A robot casing includes, in a hollow resin body portion, two attachment openings and one work opening that communicate between an inside and an outside of the body portion. The two attachment openings are respectively provided in both end portions of the body portion; a metal member constituting an attachment surface is embedded in a resin constituting the body portion at a periphery of the attachment opening; the metal member is provided with attachment holes that allow attachment screws, which are used for attachment to the attachment surface, to penetrate therethrough or to be fastened thereinto, and is also embedded in the resin in a state in which the attachment surface is exposed; and components can be respectively attached to the two attachment openings by utilizing the work opening.

Various examples are provided related to pneumatic soft robotic spiral grippers. A fiber optic sensor can enable spiral-gripper sensing of, e.g., atwining angle and target cylinder diameter. In one example, a pneumatic soft robotic spiral gripper includes an elastic spine with an embedded fiber optic sensor and a pneumatic spiral channel twining around the elastic spine. The pneumatic spiral channel can be formed in a soft gripping material surrounding the elastic spine. In another example, a method fabrication of a pneumatic soft robotic spiral gripper includes providing a gripper mold with an outer mold wall and a spiral shaped rod positioned within the outer mold wall. An elastic spine can be inserted through the spiral shaped rod and the gripper mold filled with gripping material that can be cured to form a soft gripping material surrounding the elastic spine.

A robot system includes a robot having an arm pivoting about a pivot axis (first pivot axis), a motor (first motor) pivoting the arm, a shaft (spline shaft) coupled to the arm and moving in an axial direction of a linear motion axis parallel to the pivot axis, and an inertial sensor provided in the arm or shaft, and a control apparatus having a control unit controlling the motor, wherein the inertial sensor detects an angular velocity about a roll axis orthogonal to the pivot axis and the linear motion axis or an acceleration in a tangential direction of a circle around the roll axis, and the control unit controls the motor based on information representing a pivot direction of the arm about the roll axis when the arm stops or decelerates and output from the inertial sensor.

In variants, a method for robot control can include: receiving sensor data of a scene, modeling the physical objects within the scene, determining a set of potential grasp configurations for grasping a physical object within the scene, determining a reach behavior based on the potential grasp configuration, determining a trajectory for the reach behavior, and grasping the object using the trajectory.

An actuatable joint for a robotic system has a body, a motor positioned in the body, an output shaft configured to be rotated by the motor relative to the body, and a bearing assembly positioned between the output shaft and the body and configured to support the rotation of the output shaft. The bearing assembly has a first axial angular contact roller bearing. The roller bearing has a pair of frusto-conical bearing rings forming a pair of parallel races, a bearing cage positioned between the pair of bearing rings and including a plurality of openings, and a plurality of rollers positioned in the openings and in contact with the races.

An articulating assembly of a robotic system has an extruded connector arm including a longitudinally-extending body portion and a connection portion. The body portion has an axial base member, a perimeter wall, and a plurality of webs extending radially from the base member to the perimeter wall. The robotic system may also have an actuatable joint secured to the connection portion of the connector arm. The connector arm may be cut-to-size and replaceable, thereby forming a modular component for the robotic system.

A robot with an impact buffering member on the surface of a robot arm for alleviating the impact when the arm contacts an object; and a contact detection unit for detecting a contact between the robot arm and object. The unit has a soft porous member on the front surface side of the impact buffering member and softer than the member; a housing member including the soft porous member and formed of a flexible material; a fluid discharge pipe for discharging a fluid inside the housing member when the object makes contact so the volume of the housing member decreases; and a volume change detection portion for detecting a change in volume of the housing member by utilizing the discharged fluid. It is possible to secure sufficient safety in a cooperative work between a person and a robot or the like, even when the person contacts the robot arm.

This application describes multi-stage stop devices for robotic arms. During a first stage, rotational motion of a link of a robotic arm compresses a compressible member of the multi-stage stop device to absorb and dissipate at least some of the force generated by the collision. A second stage provides a hard stop the stops any further rotation. The multi-stage stop devices described herein can include a collapsing pin configured to compress a compressible member during the first stage. After the pin has collapsed a rigid sidewall provides a hard stop preventing further rotation during the second stage.

An apparatus including a plurality of robot arm links movably connected to one another, where a first one of the robot arm links includes a frame, where the frame has a first end movably connected onto a second one of the robot arm links; and at least one vibration damper arrangement on the frame of the first robot arm link, where the at least one vibration damper arrangement includes at least one viscoelastic element connected to the frame of the first robot arm link by a connection such that, as the frame of the first robot arm link experiences vibrations, the at least one viscoelastic element dampens the vibrations in the frame of the first robot arm link based upon viscoelasticity and the connection of the at least one viscoelastic element to the frame of the first robot arm link.

An end-of-arm tool is described and includes an outer sheet and an inner sheet. The end-of-arm tool may be reinforced with a backing plate attached to the inner sheet and a front plate attached to the outer sheet. The end-of-arm tool may also include spacers to provide structure and rigidity to the end-of-arm tool at passages configured for the installation of workpiece interface tools, for example, spring plungers.