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.

A stack of products is moved with a robot which has an articulated arm and at least one gripper disposed on the articulated arm to grip the stack of products. The stack of products can be selectively turned. The step of moving terminates at a selected deposit location of a number of deposit positions of a predefined deposit scheme. The stacks of products are moved in an automated way and, in particular, the stacks are deposited in a turned or unturned arrangement.

A stack of products is moved using a robot. The robot has an articulated arm and grippers on the articulated arm to grip the stack of products. The stack of products is selectively turned in the depositing scheme. Two grippers are used in the method and, upon the deposit, the grippers are removed from the stack of products in the horizontal and in two directions perpendicular to one another. It is possible to move and selectively deposit stacks of product in a turned or unturned orientation.

An end-of-arm tool for attachment to a robotic arm, includes a housing, an outer suction cup assembly that includes an outer suction cup located at the distal end of the housing, and an inner suction cup assembly that extends centrally through the outer suction cup assembly. The inner suction cup assembly includes a lower suction tube, an inner suction cup that is positioned at a distal end of the lower suction tube and is in fluid communication with the lower suction tube. The inner suction cup is concentrically located relative to the outer suction cup. The tool includes an actuator configured to selectively extend and retract the lower suction tube with respect to the outer suction cup.

An end-effector assembly includes a master boom, a frame rail coupled thereto, and at least one branch rail movably coupled to the frame rail by a swing branch lock. The swing arm is movably coupled to the at least one branch rail by a swing arm lock. Each of the swing branch lock and the swing arm lock further includes a clamp configured to movably secure the branch rail to the frame rail or the swing arm to the branch rail. A pivot shaft extends through the clamp and is configured to rotationally secure the clamp in place. A swing plate is secured to the pivot shaft and is configured for engagement with a configuration tool. A locking fastener extends through the swing plate and into the pivot shaft and is configured to lock and unlock the clamp in position.

Exemplary embodiments provide modular robotic systems that allow one or more operation parameters of a robotic actuator, or group of actuators, to be dynamically configured or reconfigured. The operation parameters may be, for example, the X, Y, and/or Z position of the actuator or group of actuators with respect to other actuators, the arrangement of the actuator(s) into an array or matrix, the rotation or pitch of an actuator, the distance between actuators, the grip strength or grip surface of an actuator, etc. Accordingly, the same robotic manipulator(s) may be used for multiple purposes in multiple different contexts, manipulators can be swapped out on-the-fly, and robotic systems may be dynamically reconfigured to perform new tasks.

The invention discloses a robotic dexterous hand including a plurality of finger mechanisms, the finger mechanisms comprises: an actuator; a connecting element with one end fixed to the actuator; a plurality of fingers including a plurality of knuckles, the knuckle includes a fixed knuckle positioned at the other end of the connecting element, the fixed knuckles are arranged in parallel and jointly form a palm of the robotic dexterous hand; wherein the actuator drives the flexion of the fingers to perform the gripping of a target object. The fingers and the palm are built from the multiple knuckles having a same structure. Design is required merely for the structure of a single knuckle, the need for discretely designing the structure of the fingers and that of the palm is obviated, thus greatly reducing the types of components, at the same time, simplifying the structure, and favoring the production and management.

A produce packing robot is provided comprising a plurality of heads for picking up items of produce from a plurality of pick-up locations, and moving the items of produce and dropping them off at a plurality of drop-off locations. The plurality of heads move together in a first direction on a common rail. The robot may also comprise a range imaging camera and controller for sensing the location of the drop-off points dynamically.

Object manipulation in warehouses and logistics facilities is a challenging task because of the unstructured environment. The unstructured environment can have items/objects with different form factors, weight, shape, and size. Traditionally, multiple robots have been used to handle for specific task to be performed by an individual robot which requires high floor. This leads to higher cost and infrastructure. Embodiments of the present disclosure provide a gripper apparatus that addresses a single gripper design handling multiple parcels, wherein the apparatus consists of cm′ fingers parallel to each other and can be independently controlled through actuators, each finger has a force sensors feedback and also actuators which are controlled with force. Each finger comprises a linear slider for actuation for gripping objects and wherein bottom fingers are moved to provide enough gravity support. Further, apparatus comprises bellows attached to each finger end for grasping object using pneumatic grasping mechanism.

A robot hand includes a pair of movable members that is detachable from a wrist flange of a robot body and that are arranged at a distance from each other; holding parts that are provided on the movable members and that hold a workpiece; and a width adjusting mechanism that supports the pair of movable members so as to allow relative movement thereof in a width direction and that adjusts a distance B between the pair of movable members by means of the relative movement of the pair of movable members in the width direction (A). The pair of movable members are relatively moved in the width direction as a result of the width adjusting mechanism.