A workpiece conveyance device includes a base body disposed adjacent to a press machine, a pair of first arms, a pair of second arms, and a first holding portion and a second holding portion independent of each other. Each of the first holding portion and the second holding portion includes a plurality of holding members configured to hold a workpiece W. The first holding portion includes a first support member, a second support member, and an absorption member. The second support member movably supports the first support member along an intersection direction. The absorption member allows movement of the second support member caused in the intersection direction relative to the first support member, and makes it possible for the second support member to return to an initial position in the intersection direction relative to the first support member.

An end effector assembly for a picking robot, and a tool unit is disclosed, the end effector assembly comprising a first end effector part, a second end effector part, and an end effector device mounted on the second end effector part, wherein the first end effector part and the second end effector part are connected via a joint connection comprising a first joint having at least a first degree of freedom, the joint connection comprising a first spring construction having a first end and a second end, the first end connected to the first end effector part and the second end connected to the second end effector part.

A variable stiffness joint and method to alter the stiffness of the joint with multiple stiffness levels is described wherein a plurality of stiffness bits (m) are used for enabling 2 m stiffness level variations for the joint. Each stiffness bit comprises an elastic element in mechanical connection with a clutch (21, 22, 23). The joint revolves with zero stiffness level when all the clutches (21, 22, 23) are disengaged whereas a clutch (21, 22, 23) involves one of the elastic elements which alter the stiffness of the joint. Engaging other clutches (21, 22, 23) involve more elastic elements for altering the joint stiffness and the resultant joint stiffness is determined by adding the stiffness values of all the involved springs (6, 7, 8).

A sensing manipulator of an articulated arm is disclosed. The sensing manipulator includes a compliant section and a movement detection system provided along a first direction of the compliant section such that movement of the compliant section along both the first direction and at least one direction transverse to said first direction, are detectable by the movement detection system.

A roll joint is provided. The roll joint may comprise: a first body; a second body disposed opposite to and spaced apart from the first body; a connection body which is disposed between the first body and the second body and is not in contact with the first body and the second body; and a connection wire member which connects the first body, the second body, and the connection body to one another so as to make a tensegrity structure.

A clamping jaw of a connecting terminal includes a rotary cylinder assembly configured for achieving different swing angles for clamping different types of connecting terminals. The rotary cylinder assembly includes a rotating shaft for providing a driving force through rotating cylinder and an initial state limit part. A first state limit part is configured to position the rotating cylinder in a first rotation angle and a second state limit part has a working and non-working position. When the second state limit part is in the working position, it is configured to position the rotating cylinder in a second rotation angle. When the second state limit part is in the non-working position, it is configured to position the rotating cylinder in the first rotation angle. The second rotation angle is smaller than the first rotation angle.

A rotary-type series elastic actuator (SEA) for use in robotic applications. The SEA including a motor, gear transmission assembly, spring assembly, and sensors. In one example, a robotic joint may include the SEA as well as two links coupled with each other at the joint assembly. The two links may be designated as input and output links. Each link may have a joint housing body which may be concentrically connected via a joint bearing so that they freely rotate against each other. The housing frame of the SEA may be fixed at the joint housing body of the input link while the output mount of the spring assembly of the SEA may be concentrically coupled with the joint housing body of the output link. The rotation of the motor rotor causes the rotation of the output link with respect to the input link plus spring deflection of the spring assembly. When an external force or torque are applied between the two links, a control action of a control loop may cause a rotation and motive force of the motor that lead to the deflection of the spring assembly to balance with the external force/torque and inertial force from body masses moving together with the links.

This semiconductor device manufacturing device comprises: a stage; a bonding head; a copying mechanism provided on the bonding head; and a controller that executes the copying process to adjust a facing surface to be parallel to a reference plane by having the facing surface, which is a holding surface or a chip end face, follow the reference plane 110, which is a planar surface of the stage or a substrate. In the copying process, the controller moves the bonding head relative to the surface direction of the reference plane with the facing surface left abutting the reference plane in a state with the copying mechanism switched to a free state, until the axial direction position of the bonding head reaches a stipulated reference position, and when the axial direction position reaches the reference position, switches the copying mechanism to a locked state.

A grinding or polishing device and a method for treating a workpiece are provided. The grinding or polishing device includes a tool holder for holding a grinding or polishing tool and a mounting head for mounting the tool holder to a multi-axis manipulator. The tool holder is rotatable with respect to the mounting head about a pivot axis. The grinding or polishing device further includes a sensor for converting at least one parameter indicative of an angular position of the tool holder about the pivot axis into an output signal that can be used for determining a control signal for controlling the multi-axis manipulator.

The invention relates to a method for controlling a charging infrastructure comprising a charging station for charging a vehicle having a vehicle-side charging interface, wherein the charging station comprises a robot that carries a robot-side charging interface for establishing a charging connection with the vehicle-side charging interface, wherein the robot comprises a main base and a compliance assembly that is arranged kinematically between the main base and the robot-side charging interface for providing a compliance, wherein the method comprises in series a positioning phase in which the robot-side charging interface is moved to an initial connecting position, and a connecting phase in which the robot-side charging interface establishes a charging connection with the vehicle-side charging interface, wherein in the positioning phase a compliance value is compared with a positioning intervention value and a positioning instruction is changed when the compliance value exceeds a positioning intervention value, and in the connecting phase the compliance value is compared with a connecting intervention value and a connecting instruction is changed when the compliance value exceeds the connecting intervention value, wherein the positioning intervention value differs from the connecting intervention value.