In a robot (industrial robot) system, a robot holds a workpiece by pinching the workpiece between movable claws. A controller, which controls the robot, includes a host controller that controls the robot to perform a positioning operation for positioning the hand to a grip position and a gripping operation for displacing each of the movable claws toward each other at the grip position. In the controller, a machine learning device acquires stop reference data set for gripping of the workpiece, distance data indicating a distance between each of the movable claws of the hand positioned at the grip position and the workpiece, and comparison data indicating a deformation amount of the workpiece before and after the gripping operation. The machine learning device performs machine learning using such acquired data, resulting in constructing a model used for setting an operation mode of the gripping operation.

A robot hand includes: a first link; a first fixed pulley and a second fixed pulley, respectively provided at a proximal end pivot part of the first link and rotatable around a first axis; a second link, supported at an intermediate pivot part by the first link to be rotatable around a second axis; a lever link, supported by the proximal end pivot part of the first link to be rotatable around the first axis; a lever pulley, supported by the lever link; a hanging cable, hung on the first fixed pulley, the lever pulley, and the second fixed pulley; a conversion mechanism, connecting the lever link and the second link, and converting rotation of the lever link into rotation of the second link; and a second link driving mechanism, rotating the lever link around the first axis by pulling the hanging cable.

Techniques are described for testing whether an end effector, or component thereof, is correctly or incorrectly installed to a manipulation system. In an example, a manipulation system can include a manipulator arm configured to receive an end effector having a first moveable jaw, a transducer configured to provide first effort information of the end effector as the end effector moves, and a processor configured to provide a command signal to effect a first test move of the first moveable jaw, and to provide an installation status of the of the end effector using the first effort information of the first test move.

A gripper arrangement adapted for gripping a cleanroom container, such as a FOUP, FOSB or reticle container and a method therefore, includes: a gripper adapted to grip the cleanroom container; a lifting unit comprising a first motor for lifting the gripper; at least one cord connecting the gripper with the lifting unit, wherein the at least one cord is driven by the first motor; a second motor for rotating at least a portion of the gripper with respect to the lifting unit around the vertical axis; wherein the gripper comprises engagement elements and the lifting unit comprises complementary engagement elements adapted to engage with the engagement elements for preventing a rotation around the vertical axis of the gripper with respect to the lifting unit; wherein the gripper comprises an upper gripper element and a lower gripper element; wherein the lower gripper element is adapted for supporting the top flange of the cleanroom container; and the lower gripper element comprises an opening that can be passed over the upper flange of the cleanroom container and at least one recess formed at least partially around the opening for accommodating the upper flange of the cleanroom container.

An emptying system for emptying a box of food products comprising: —a box overturning robot (2) comprising gripping means (20); —acquisition means (3) for acquiring at least one image of at least one part of the box; —a control unit (4) that moves said gripping means (20) in function of the information arising from said acquisition means (3) for grasping the box by said gripping means (20).

A multi-armed robotic translation device includes a robotic body that includes a base section and a cover section attached to the base section. A plurality of tentacles is attached to the robotic body. The plurality of tentacles are configured to apply a shear force on the target object to grip the target object using an adhesive force, each tentacle including at least one shape memory alloy wire configured to move the tentacle. A control system is positioned in the robotic body and is configured to provide power and/or control signals to the tentacles.

A load handling device is disclosed for lifting and moving storage containers stacked in a grid framework structure having first and second sets of parallel rails or tracks. The load handling device includes: a body mounted on first and second sets of wheels arranged to engage with the tracks. A direction-change assembly is arranged to raise or lower the first set of wheels and or lower or raise the second set of wheels with respect to the body to engage and disengage the wheels with the tracks. The direction-change assembly includes a linkage-set having a series of members arranged between a traveller and a fixed brace, wherein the traveller is arranged to move under an applied force to cause the wheels to raise or lower.

A load handling device is disclosed for lifting and moving storage containers stacked in a grid framework structure having first and second sets of parallel rails or tracks. The load handling device includes: a body mounted on first and second sets of wheels arranged to engage with the tracks. A direction-change assembly is arranged to raise or lower the first set of wheels and or lower or raise the second set of wheels with respect to the body to engage and disengage the wheels with the tracks. The direction-change assembly includes a linkage-set having a series of members arranged between a traveller and a fixed brace, wherein the traveller is arranged to move under an applied force to cause the wheels to raise or lower.

A thumb structure includes a proximal phalanx, a distal phalanx rotatably connected to one end of the proximal phalanx, a fixing member connected to the proximal phalanx through a first ball joint, a linking member having opposite ends that are connected to the distal phalanx and the fixing member through a second ball joint and a third ball joint, a first actuating assembly to drive the proximal phalanx to swing in a direction of a first degree of freedom, and a second actuating assembly to drive the proximal phalanx to swing in a direction of a second degree of freedom.

A force sensing device for use in a robotic finger including: a first segment, the first segment having a first joint at a first end thereof; a second segment, the second segment being connected to the first segment by a second joint; and a third segment, the third segment being connected to the second segment by a third joint; and torque sensor for sensing the torque at each of the joints when a force is applied to the third segment. The first, second and third joints are disposed within the same plane and are disposed in a triangular arrangement.