A workpiece transport robot configured to determine whether a workpiece gripping failure has occurred, the workpiece transport robot including a transport robot main body having a driving mechanism configured to move a held workpiece; a robot hand having a first chuck and a second chuck configured to grip workpieces on both front and back faces of the robot hand; a robot hand rotating mechanism configured to axially support the robot hand and position the robot hand in a rotational direction with a servomotor, the robot hand supported with the transport robot main body via a rotation shaft to which first chuck and second chuck are symmetrically positioned, and a control device configured to compare measurement state information of the robot hand, of which information being based on torque information obtained by measuring and driving the servomotor; with workpiece gripping information obtained from a work program of the robot hand.

A gripper for an articulable arm of an automated processing tool is described that is suitable for picking and placing objects on a wire harness peg board. The gripper includes at least two spaced apart opposing grips. Each grip further includes spaced apart protrusions. The opposing grips and protrusions actuate between open and closed positions. When in the closed position the opposing grips are capable of enclosing a perimeter of an object and may further support an underside of the object. The gripper may further grip a wire so that the automated processing tool may orient the wire and apply a constant upward, downward or lateral tension on the wire.

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.

The present disclosure provides an apparatus and method for positioning an object. The apparatus can include gripping elements or arms to grip the object and actuators to move the object. Methods for positioning the object can include rotating the object about a first and second axis to achieve the desired position.

Electronic device manufacturing apparatus and robot apparatus are described. The apparatus are configured to efficiently pick and place substrates wherein the robot apparatus includes an arm component and a blade component. The blade component may comprise two or more end effectors that can retrieve and place two or more substrates at a time. The apparatus can include multiple arm components and multiple blade components. Each blade component can comprise two or more end effectors to carry two or more substrates at one time. The blade components can move independent of one another or may be dependently connected.

A robot for transporting long and flexible food to a predetermined position, which includes: a base, a first and a second robot arm which are connected to the base, a robot hand provided to the first robot arm and configured to hold the food, an end effector provided to the second robot arm, and a control device configured to control an operation of the first robot arm and the second robot arm. The end effector is configured to support a longitudinal intermediate portion of the food in a state where the food is hung down from an end portion of the robot hand, and the control device controls the operation of the first robot arm and the second robot arm to transport the food in a state where the food is held by the robot hand and the longitudinal intermediate portion of the food is supported by the end effector.

The present disclosure relates to a robotic gripper comprising a body and two robotic fingers mounted to the body. Each robotic finger includes a first link, a second link, a third link, a fourth link, a first joint, a second joint and a third joint. The first joint connects the first link and the second link, and the second joint connects the second link and the third link, and the third joint connects the third link and the fourth link. These links and these joints are comprised of elastic material and are formed in one piece.

An endoscopic grabber includes a proximal housing, a distal assembly, a flexible shaft extending between the proximal housing and the distal assembly, a flexible member within the flexible shaft having a distal end portion connected to the distal assembly and a proximal end portion connected to the proximal housing, and a camera within the distal assembly. A distal end portion of the flexible member is movably disposed within the distal assembly. A proximal end portion of the flexible member is connected to an actuator within the proximal housing. Actuation of the proximal end portion moves the distal end portion of the flexible member such that one or more elongate arms extending from the distal end portion deforms to form part of a grabber. The camera is configured to capture an image including a tip portion of the elongate arm. The elongate arms are configured to grab a target object.

A robotic system includes an end effector with one or more fin grippers that have one or more vacuum ports. The fin grippers are made of elastic material. The fin grippers each include contact and exterior flanges joined together with a series of crossbeams. The crossbeams each define a tube opening to form a tube guide channel between the contact and exterior flanges. In one form, the vacuum ports are located at fingertip ends of the fin grippers, and the vacuum ports include vacuum cups.

A pin field, comprising a plurality of pins mounted parallel with each other in a frame. The plurality of pins are extendable and retractable from the frame for sensing an object or for manipulation of the object in a working environment wherein a distal end of each pin in the plurality of pins comprises a combination pressure and temperature sensor.