A robot system includes a track that extends along an axis between a first location and a second location. The track includes a pair of rails and a power transmitter and a radiating cable each extending along the track. A carriage is configured to convey a robot arm along the track. The carriage includes a plurality of wheels configured to roll along the pair of rails, a motor configured to drive at least one of the wheels along one of the rails, a power collector configured to translate along the power transmitter while maintaining contact with the power transmitter so as to conduct electrical power from the power transmitter to the motor, and a transceiver configured to receive and send electronic information from and to the radiating cable.

An apparatus includes a platform configured to traverse a stationary base along a motion path; a drive coupled to the platform; and a movable arm assembly. The movable arm assembly includes a pivoting base connected to the drive, first and second linkages connected to the pivoting base, each linkage having links connected via rotary joints and each link having at least one end-effector. The platform is configured to traverse the stationary base along a motion path in two opposing directions and the drive and the movable arm assembly are configured to cause independent and simultaneous movement and transfer of substrates from at least one of a first substrate holding area, a second substrate holding area, a third substrate holding area, or a fourth substrate holding area into or from a respective substrate workstation.

A robotic arm system comprising a deployment system or a base, a first joint, and a manipulator coupled to the deployment system or base at the first joint and movable relative to the deployment link or base about the first joint. The manipulator includes a manipulator link, a second joint coupled to the manipulator link distal from the first joint, an elevation linkage coupled to the manipulator link at the second joint, a wrist coupled to the elevation linkage distal from the second joint, and an end effector coupled to the wrist. The end effector can change elevation via the elevation link without changing orientation.

Robotic arms and surgical robotic systems incorporating such arms are described. A robotic arm includes a roll joint connected to a prismatic link by a pitch joint and a tool drive connected to the prismatic link by another pitch joint. The prismatic link includes several prismatic sublinks that are connected by a prismatic joint. A surgical tool supported by the tool drive can insert into a patient along an insertion axis through a remote center of motion of the robotic arm. Movement of the robotic arm can be controlled to telescopically move the prismatic sublinks relative to each other by the prismatic joint while maintaining the remote center of motion fixed. Other embodiments are also described and claimed.

Provided is a robot system. The robot system includes a guide rail, a slider configured to move along the guide rail, a first source disposed the slider to move together with the slider, a rotation arm configured to rotate by the first driving source, and a vehicle service robot installed the rotation arm to move by the rotation arm.

Robotic arms and surgical robotic systems incorporating such arms are described. A robotic arm includes a roll joint connected to a prismatic link by a pitch joint and a tool drive connected to the prismatic link by another pitch joint. The prismatic link includes several prismatic sublinks that are connected by a prismatic joint. A surgical tool supported by the tool drive can insert into a patient along an insertion axis through a remote center of motion of the robotic arm. Movement of the robotic arm can be controlled to telescopically move the prismatic sublinks relative to each other by the prismatic joint while maintaining the remote center of motion fixed. Other embodiments are also described and claimed.

The disclosure concerns a pivoting unit for a handling robot for opening a flap (e.g. door) of a motor vehicle body, comprising a mounting flange, a gripper arm and a first gripping tool for gripping an engagement on the flap to be opened, the first gripping tool being mounted on the gripper arm, and a pivoting head for pivoting the gripper arm between an initial position and an engaged position. The disclosure provides that a second gripping tool is also mounted on the gripper arm, and that the two gripping tools on the gripper arm are adapted to be inserted in different insertion directions into engagement with the openable flap of the motor vehicle body, in particular from top to bottom for the first gripping tool and from bottom to top for the second gripping tool. The disclosure further comprises an associated method.

A locking system for a continuum arm robot system, the robot system includes: a continuum arm robot having a manipulatable tip, a passive robot section through which controls for the manipulatable tip, and at least one ferromagnetic collar, and at least one external controllable electromagnetic device which can be activated so that the ferromagnetic section on the continuum arm robot is attracted to the electromagnetic device.

Production system including a rail extending horizontally, and an articulated robot that is self-travelable along the rail parallel to an extending direction of the rail. The robot includes a carriage having at least one operating shaft configured to be driven by a servomotor and to self-travel along the rail, a slider projecting toward the rail from the carriage and configured to releasably engage with the rail, a robotic arm supported by the carriage and having at least one operating shaft driven by a servomotor and constitutes a joint, an end effector provided to a tip-end of the robotic arm, and a control unit inside the carriage configured to control the operating shafts of the robotic arm and the carriage so a control point defined in the robotic arm or the end effector reaches a target position by a collaboration of the operating shafts of the robotic arm and the carriage.

A robot includes: a manipulator that is provided with an n-th (n is an integer of 1 or larger) arm which is capable of rotating around an n-th rotation axis, an (n+1)-th arm provided on the n-th arm to be capable of rotating around an (n+1)-th rotation axis having an axial direction which is different from an axial direction of the n-th rotation axis, and an (n+2)-th arm provided on the (n+1)-th arm to be capable of rotating around an (n+2)-th rotation axis. In a first state, an outline of the manipulator is positioned on an inner side of a first circle or on the first circle with the n-th rotation axis as the center thereof, and with first length between a distal end of the manipulator and the n-th rotation axis, as a radius, when viewed in the axial direction of the n-th rotation axis.