The present application discloses a mechanism to adjust backlash in a rack and pinion powertrain assembly. The mechanism to adjust backlash includes a mounting frame having an opening defined therein to receive an operative end of a drive assembly, a shoulder fastener positioned through a first complementary set of holes at a first end of a mounting flange to movably couple the mounting flange to the mounting frame, the fastener being fastened in a manner such that the mounting flange and drive assembly have freedom to pivot about a longitudinal axis of the first complementary set of holes, and an adjustable length coupling device having a first end coupled mechanically to the mounting plate and a second end coupled mechanically to the mounting flange at a location substantially opposite the first end of the mounting flange.

In one embodiment, a method includes accessing a target value for a gear system, where the target value includes a target backlash or a target preload, and where the gear system includes a driving gear, a driven gear, a preloading actuator coupled to the driving gear, and a preloading actuator controller, determining a measured value for the gear system, where the measured value includes a measured backlash or a measured preload, determining that an error value between the measured value and the target value exceeds a threshold error, and sending, by the preloading actuator controller, instructions to the preloading actuator to adjust the driving gear in response to determining the error value between the measured value and the target value exceeds the threshold error.

A joint structure for a robot according to the present disclosure includes a first link and a second link rotatably coupled to each other via a joint part. The joint part has a first rotary member disposed so that an axial center thereof is oriented in a first direction and connected to the first link, a pair of second rotary members disposed so that an axial center thereof is oriented in a second direction perpendicular to the first direction, and so as to engage with the first rotary member, and a shaft member formed in a T-shape and having a first shank and a pair of second shanks. The joint structure further includes a pressing member connected to the second shank and configured to press the second rotary member inwardly.

A robot includes a base, a first body provided above the base, a first gearing configured to rotate the first body about the base, a second body provided above the first body, a second gearing configured to tilt the second body about a tilting axis, an interface installed in at least one of the first body and the second body, a first gear mounted on the second body and tilted together with the second body, and a damper mounted on the first body. The damper includes a damping gear engaged with the first gear, and the first gear is tilted along an outer circumference of the damping gear.

In one embodiment, a method includes accessing a target value for a gear system, where the target value includes a target backlash or a target preload, and where the gear system includes a driving gear, a driven gear, a preloading actuator coupled to the driving gear, and a preloading actuator controller, determining a measured value for the gear system, where the measured value includes a measured backlash or a measured preload, determining that an error value between the measured value and the target value exceeds a threshold error, and sending, by the preloading actuator controller, instructions to the preloading actuator to adjust the driving gear in response to determining the error value between the measured value and the target value exceeds the threshold error.

A planetary gearing for a robot gearing arrangement includes a sun gear, a ring gear, and a planet carrier with at least three planetary gears rotatably mounted thereon. The planetary gears are arranged on planet pins arranged perpendicular to the planet carrier and are in meshing engagement with the sun gear and the ring gear. At least one first planetary gear is biased in a first circumferential direction and/or at least one second planetary gear is biased in a second circumferential direction. A first planet pin of the first planetary gear is at least partially elastically deformable in the second circumferential direction and/or the second planet pin of the second planetary gear is at least partially elastically deformable in the first circumferential direction.

A planetary gear train including a ring gear defining a central axis; a plurality of planet gears, each planet gear being rotatable about a respective planet axis and meshing with the ring gear, and each planet gear including a conical and helical planet gear toothing defining a conical direction; a planet carrier rotationally supporting the planet gears for rotation about the planet axes, the planet carrier being axially displaceable along the central axis; and a carrier forcing device arranged to force the planet carrier along the central axis in the conical direction. A gearbox for an industrial robot, the gearbox including a planetary gear train, and an industrial robot including a planetary gear train or a gearbox, are also provided.

The system can include a set of joints, a controller, and a model engine; and can optionally include a support structure and an end effector. Joints can include: a motor, a transmission mechanism, an input sensor, and an output sensor. The system can enable articulation of the plurality of joints.

A driving force transmission device includes an input section and an output section with rotation axes nonparallel to each other to avoid backlash. A driving force transmission device (1) includes a first rotator (2), a second rotator (3), and spheres (5A, 5B, 5C). The first rotator (2) performs one of an input operation and an output operation of a driving force and includes a concave surface (7). The second rotator (3) performs the other of the input operation and the output operation of the driving force and includes a convex surface (13) fitted into the concave surface (7). The spheres (5A, 5B, 5C) are between the concave surface (7) and the convex surface (13). The concave surface (7) has holes (32A, 32B, 32C) in which the respective spheres (5A, 5B, 5C) are received. The convex (13) surface has a groove (29, 30) that receives parts of the spheres (5A, 5B, 5C) protruding from the holes (32A, 32B, 32C).

The present application discloses a robotic control system, and a method and a computer system for controlling a robot. The robotic control system includes a memory and one or more processors coupled to the memory. The memory is configured to store configured to store a model of a robot having a plurality of axes of control including at least a linear axis and one or more rotational axes. The one or more processors are configured to use the model to control the robot to perform a task, including by sending to the robot a set of control signals to cause the robot to move with respect to two or more of said axes of control including at least the linear axis.