A robot control system according to an embodiment is a control system for a robot comprising an arm, the arm being capable of holding a tool while rotating the tool and capable of moving the tool in at least two-dimensional directions, the arm being equipped with a rotating mechanism provided for the tool. The robot control system comprises a load-acquiring unit and a control-signal-generating unit. The load-acquiring unit is configured to acquire a force measured by a force sensor configured to measure a force applied from the tool to the arm during profile copying performed on a machining object by moving the arm while a copying guide attached to the arm and a copying mold placed on the machining object are kept in contact with each other. The control-signal-generating unit is configured to automatically control the arm by generating a control signal for the arm in accordance with the force acquired by the load-acquiring unit and with control information for the arm regarding the profile copying, and by outputting the control signal to the arm.

A robot unit includes a robot body which is an arm-type robot having a plurality of arms coupled via joints, and in which one or more connecting portions are provided on a surface of at least one of the arms, and one or more auxiliary parts which are attachable and detachable to and from the arms via the connecting portions and which control or support movement of at least one of the joints.

A robotic tool changer includes a locking mechanism that enhances safety. More particularly, the locking mechanism is an over center locking mechanism that maintains a constant lock force on a tool. The lock force exerted on the tool by the locking mechanism remains substantially constant, even after a motor providing power to the robotic tool changer is removed, and after the robotic tool changer experiences mechanical wear.

A robotic system includes a robotic arm and a movable hardstop disposed proximate to the robotic arm. The movable hardstop is separated from the robotic arm by at least one clearance in a first operating condition. The movable hardstop physically contacts the robotic arm in a second operating condition. The robotic system also includes one or more controllers configured to control movement of the robotic arm and movement of the movable hardstop such that the first operating condition is maintained or such that, if the second operating condition occurs, the hardtop blocks movement of the robotic arm.

A robot arm includes a mechanical stop device having at least one counter-stop body having a shape, which, in interaction with a respective corresponding shape of a receptacle, is designed to retain the counter-stop body whenever the counter-stop body is inserted in one of a plurality of the receptacles. The receptacle retains the counter-stop body in both a circumferential direction and in a radial direction with respect to the axis of rotation of a swivel joint, in a form-fitting manner.

A horizontal articulated robot includes a base, a first arm supported by the base to be pivotable in a horizontal direction, a second arm supported by the first arm to be pivotable in the horizontal direction, a shaft supported by the second arm to be linearly movable along a longitudinal axis in a vertical direction, and a stopper mounted to the shaft and limiting movement of the shaft within a movable range. The stopper includes a fixing section fixed to an outer circumferential surface of the shaft and protruding therefrom, and a shock absorbing section fixed to one of the fixing section and the second arm. The shock absorbing section is disposed in a position sandwiched by the fixing section and the second arm in the vertical direction, and is elastically compressed in the vertical direction when the shaft tries to move beyond the movable range.

Provided is a robot to which is disposed a cartilage vibration-transmission source, the robot being configured so that both hands of the robot are lain onto the face of a person or hold the back of the head, or so that one hand touches the cartilage of the ear. The relative positions of both hands touching the cartilage of both ears are maintained, but movement of the face is not restricted. The hands of the robot extend in the line-of-sight direction of the robot. The mouth of the robot is caused to move in conjunction with cartilage transmission audio. A limiter is applied to the touch pressure of the hands. Permission is sought before touching. Safety is confirmed before touching. When a malfunction occurs, touching with the hands is cancelled. The hands are warmed to the temperature of the human body.

The invention relates to a robot arm having at least two limbs (2), which are connected to one another at their ends via an articulated joint (10) so that they can be pivoted relative to one another about a rotation axis (A), the two limbs (2) each comprising at least one joint portion (3) and a transition region (4) adjoined thereto and each extending in a longitudinal direction (L). According to the invention, the transition region (4) of at least one of the limbs (2, 2a) has a circumferential edge (6) which, when viewed from a direction running transverse to the rotation axis (A) and transverse to the longitudinal direction (L), crosses a parting line (9) between the two joint portions (3) and runs at a predefined distance radially outside the joint portion (3) of the other limb (2), the circumferential edge (6) running at a distance, in relation to the rotation axis (A), of less than 25 mm outside the surface of the joint portion (3) of the other limb (2) arranged beneath. In addition, a portion of the circumferential edge (6) extends obliquely to the rotation axis (A) when viewed from a direction running transverse to the rotation axis (A) and transverse to the longitudinal direction (L).

An example rotational joint assembly for a robotic medical system, the rotational joint assembly comprising at least one arm segment and a rotational joint provided at one end of the arm segment. The rotational joint is to allow the arm segment to rotate about a rotational axis. The rotational joint comprising a brake to lock rotation of the arm segment at the rotational joint and an actuator to selectively engage or disengage the brake. The actuator comprising a cam having two stable regions separated by two transition regions, the two stable regions comprising a first stable region corresponding to engagement of the brake and a second stable region corresponding to disengagement of the brake.

A leg assembly and a legged robot having same are provided. The leg assembly includes a first leg, a second leg, a motor, an output flange and a transmission component. The motor is arranged at a first end of the first leg, and an output shaft of the motor is connected to the output flange to drive the output flange to rotate. The first leg is pivotably connected to the second leg, and the transmission component is connected to the output flange and the second leg to drive the second leg to rotate relative to the first leg. The output flange is provided with a first limiting portion, the first leg is provided with a first stop portion and a second stop portion spaced apart and configured to stop the first limiting portion, and the first leg is provided with a second limiting portion configured to stop the second leg.