolling friction gears (114) houses a freewheeling clutch (118) acting upon the pinion (116).