A gripper for a transport system of a picking device having horizontal storage surfaces for storing and dispensing small piece goods of different shapes and/or surface properties is provided. The gripper comprises a drop table extending in first and a second horizontal directions and having a storage and dispensing end face. Two elongated gripping jaws are arranged above the drop table extending in the first horizontal direction, and are fastened to a gripping jaw guide arrangement. At least one of the gripping jaws is movable in the second horizontal direction and at least one of the gripping jaws has a gripper coupler in its end portion facing away from the gripping jaw guide arrangement, and at least one transport attachment with an attachment coupler. The gripper and attachment couplers interact so that a transport attachment is releasably fixed at an end portion of a gripping jaw.

A cleaning system is provided. The cleaning system includes a robot cleaner and a station. The robot cleaner includes a pad fixing part on which a cleaning pad is detachably mounted, a lifter to lift a part of the robot cleaner at which the pad fixing part is positioned, and a pad detacher to detach the cleaning pad mounted on the pad fixing part. The station includes a pad storage box in which a cleaning pad that is to be provided to the robot cleaner is stored, a pad coupling part on which a cleaning pad that is to be coupled to the robot cleaner is rested, and a pad supplier to supply the cleaning pad stored in the pad storage box to the pad coupling part.

A tool changer in accordance with the present disclosure comprises: a housing fastened to a manipulator of a robot, wherein the housing is a non-magnetic material; a bar-shaped magnet disposed in the housing; a motor configured to rotate the magnet on a rotation shaft perpendicular to a longitudinal direction of the magnet; and a core configured to derive a path of a magnetic flux by the magnet. The core comprises: a pair of first poles facing both poles of the magnet, when the magnet rotates to be elongated in a first direction; a bridge configured to connect the pair of the first poles and disposed in the housing, wherein the bridge is a magnetic material; a pair of second poles facing the both poles of the magnet, when the magnet rotates to be elongated in a second direction perpendicular to the first direction; and a pair of terminals connected to the second poles and facing a magnetic body disposed outside the housing.

Provided herein is an apparatus and system to increase the capacity for grasping or engagement of an object using an accessory tool. Methods of increasing the capacity of a tool can include: engaging an accessory tool with a tool, where the tool includes a first vacuum cup and the accessory tool includes one or more second vacuum cups; securing the tool to the accessory tool with a securing mechanism; drawing a vacuum through the first vacuum cup, where the vacuum is drawn through the one or more second vacuum cups in response to drawing a vacuum through the first vacuum cup while the accessory tool is engaged with the tool; and grasping an object with the second one or more vacuum cups in response to vacuum drawn through the one or more second vacuum cups and the one or more second vacuum cups engaging a surface of the object.

A robotic transport system including a drive section connected to a frame, an articulated arm operably coupled to the drive section providing the articulated arm with arm motion in at least one axis of motion moving at least a portion of the articulated arm in a collaborative space, corresponding to the frame, from a first location to another different location in the collaborative space, the articulated arm having an end effector with a workpiece grip having workpiece engagement members engaging and holding a workpiece during workpiece transport, by the arm motion in the at least one axis of motion, wherein at least one of the workpiece engagement members is frangible compliant, having a frangible compliant coupling between a distal portion of the at least one of the workpiece engagement members and a base portion of the end effector from which the at least one of the workpiece engagement members depends.

Provided are a robot hand which may be detached by a simpler mechanism, and a robot including the robot hand. The robot hand includes: a gripping part configured to grip a target object; and a mounting part configured to mount the gripping part to a mounted part of a robot, wherein the gripping part may be further configured to operate in a first movement region to grip the target object, and a second movement region to be removed from the mounted part, and wherein the mounting part is engaged with the mounted part in the first movement region, and the mounting part is removed from the mounted part in the second movement region.

A storage system configured to house a plurality of containers housing inventory items includes support members, a first set of parallel rails to support a mobile, manipulator robot, and a fluid supply line having a plurality of valves disposed within the fluid supply line. Each of the valves having a closed condition in which the supply line is in fluid isolation from an outside environment and an open condition in which the supply line is in fluid communication with the environment such that the supply line is configured to supply fluid to a mobile, manipulator robot. Mobile, manipulator robots for retrieving inventory items stored within the containers and retrieval methods are also disclosed herein.

A mobile manipulator robot for retrieving inventory items from a storage system. The robot includes a body, a wheel assembly, a sensor to locate a position of the robot within the storage system, an interface configured to send processor readable data to a remote processor and to an operator interface, and receive processor executable instructions from the remote processor and from the operator interface, an imaging device to capture images of the inventory items, a picking manipulator, first and second pneumatic gripping elements for grasping the inventory items, and a coupler configured to mate with a valve to access a pneumatic supply for operating at least one of the first or second pneumatic gripping elements. The robot is configured to transition the valve from a closed condition to an open condition and selectively place one of the first or the second pneumatic gripping elements in communication with the pneumatic supply.

The present disclosure is directed toward a robotic system that includes a robotic arm, a robotic end-effector, a lock, and a control system. The robotic end-effector is detachably coupled to the robotic arm and includes a locomotion device to move the robotic end-effector independent of the robotic arm. The lock is disposed with the robotic arm and robotic end-effector, and is operable to detach and attach the robotic arm and the robotic end-effector. The control system is configured to control the robotic arm and the robotic end-effector, and to operate the lock to detach and attach the robotic arm and the robotic end-effector.

Devices, systems, and methods for automatically exchanging a first end-effector on a robot arm with a second end-effector housed in a docking station. The first end-effector has a clamp that either engages or disengages the robot arm based upon an application of force of the robot arm onto the end-effector. The clamp has a spring loaded clip that disengages the first end-effector to allow the robot arm to move away from the released first end-effector. The robot arm is configured to automatically move to a port of a docking station housing the desired second end-effector using magnetic coils on the robot arm and the docking station to guide the robot arm.