A device for robot-assisted machining of surfaces is described below. According to an example, the device has a retainer with a base plate designed for mounting on a manipulator and has an assembly suspended on the retainer, the assembly comprising a machine tool. The retainer has a tilt mechanism which couples the assembly to the retainer in such a way that the assembly can be tilted relative to the base plate about two axes of rotation, wherein the two axes of rotation can intersect with one another and run through the assembly below the base plate.

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 compliant end effector includes a robot mounting bracket and a component support member. The component support member includes a side surface and a top surface. A component clamping system includes a first clamp member operable to move toward the side surface of the component support member and a second clamp member operable to move toward the top surface of the component support member. A controller is operatively connected to the clamping system. The controller is configured to engage the first and second clamp members as the component gripping and manipulating system is in a set position and release the first clamp member and the second clamp member allowing a portion of a component held by the component clamping system to move with one or more degrees of freedom when the component gripping and manipulating system is moving to the set position.

A joint structure includes a locking mechanism for switching a free state in which a second element is independent from a first element and capable of moving, and a locked state in which the second element is fixed to the first element. The locking mechanism includes a first member joined to the first element, a second member joined to the second element, and a flexible wire-shaped member in which one end thereof is attached to the second member and another end thereof is led out to the outside of the joint structure via a through hole provided in the first member. The joint structure enters the locked state by the wire-shaped member being pulled to bring the second member into contact with the first member, and enters the free state by the wire-shaped member being fed to separate the second member from the first member.

An example test head manipulator includes a tower having a base and a track, where the track is vertical relative to the base, and arms to enable support for the test head. The arms are connected to the track to move the test head vertically relative to the tower, and the arms are configured to control rotation of the test head. Each of the arms includes a cam that is rotatable, and at least one plunger in contact with the cam and that is configured to contact the test head. Rotation of the cam is controllable to move the at least one plunger to offset an uncontrolled rotation the test head.

The disclosure provides an apparatus, system and method for a moveable bearing stage that allows for highly refined alignment and placement, and particularly planar alignment and placement, of component or devices through the use of robotics. The apparatus, system and method of providing at least a planar alignment of at least one component or device in relation to a secondary reference plane may include at least: a frame and stator assembly, having, at an upper portion thereof, at least a semi-spherical receiving interface; a movable assembly that moves within the frame and stator assembly, and that is connectively associated therewith by at least a plurality of springs; a semi-spherical stage, suitable for reception by the semi-spherical receiving interface and capable of at least rotational movement therewithin; a chuck within the semi-spherical stage and capable of at least co-planar, post-planar, and ante-planar positioning in relation to a plane provided by a topmost portion of the semispherical stage, wherein the chuck is capable of receiving the component or device; and at least two gripper jaws suitable for receiving and holding, at an upper portion thereof, the component or device, wherein the two gripper jaws comprise, at a lower portion thereof, at least ramps capable of physically interacting with ones of the motion stops.

An electromechanical system operates in part through physical interaction with an operator, and includes a multi-axis robot, a controller, and a counterbalance mechanism connected to the robot. The counterbalance mechanism includes a base structure connected to a set of linkages, a pneumatic cylinder, a spring-loaded cam assembly, and an optional constant force spring. The linkages form a four-bar parallelogram assembly connectable to a load. The cylinder and cam assembly, and optional constant force spring, each impart respective vertical forces to the parallelogram assembly. The forces combine to provide gravity compensation and self-centering functions or behaviors to the load, enabling the load to move with a vertical degree of freedom when manually acted upon by the operator, and to return the load to a nominal center position.

A metallurgic casting installation comprises a robot. The robot comprises a handling tool coupled to an arm of the robot by a coupling element. The coupling element comprises a tool interface rigidly coupled to the handling tool, and a robot interface rigidly coupled to the arm of the robot. The compliance of the coupling element can be controlled such that upon application of a load onto the tool interface, the tool interface can be moved relative to the robot interface, by translation along and/or rotation about one or more of a first, second and third orthogonal spatial axes X1, X2, X3. The coupling element is resilient in that upon release of the load, the tool interface returns to a reset position relative to the robot interface corresponding to a reset distance Dr separating the tool interface and the robot interface.

An automatic assembling system, comprising: a robot performing an operation of inserting a first member into a second member; a force sensor for detecting an insertion force exerted on the first member by the robot; and a controller for controlling the insertion force with a closed-loop feedback control according to a difference between the insertion force detected by the force sensor and a predetermined insertion force, so that the insertion force is less than the predetermined insertion force to protect the first member and/or the second member from damage due to an overlarge insertion force. The present invention also is directed to a method for automatically assembling a product.

A robot system includes an end effector that is able to work on a workpiece, a support part configured to support the end effector in a state in which the end effector is displaceable, a first driving part configured to drive the end effector via the support part with a first stroke, a detector configured to detect a position of the end effector, and a second driving part that is disposed between the support part and the end effector and that is configured to drive the end effector with respect to the support part with a second stroke smaller than the first stroke based on a position information of the end effector detected by the detector.