A lower limb rehabilitation training robot is provided, which includes a bedstead support and a rising bedstead arranged on the bedstead support, and further includes a linear motion device, a push rod device, a bionic leg arranged at one end of a surface of the rising bedstead and hinged to the rising bedstead, and a bed board configured to support a patient and arranged at another end of the rising bedstead. The linear motion device is arranged between the bedstead support and the rising bedstead, is configured to allow the rising bedstead to slide along the bedstead support, and has one lateral surface connected to the bedstead support and another lateral surface hinged to the rising bedstead. The push rod device is configured to drive the rising bedstead to rotate around a hinge point where the rising bedstead is hinged to the linear motion device.

An apparatus including a robot arm comprising a wrist, and an end effector. The wrist includes a frame member. The frame member includes a first material having a first coefficient of thermal expansion. The end effector is connected to the wrist at a connection. The end effector is configured to support a substrate thereon. The end effector includes a first member and a second member. At least one of the first and second members has a different second material with a different second coefficient of thermal expansion. The connection includes the first and second members being stationarily attached to each other with a portion of the frame member sandwiched therebetween. The connection is configured to substantially prevent the different respective coefficients of thermal expansion to deflect the end effector relative to the wrist when the end effector and wrist are heated and/or cooled.

A robotic attacher includes a main arm that is suspended vertically from a rail, and a supplemental arm that is coupled to and extends horizontally from the main arm along a longitudinal axis. The supplemental arm includes a pivot assembly that pivots a gripping portion around a vertical axis that is substantially parallel to the main arm of the robotic attacher, in a direction transverse to the longitudinal direction of the supplemental arm, and between at least a maximum-left position, a maximum-right position, and a centered position. The pivot assembly includes a first actuator that extends and retracts a first cable coupled to a left side of the gripping portion in order to pivot the gripping portion. The pivot assembly further includes a second actuator that extends and retracts a second cable coupled to a right side of the gripping portion in order to pivot the gripping portion.

A modular tooling receiver includes a housing having a wall and a port, and an engaging member movably disposed in the port. A lock actuator is moveable between a first position and a second position. The release lever is connected to the housing and is engageable with the lock actuator for causing movement of the lock actuator from the first position toward the second position. An anti-release mechanism is connected to the release lever and is movable between an engaged position, in which the anti-release mechanism engages the housing to restrain movement of the release lever to prevent movement of the lock actuator from the first position to the second position, and a disengaged position, in which the anti-release mechanism disengages the housing to allow movement of the release lever.

Techniques for torque compensation include a system include actuating means coupled to a clamping means and processing means. The processing means is configured to acquire an initial torque limit for the clamping means; adjust the initial torque limit based on an angle of a wrist of the clamping means to obtain an adjusted torque limit; and drive, subject to the adjusted torque limit, the actuating means to cause the clamping means to clamp a material.

Exemplary embodiments relate to user-assisted robotic control systems, user interfaces for remote control of robotic systems, vision systems in robotic control systems, and modular grippers for use by robotic systems. The systems, methods, apparatuses and computer-readable media instructions described interact with and control robotic systems, in particular pick and place systems using soft robotic actuators to grasp, move and release target objects.

A robot arm includes a wrist, an end effector, and an adjustable joint coupling the end effector to the wrist. The adjustable joint includes a member received in a socket. In one example, the member is a ball. In another example, the member is a tang. In both examples, an upper flange and a lower flange can be used to couple the wrist to a forearm.

A programmable motion system is disclosed that includes a dynamic end effector system. The dynamic end effector system includes an end effector that is coupled via a dynamic coupling to the programmable motion system, wherein the dynamic coupling provides that at least a portion of the end effector may spin with respect to an other portion of the end effector.

An industrial robot with parallel kinematics is proposed which is equipped with a robot base (1), a carrier element (2) for receiving a gripper, a tool or a machine element, at least two moveable actuating units (4), one of which ends is connected to actuating-unit drives (6) arranged on the robot base (1) and the other end is moveably connected to the carrier element (2), a telescope (13) that is moveably arranged between the robot base (1) and the carrier element (2), a first joint (17) with multiple degrees of freedom, by means of which joint the telescope (13) is moveably held on the robot base (1), a second joint (23) with multiple degrees of freedom, by means of which joint the telescope (13) is moveably held on the carrier element (2), whereby the position of the first joint (17) can be displaceably arranged relative to the robot base (1).

A direction-adjustable jig is capable of translating an artifact between two mutually perpendicular planes in a three-dimensional space. The jig includes a base, a sliding member, and a hinge member. The base has a pair of side walls each having a first guiding portion. The first guiding portion has a lower guiding portion and an upper guiding portion in communication with each other. The lower guiding portion and the upper guiding portion are formed at different height vertically. The sliding member is disposed reciprocatingly on the base and in between the side walls. The hinge member is pivotally connected to the sliding member and has a pair of second guiding portions for engaging the first guiding portions. The reciprocating motion of the sliding member allows the hinge member to rotate above the base and change its direction.