A method moves a stack of products by a robot. The robot has an articulated arm and at least one gripper disposed on the articulated arm to grip the stack of printed products and the stack of products selectively being turned. The method includes pivoting the stack of products through an effective angle α1< >180° and subsequently pivoting the stack through an effective angle α2=180°−α1 or pivoting the stack back through an effective angle α2=−α1. This method of moving stacks of products is performed in an automated way and in particular of depositing them in a turned or unturned arrangement.

An apparatus, system and method for a substrate flipper capable of accommodating substrates of varying sizes. The apparatus, system and method may include a base housing providing at least a portion of a rotating feature; an arm enclosure rotatably associated with the rotating feature and providing at least one arm actuator, and at least one gripper actuator; two arms at two substantially distal points with respect to one another along the arm enclosure, each of the two arms being communicatively associated with the at least one arm actuator; and a gripper associated with each of the two arms distal from the arm enclosure, communicatively associated with the at least one gripper actuator and capable of gripping one of the substrates upon actuation of the gripper. The actuation of the at least one arm actuator effectuates a change in distance between central longitudinal axes of each of the two arms.

A gripper device includes a holding portion that is attached to an elevating section capable of lifting and lowering above a transfer section to hold an article, a first positioning section that is attached to the elevating section and that positions the holding portion in a horizontal direction with respect to the article by contacting the article at two first contact positions in an upper portion of the article, and a second positioning section that is attached to the elevating section and that positions the holding portion in a height direction with respect to the article by contacting the article at three second contact positions that are not located on a straight line in the upper portion of the article.

An apparatus, system and method for a wedge clamp suitable to provide self extracting grips for an end effector suitable to hold semiconductor wafers, or other substrates such as rectangular panels. The apparatus, system and method may include two inner jaws at least mechanically associated with a robotic base; two outer arms associated with the inner jaws via at least one arms cam; and a plurality of wedge clamps. Each of the wedge clamps may comprise: a spring; a cam loaded on the spring; and a cam travel path into which the cam is slidably associated. A contraction of the inner jaws and a consequent arms camming of the outer arms applies pressure to a circumferential edge of the semiconductor wafer such that the circumferential edge depresses each of the cams along its respective cam travel path and against its respective one of the springs. The jaws close may synchronously about a center point of the substrate, thereby keeping it centered.

A gripping system for an autonomous guided vehicle (AGV) and such AGV are disclosed herein. The gripping system for automated gripping and pulling/pushing a cart comprises a unique gripping end effector ensuring controlled steering of the cart while allowing rolling of the cart relative to the body of the AGV. The end effector comprises means for indication of state of connection between the cart and the gripping system, ensuring a reliable, safe and efficient cart gripping and pulling operation.

A gripper device and method is provided. The method includes capturing, using an electronic device, information of an object that is indicative of holding position; determining, using the information, by a hardware processor, an optimal holding orientation and an optimal movement of at least one of (i) a plurality of fingers, or (ii) a plurality of suction cups of a gripper device; identifying the at least one of (i) the plurality of fingers, and (ii) the plurality of suction cups as one or more grasping components based on the information, the optimal holding orientation and the optimal movement; and enabling, using an actuator, the one or more identified grasping components to grasp the object based on the information, the optimal holding orientation and the optimal movement.

A robot hand is designed to open or close fingers using a linear actuator disposed in a housing. The robot hand has linear motion shafts extending from inside to outside the housing through guide holes formed in a wall of the housing. Each of the fingers includes a base portion and a tip portion. The base portions are secured to the linear motion shafts outside the housing. The tip portions are bent inwardly from the base portions in directions in which they approach each other and then extend toward tips of the fingers. A sealing member is disposed between each of the linear motion shafts and a corresponding one of the guide holes to hermetically isolate the inside of the housing from the outside thereof. This structure achieves an increased degree of sealing of the housing and is capable of having an increased opening or closing stroke of the fingers.

A gripper tooling includes: a gripper having a gripper body and an angular jaw; a rotor fixedly connected to the angular jaw; and a tooling member for gripping a workpiece, the tooling member including: a base pivotally connected to the rotor; a middle segment pivotally connected to the base; a distal segment pivotally connected to the middle segment; an adducting tendon having a proximal end attached to the rotor and a distal end attached to the distal segment, the rotor for rotating relative to the base and thereby for tensioning the adducting tendon; and an abducting tendon having a proximal end attached to the base and a distal end attached to the distal segment such that the tooling member can autonomously grip the workpiece as the angular jaw rotates toward the workpiece and the tooling member autonomously returns to an ungripped position as the angular jaw rotates away from workpiece.

A robot gripper for moving wafer carriers and packing materials and a method of operating the same are provided. The robot gripper includes two opposing clamp assemblies. The two clamp assemblies are configured to move close to or away from each other. Each of the clamp assemblies includes a movable support pin at a bottom of the clamp assembly.

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.