An arm joint is provided with a first coupling part with a first axis and a second coupling part with a second axis. Further, the arm joint includes a third coupling part connected in a manner rotatable around a third axis with the first coupling part. The third axis includes an angle with the first axis in the range of 30-60 degrees, preferably of 45 degrees. The third coupling part is connected in a manner rotatable around a fourth axis with the second coupling part. The fourth axis includes an angle with the second axis in the range of 30-60 degrees, preferably of 45 degrees. The third and the fourth axis mutually include an angle in the range of 60-120 degrees, preferably of 90 degrees. A robot arm with a number, preferably three, of such arm joints is also disclosed.

Disclosed is a triple harmonic speed reducer, which enables a flexible inner gear to generate three tooth misalignment motions after a wave generator rotates for one circle, so that the harmonic speed reducer has higher position precision and rotation precision, more stable transmission, and more stable operation. The triple harmonic speed reducer includes a wave generator, a flexspline and a rigid circular spline, wherein the flexspline includes a flexible inner gear and an output part, the wave generator is arranged in an inner installation cavity of the flexible inner gear, the wave generator includes an input shaft end and a cam, wherein a flexible bearing is annularly arranged between an outer ring peripheral surface of the cam and an inner ring peripheral surface of the flexible inner gear, the cam of the wave generator is specifically of a three-convex structure.

A gear device includes an internal gear, a flexible external gear, and a wave generator. The wave generator includes an elliptical cam and a bearing. Grease is applied to the inner circumferential surface of the external gear. A groove is provided along a rotation axis on at least one of the inner circumferential surface of the external gear and an outer circumferential surface of the bearing.

A gearing includes an internal gear, a flexible external gear partially meshing with the internal gear and relatively rotating about a rotation axis to the internal gear, and a wave generator provided inside of the external gear and moving a mesh position between the internal gear and the external gear in a circumferential direction about the rotation axis, wherein the external gear includes an external tooth having an external tooth surface, the external tooth surface has an external tooth convex pattern including a first convex portion and a second convex portion extending in directions crossing directions of a tooth trace of the external tooth and arranged adjacent to each other in the directions of the tooth trace, and a distance between the first convex portion and the second convex portion is from 80 μm to 520 μm.

The invention relates to a flexible transmission components for a harmonic drive comprising a resilient toothing element formed as a sheet metal part and having external toothing, and a printed circuit board bonded to the toothing element.

A circular wave drive system is provided. In one aspect, the circular wave drive includes a compliant input ring gear having an inner surface having internal input ring gear teeth; an input cycloidal disc having an outer surface having external input cycloidal disc gear teeth oriented on the outer surface, and wherein the external input cycloidal disc gear teeth at least partially engage the internal input ring gear teeth; a compliant primary drive gear having an outer surface having external primary drive gear teeth; an eccentric motion generator including an eccentric portion and a non-eccentric portion and wherein a centerline of the eccentric portion and the non-eccentric portion are offset from one another; and an output cycloidal disc having an inner surface with internal output cycloidal disc teeth, and wherein the internal output cycloidal disc teeth at least partially engage the external primary drive gear teeth.

Disclosed is a compound harmonic gear motor having: first and second ground gears connected by a stationary shaft; a wave generator including an outer surface that can rotate completely around the stationary shaft, the wave generator including a rotor and a stator, wherein rotation of the rotor causes rotation of the outer surface; a flex spline surrounding the outer surface of the wave generator that is driven to rotate by rotation of the outer surface of the wave generator; and an output flange including internal teeth that mate with the flex spline to cause rotation of the output flange completely around the stationary shaft.

A wave transmission gearbox includes an output wheel, a deformable gear band, a low profile fixed spline, a wave generator, and a flexible-band-compensating rigid torque transmitter. The deformable gear band has external teeth transmitting relative torque motion to the output wheel, and is as wide as its external teeth. The low profile fixed spline has internal teeth meshing with the external teeth of the deformable gear band, and has a width which is a function of the width of the deformable gear band. The wave generator deforms the deformable gear band within the low profile fixed spline to generate relative torque motion between the deformable gear band and the low profile fixed spline. The flexible-band-compensating rigid torque transmitter transfers relative torque motion from the deformable gear band to the output wheel.

A novel way of mounting a harmonic drive gearhead to a cylindrically shaped motor reduces the overall size of the actuator assembly. Specifically, the motor is mounted within the harmonic drive and its bearings, a space that is typically occupied by a harmonic drive component. This is made possible by redesigning the harmonic drive such that it is able to surround the motor and provide for a compact footprint for the actuator assembly.

A first driving device includes a motor including a rotating shaft, a speed reducer, and a supporting member. The speed reducer includes a rigid gear, a flexible gear configured to partially mesh with the rigid gear, and a wave motion generator coupled to the rotating shaft and configured to come into contact with the inner circumferential surface of the flexible gear, bend the flexible gear, and move a meshing position of the rigid gear and the flexible gear in the circumferential direction. The wave motion generator includes a projecting section projecting along the rotating shaft. The rotating shaft is supported by the supporting member via a bearing including an inner ring and an outer ring. The outer ring of the bearing is supported by the supporting member. The rotating shaft and the projecting section are coupled to the inner ring of the bearing by tight fitting.