An end of arm tool includes a rotating plate with a first slot and an end effector inserted through the first slot with a clearance to move the end effector within the first slot. Further, the rotating plate is adjusted to alter an orientation of the end effector to position the end effector at one of a plurality of different angles based on characteristics of object to be handled by the end effector.

A robot hand including a set of carpal bones, each of the carpal bones having at least one adjacent bone; and each carpal bone defining at least one socket. For each pair of adjacent carpal bones, at least one connector having a first and second end and wherein the first end and the second end are each in the form of a ball, and wherein the balls are joined by a connective element. Wherein the ball at the first end of the connector is fitted conformally into the socket of a first one of the pair of adjacent carpal bones and the ball at the second end of the connector is fitted conformally into the socket of a second one of the pair of adjacent bones, thereby joining the carpal bones together, but permitting limited relative movement.

Example systems and methods are described that are capable of gripping objects. In one implementation, a method involves identifying, by a processing system, an object to be gripped at a first location, commanding, by the processing system, a robotic actuator to move a gripper in a first direction so that the gripper makes contact with the object, wherein one or more teeth in a plurality of fingers associated with the gripper mechanically engage the object, and commanding, by the proceeding system, the robotic actuator to move the gripper in a second direction that is substantially opposite to the first direction, causing the gripper to grip the object.

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.

An adhesive apparatus with an electrostatic adhesive including a microstructured adhesive disposed over an electrode and/or a piezoelectric element. The adhesive can be added to any robotic gripper, such as a gripper finger formed of a flexible material and including a grip surface. The electrode and/or a piezoelectric element can be used for applying an electrostatic field and/or ultrasonic vibration, configured for cleaning the microstructured adhesive, releasing the adhesive, and/or sensing a load on the adhesive apparatus.

A fluid powered gripper can include a body, a bore, a first finger, a second finger, and a piston. The body can include a central bore coaxial with a central longitudinal axis of the body. A bore fluid inlet can be fluidly coupleable to the central bore. The first finger can be rotatable about the body. The second finger can oppose the first finger and the second finger can be rotatable about the body. The piston can be disposed in the central bore. The piston can be powered by a fluid to move between a first position and a second position. The first finger and the second finger can be closed in the first position and open in the second position.

Example systems and methods are described that are capable of gripping objects. In one implementation, a system includes a first finger that includes a plurality of teeth and a second finger that is mechanically coupled to the first finger and includes a plurality of teeth. The first finger and the second finger are configured to move apart when the first finger and the second finger are moved in a first direction against an object. The first finger and second finger are further configured to grip the object when the first finger and the second finger are moved in a second direction that is substantially opposite to the first direction.

A drone payload device includes a remote drone arm and a control module. The remote drone are is coupleable to a drone. The remote drone arm includes a base, an arm, and a gripper. The base includes mounting hardware to couple to the drone. The arm extends from the base. The griper is coupled to the arm at an end of the arm distal from the base. The control module is coupleable to a drone controller. The control module is to provide a control signal to the remote drone arm to control a movement of at least one of the arm and the gripper.

The present disclosure provides a gripper of a robot and a robot including the same. The gripper may include a case, a plurality of fingers rotatably connected to the case, and a plurality of connecting rods. A first end of each of the connecting rods may be connected to a respective one of the fingers. The gripper may also include a driving assembly connected to a second end of each of the connecting rods, and the driving assembly may be configured to drive the second end of each of the connecting rods to move along a moving direction so as to drive the plurality of finger to rotate. The gripper may further include a force detecting assembly connected to the case and the driving assembly, which may be configured to limit a position of the driving assembly along the moving direction and to detect a force from the driving assembly.

Provided is a robotic hand which includes a palm, a plurality of phalanges adapted to reproduce a plurality of fingers, and an actuating mechanism. The actuating mechanism may include a first pulley located at each hinge and bound to the first element, second pulleys located at each of the hinges and bound to the second element, a single cable running in all of the pulleys and a motor adapted to act on the cable by controlling the rotation of the phalanges.