A robot control device able to accurately estimate an external force applied from a workpiece to a robot in a time-dependently changing manner. The robot control device includes a support force data acquisition section which acquires measurement data of a workpiece support force by the environment, the workpiece support force varying while the robot lifts the workpiece; a disturbance estimation section which estimates a disturbance value applied to the robot using state information of the robot; and a correction section which corrects, using the measurement data acquired by the support force data acquisition section, the disturbance value estimated by the disturbance estimation section or the state information inputted to the disturbance estimation section.

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.

In a gripping device including carriages disposed on a base body so as to be movable relative to each other by a motor drive, the carriages being provided with gripping elements which are movable with the carriages between an opening and a closing position of the gripping elements, at least one of the gripping elements is supported on the respective carriage so as to be able to yield to a certain engagement pressure force which is adjustable in the range of 5 to 300 N in order to prevent excessive damage or injuries-causing engagement forces.

A displacement measurement device includes a first structure, a second structure, and a coupling portion configured to couple the first structure with the second structure. The first structure includes a first sensor configured to generate an electrical signal corresponding to displacement between a first attachment portion of the first structure and a second attachment portion of the second structure in the at least one first direction. The second structure includes a second sensor configured to generate an electrical signal corresponding to displacement between the first attachment portion and the second attachment portion in the at least one second direction.

This invention comprehensively detects an operational abnormality caused by a disturbance factor such as contact of a robot arm. A robot device according to the present embodiment is equipped with an articulated arm mechanism, and includes: a plurality of links; a plurality of joints interconnecting the plurality of links; a plurality of motors that generate motive power for driving the plurality of joints; a transmission mechanism that transmits rotation of a drive shaft of a motor of at least one joint among the plurality of joints to a rotary shaft of the at least one joint; a first encoder that detects rotation of the drive shaft of the motor of the at least one joint; a second encoder that detects rotation of the rotary shaft of the at least one joint; and a determining section that determines an operational abnormality based on an encoder pulse that is output from the first encoder and an encoder pulse that is output from the second encoder.

A safety device for a mechanical motion device and a method for protecting a person or object in the vicinity of a mechanical motion device are described herein. The safety device may include: a shroud; a coupling mechanism; and a detection device. The coupling mechanism joins the shroud in a displaceable manner to a mechanical motion device. The detection device is configured for communication with the safety control system of a mechanical motion device. The detection device is capable of detecting misalignment of the shroud from its initial aligned position and/or a collision between the shroud and a person or object. The detection device may send a signal to the safety control system of the mechanical motion device to at least slow the movement of the mechanical motion device before the mechanical motion device reaches the location of the collision of the shroud with an object or person.

A production system includes a robot, a robot controller, and a person detection part. The controller includes first speed comparison unit that has the function of activating a power cutoff unit so as to stop an operation of the robot when a current speed exceeds a predetermined reference speed; and an external-force comparison unit that has the function of activating the power cutoff unit so as to stop the operation of the robot when a current force applied to the robot exceeds a predetermined reference force. The controller disables the functions of the first speed comparison unit and the external-force comparison unit while the person detection part detects the absence of the operator in the cooperative operation space.

A safety control device for releasing an operation of a machine, in particular a robot, includes an input device for detecting a manual contact, in particular a finger contact. The safety control device has a retaining device for securing the input device to a finger, in particular a fingertip, of an operator, in particular in a frictional manner, and/or a signaling means for outputting a signal, in particular an optical, acoustic, tactile, thermal, and/or electric signal, if a contact force detected by the input device is smaller than a specified upper minimum value and/or for outputting a signal, in particular the same signal or a different signal, in particular an optical, acoustic, tactile, thermal, and/or electric signal, if a contact force detected by the input device is greater than a specified lower maximum value.

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 robotic transport system including a drive section connected to a frame, an articulated arm operably coupled to the drive section providing the articulated arm with arm motion in at least one axis of motion moving at least a portion of the articulated arm in a collaborative space, corresponding to the frame, from a first location to another different location in the collaborative space, the articulated arm having an end effector with a workpiece grip having workpiece engagement members engaging and holding a workpiece during workpiece transport, by the arm motion in the at least one axis of motion, wherein at least one of the workpiece engagement members is frangible compliant, having a frangible compliant coupling between a distal portion of the at least one of the workpiece engagement members and a base portion of the end effector from which the at least one of the workpiece engagement members depends.