The present disclosure provides a biologically-inspired robotic device comprising: a first member; a second member pivotably connected to the first member; one or more actuators; and a coupler/decoupler mechanism (CDC) selectively coupling or decoupling of the one or more actuators to the second member, such that, when the one or more actuators are coupled to the second member, the one or more actuators act to pivot the second member relative to the first member.

A robot includes a support, a movable member coupled to the support to permit gimbal rotation about a pitch axis and a yaw axis, and first and second linear actuators connected to each of the support and the movable member and operable to rotate the movable member about the pitch axis and the yaw axis. The first linear actuator is pivotally attached to the movable member at a first pivot point. The second linear actuator is pivotally attached to the movable member at a second pivot point. The first and second pivot points are each angularly offset from the pitch axis and the yaw axis by about 45 degrees and are located on the same side of the pitch axis.

A piezoelectric driving device includes a substrate, a plurality of piezoelectric elements disposed on the substrate, a first groove section provided between the plurality of piezoelectric elements, and a first wire provided in at least a part of a side surface and a bottom section of the first groove section.

One or more embodiments of a continuum robot may include a bendable body having linear members provided along a first pitch circle, and motors respectively having output shafts provided along a second pitch circle offset outside from the first pitch circle and being configured to respectively drive linear members to bend the bendable body; intermediate supporting shafts provided along a third pitch circle offset outside from the first pitch circle and offset inside from the second pitch circle; first connection members respectively connecting end portions of the linear members and the intermediate supporting shafts to each other; and second connection members respectively connecting the intermediate supporting shafts and the output shafts to each other and configured to convert rotation of each of the output shafts into rectilinear motion to cause each of the intermediate supporting shafts to rectilinearly move.

A workpiece conveying system for a transfer press machine includes: a beam provided to extend in a feed direction of a workpiece; and a plurality of workpiece conveying apparatus supported by the beam. The workpiece conveying apparatus each include: a feed device including a first carrier that is movable relative to the beam in the feed direction; a raising and lowering device including a second carrier that is movable relative to the first carrier in a raising and lowering direction; a clamp device including a third carrier that is movable relative to the second carrier in a clamp direction of the workpiece; and a workpiece holding tool, which is supported at a distal end of the third carrier, and is configured to hold and release the workpiece.

A robotic actuator may include a series elastic actuator (SEA) that includes an elastic element made of a viscoelastic material. The viscoelastic material may have hardness, stiffness, hysteresis, or damping properties suitable for a particular robotic application. The elastic element may include two portions of the viscoelastic material in compression with each other in the SEA. The SEA may include a motor to generate mechanical power, a speed reduction element to amplify motor torque, an encoder to measure deflection of the viscoelastic elastomer due to an applied force, and a transmission mechanism. The transmission mechanism may be connected to the motor using a pulley and may route mechanical power to an output joint. The SEA may be a prismatic SEA or another type of linear actuator. The motor may include a 3D printed liquid cooling jacket that includes removable fluid seals and that is assembled and disassembled using removable screws.

A manipulator including a shaft driven by a first motor, a rotatable unit, a linear slider, and a gripper is provided. The rotatable unit is coupled to the shaft, wherein the rotatable unit rotates with rotation of the shaft. The linear slider disposed on a first surface of the rotatable unit configured to slide from an initial position proximate to an outer edge of the rotatable unit to intermediate positions and to a final position proximate to a center of the rotatable unit. The gripper coupled to the linear slider to facilitate movement of the gripper along a first plane defined by the first surface of the rotatable unit.

The disclosure describes devices, systems and methods relating to a transfer chamber for an electronic device processing system. For example, a method includes causing a robot arm to pick up a substrate. The robot arm is caused to pick up the substrate by causing a first mover to rotate or to change a first distance to a second mover. Rotation of the first mover or the change in the first distance causes the first robot arm to rotate about a shoulder axis. The robot arm is further caused to pick up the substrate by causing one of a) a second mover to rotate or b) a third mover to change a second distance to the second mover. Rotation of the second mover or the change in the second distance causes the robot arm to raise or lower.

Provided is a driving control apparatus that can control relaxation of force in an actuator. The driving control apparatus is provided with: a driving control unit configured to control driving of the actuator according to a driving control signal; and a pressure control unit configured to control, according to a pressure control signal, involvement of the driving control signal in control of pressure to be generated by the actuator.

A device includes a housing. An actuator is disposed within the housing. The actuator includes an actuator arm extending from the housing. A motor controller is disposed within the housing to control the actuator. A network input/output device is configured to communicate with a computer device over a communications network. The actuator is controlled remotely by one or more commands received from the computer device.