A direct drive brushless motor including a plurality of rotational components and a plurality of non-rotational components. Ones of the pluralities of rotational and non-rotational components form a dual magnetic circuit. The plurality of rotational components includes a center rotation shaft circumscribed by a plurality of coils and a coil termination plate configured to support the plurality of coils. The plurality of non-rotational components includes a plurality of outer magnets arranged around the plurality of coils in a Halbach configuration and a plurality of inner magnets arranged in a Halbach configuration between the coils and the shaft. A flex cable having one or more leads provides electrical current to the plurality of coils without the use of brushes.

A robot includes a movable unit and a driving unit that drives the movable unit. The movable unit includes a predicted colliding section that is a structure forming an outer shape of the movable unit and may collide with a human body during movement of the movable unit. The predicted colliding section is formed to have a predetermined shape such that a pressure applied to a human body is lower than a predetermined safety standard value for pressure for the human body when the movable unit is driven at maximum thrust by the driving unit and collides with the human body.

A control system is provided for controlling movements of an end effector connected to a clutch output of at least one magnetorheological (MR) fluid clutch apparatus. A clutch driver is configured to drive the at least one MR fluid clutch apparatus between a controlled slippage mode, in which slippage between a clutch input and the clutch output of the MR fluid clutch apparatus varies, and a lock mode, in which said slippage between the clutch input and the clutch output is maintained below a given threshold, the clutch output transmitting movement to the end effector. A motor driver is configured to control a motor output of at least one motor, the motor output coupled to the clutch input. A mode selector module is configured to receive signals representative of at least one movement parameter of the end effector, the mode selector module selecting a mode between the controlled slippage mode and the lock mode of the clutch driver based on the signals, and switching the selected mode based on the signals. A movement controller controls the clutch driver and the motor driver to displace the end effector based on at least one of the selected mode and on commanded movements of the end effector for the end effector to achieve the commanded movements. A method for controlling movements of an end effector connected to the MR fluid clutch apparatus is also provided.

A monitoring device of a robot system including: a current sensor detecting a value of a current flowing through the servo motor; a current/torque converting the value of the current flowing through the servo motor which is detected by the current sensor into a torque value; a driving torque estimating section estimating at least a part of driving torque required to drive the servo motor; a differential torque calculating differential torque between the torque value obtained by conversion in the current/torque converting section and an estimated value of the driving torque; an external force converting the differential torque calculated by the differential torque calculating section into an external force applied to the robot; and a stop signal generating section which generates to stop the robot based on a value of the external force obtained by conversion in the external force converting section, and supplies the stop signal to the controller.

A robotic tool has a longitudinal shaft, defining a longitudinal axis when the shaft is in a default, centered position. A lockout rod is moveable between first and second positions. In the first position, the lockout rod allows the longitudinal shaft to move with 360 radial degrees of compliance about the longitudinal axis. In the second position, the lockout rod limits compliance of the longitudinal shaft to only one radial angle from the longitudinal axis. In one embodiment the lockout rod is positioned adjacent (e.g., above or below) part of one ring of a 2-axis concentric ring gimbal. The lockout rod is shaped so as to not contact any part of the gimbal in the first position, allowing compliance in a full 360 radial degrees. In the second position, the lockout rod limits the motion of one ring of the gimbal, limiting compliance of the shaft to motion of the other ring, which is necessarily limited to only one radial angle. In one embodiment the lockout rod is shaped and position such that it moves between the first and second positions by rotational motion about its own longitudinal axis.

A compensating device, which can be placed between a robot, e.g., used to grip and position workpieces, and a gripper moved by the robot to compensate position tolerances, includes respective interfaces for a manipulator and an end effector, with the compensating device positioned between the manipulator and the end effector and including a joint device aligned with a first axis Z between the interface segments, a first joint partner connected to the first interface segment, and a second joint partner connected to the second interface segment, one of the joint partners including a ball segment and the other including, for the ball segment, a receptacle segment that includes at least one ramp region so that the joint device forms a pivot or ball joint, the ball segment being capable of being displaced from a normal position in a transverse direction X-Y to the first axis Z into a compensating position.

During an operation of a mobile robot 1, observed values of a plurality of reference parameters including at least one of contact reaction forces) of one or more movable links 3, 4 and a contact reaction force function value expressed as a function value of contact reaction force(s) of one or more movable links 3, 4 are acquired based on outputs from force detectors 31 mounted on the respective movable links 3, 4 of the mobile robot 1, and the observed values of the reference parameters are used to detect presence or absence of occurrence of abnormal contact of the mobile robot 1 by a contact detecting model Ai.

A robot includes a movable part having a first internal space, a shock-absorbing section disposed outside the movable part, and having a second internal space, and a state switching section capable of switching between a first state of supplying a fluid from a fluid supply source to the first internal space and a second state of supplying the fluid from the fluid supply source to the second internal space. Further, the state switching section includes a first flow channel adapted to supply the fluid from the fluid supply source to the first internal space, a second flow channel adapted to supply the fluid from the fluid supply source to the second internal space, and a valve capable of adjusting opening/closing degrees of each of the first flow channel and the second flow channel.

A gripper system for a robot includes a first gripper element for carrying an object. The first gripper element includes a gripper hand with a support plane for supporting the object and a gripper thumb opposing the support plane. The first gripper element also includes a slot between the gripper hand and the gripper thumb for allocating at least part of the object to passively secure the object from tilting. This gripper system is advantageous when moving around carrying an object such as a tray or plate on which articles are loosely positioned.

In an apparatus for detecting a collision of a handling device with an obstacle, comprising at least one gas-filled chamber, which is surrounded by a flexible sheath that is deformable by collision with an obstacle and has a flexible supporting structure, wherein the supporting structure forms a damping element, which, together with the sheath, mechanically damps the forces that act in the event a collision, and also comprising a pressure sensor for measuring the gas pressure inside the chamber, wherein the apparatus is able to be attached to the handling device in a manner covering at least a first and a second region of the handling device, the sheath and the supporting structure are formed in one piece with one another and provide different degrees of damping from one another in the first and the second region.