A retention and movement unit of at least one component and at least one container is described. The unit has a moving retention member including, in turn, a frame and a first gripping device with a first retention element, the gripping device having a first configuration for selectively retaining the at least one component by the first retention element. In a first alternative, the first gripping device has a second configuration, different from the first configuration, for selectively retaining the at least one container. In the second alternative, the moving retention member further includes a second gripping device, including a second retention element, the second gripping device having a second configuration, different from the first configuration, for selectively retaining said at least one container.

Pre-plating systems and related methods are disclosed. A pre-plating system includes a press, an infeed robot configured to deliver a structural member to the press, and an outfeed robot configured to remove the structural member from the press. The press is configured to secure a plate to the structural member while the structural member is held in position by at least one of the infeed robot or the outfeed robot. A pre-plating system includes a press, a transfer pedestal, a plate picking robot, and a press loading robot. The plate picking robot is configured to pick a plate from a container and position the plate on the transfer pedestal. The press loading robot is configured to transfer the plate to the press. The press is configured to press the plate into a structural member positioned within the press.

An article discharge system includes a placement unit in which the article group is placed, plural grippers, a movable member, a robot that moves the movable member, weight acquisition units, and a control unit. The plural grippers grip some articles with gripping member. The plural grippers are attached to the movable member. The weight acquisition units acquire weight values of the articles that each of the grippers grips. The control unit moves the movable member, brings the plural grippers closer to the placement unit, causes the plural grippers to grip some of the articles of the article group placed in the placement unit, and, based on the result of a combination calculation using the weight values of the articles that each of the grippers grips and which the weight acquisition units have acquired, causes predetermined grippers among the plural grippers to release the articles and thereby discharge the articles.

A robotic tool changer system and a method for performing a tool change with the robotic tool changer system are disclosed. Providing a plurality of second coupling units each connected with a tool, wherein the second coupling units are detachably connected to a respective tool changer grippers; driving a first coupling unit along a second direction with a robot arm end shaft to be coupled with a selected second coupling unit; driving the first coupling unit coupled with the selected second coupling unit away from the corresponding tool changer gripper in a first direction, defining an angle between the first direction and the second direction; wherein when the selected second coupling unit is moved to the corresponding tool changer gripper and before the first coupling unit to separate from the selected second coupling unit, a third acting force is applied to the selected second coupling unit for restricting movement.

A retainer apparatus configured to releasably retain an article, comprising a face plate member each having a front face, a plurality of vacuum cups and a plurality of support pins each extending distally relative to the front face, respectively, wherein the vacuum cups and the support pins are laterally spaced from one another, wherein the plurality of vacuum cups retain the article to the retainer apparatus in a presence of vacuum, wherein the plurality of support pins are extendable/retractable relative to the face plate member, wherein each of the support pins have a longitudinal axis, respectively, and are configured to contact the article to support the article against movement along the longitudinal axis and support the article against movement transverse to the longitudinal axis, and a locking mechanism configured to inhibit the support pins from being retractable and extendable when the locking mechanism is engaged.

A method for manufacturing an automotive mirror, in particular a side mirror, includes forming a printed circuit board as flexible printed circuit board with n+1 branches, nεN, providing n modules each including at least one electronic element housed within a plastic casting and connected to conducting paths on at least one of the surfaces of the plastic casting, and at least one standard gripping point, guiding structure, snap connection element and/or sealing member provided by the plastic casting, connecting up to n of said branches to one module each and connecting one branch to cables or a cable harness to be connected to a power supply and/or a control unit outside the mirror, providing mirror parts free of electronic elements, and assembling the mirror parts and the modules.

An object of an embodiment is to provide a robot hand with high versatility for various kinds of workpieces. A robot hand according to the embodiment has a pair of grasping sections that are disposed to face each other to grasp a workpiece. The pair of grasping sections are equipped with a pair of workpiece contact sections. The pair of grasping sections are moved in directions to move close to and separate from each other by a moving mechanism. The workpiece contact section is a vacuum suction section including flexibility. The vacuum suction section grasps a workpiece while vacuum-sucking the workpiece.

An automobile vehicle flexible robot door hinge installation system includes a hinge servo-linear positioning device. The hinge servo-linear positioning device includes at least one servo-motor and at least one hinge effector releasably holding and positioning a vehicle door hinge. A fastener servo-linear installation device is also provided.

A method for palletizing by a robot includes positioning an object at an initial position adjacent to a target object location, tilting the object at an angle relative to a ground plane, shifting the object in a first direction from the initial position toward a first alignment position, shifting the object in a second direction from the first alignment position toward a second alignment position, and releasing the object from the robot to pivot the object toward the target object location.

The present invention is directed to tool arrangement having a one piece frame. The one piece frame that is solid and non-adjustable and includes a back side, front side and one or more extension walls extending away from the front side of the one piece frame. An attachment portion is located on said back side of the one piece frame for connecting the tool arrangement to a robotic arm. The one piece frame has at least three mounting locations formed at predetermine locations on said one piece frame. The at least three mounting locations are predetermined and non-adjustable locations on the one piece frame. The tool arrangement includes a stationary gripper connected to one of the three mounting locations and at least one four point gripper connected to another one of the three mounting locations.