A soft gripper including tentacles, each tentacle includes lower and upper members connected by a connector. Each member includes guide discs, and each guide disc includes a ring with passthrough holes, and a spacer located in a donut hole of the ring with passthrough holes, the passthrough holes collectively define cable pathways. The connector includes a center thru-hole and transfer channels. Cables have proximal ends attached to actuators and extend through apertures of a baseplate located at a proximal end of the lower member. A set of lower cables extend through the lower ring passthrough holes to couple to a distal lower guide disc. A set of upper cables extend through the lower spacer passthrough holes, through the transfer channels to the upper ring passthrough holes to couple to a distal upper guide ring, and an end cap is attached to the distal end of the upper member.

An end effector is an end effector to be grasped by a robot including a hand having a plurality of first movable parts and a second movable part using the hand, including an operation unit operated by movements of the second movable part in first directions, and an actuation unit actuated by an operation of the operation unit, wherein concave portions into which the first movable parts are inserted are formed.

A three-finger mechanical gripper system is provided, which includes a torque sensor, a three-finger mechanical gripper, an image capturing module and a controller. The three-finger mechanical gripper is connected to the torque sensor. The controller is connected to the torque sensor, the three-finger mechanical gripper and the image capturing module. The image capturing module captures the image of a training object. The controller controls the three-finger mechanical gripper to grip the training object by a plurality of gripper postures respectively and calculates the torque information of each gripper posture according to the measured values of the torque sensor. Then, the controller performs a training process according to the image of the training object and the torque information of the gripper postures in order to obtain a training result of the training object.

A soft gripper including tentacles, each tentacle includes lower and upper members connected by a connector. Each member includes guide discs, and each guide disc includes a ring with passthrough holes, and a spacer located in a donut hole of the ring with passthrough holes, the passthrough holes collectively define cable pathways. The connector includes a center thru-hole and transfer channels. Cables have proximal ends attached to actuators and extend through apertures of a baseplate located at a proximal end of the lower member. A set of lower cables extend through the lower ring passthrough holes to couple to a distal lower guide disc. A set of upper cables extend through the lower spacer passthrough holes, through the transfer channels to the upper ring passthrough holes to couple to a distal upper guide ring, and an end cap is attached to the distal end of the upper member.

A gripper system having tentacles including a control system configured to receive operator data and sensor data. Compare stored object configurations associated with grips to identify a corresponding set of object configurations using a target object shape and a pose via sensor data and select an object configuration. Compare stored commands to identify sets of commands corresponding to the object configuration and select sets of commands. If a set of pickup actions are received, compare to the corresponding object configuration to identify a set of pickup actions using the received set of pickup actions, and select a set of pickup actions. Compare the sets of commands to identify a corresponding first set of commands corresponding to a set of pickup actions using the set of pickup actions and select the first set of commands. If the received set of pickup actions are absent, then select a second set of commands.

A gripper system having tentacles including a control system configured to receive operator data and sensor data. Compare stored object configurations associated with grips to identify a corresponding set of object configurations using a target object shape and a pose via sensor data and select an object configuration. Compare stored commands to identify sets of commands corresponding to the object configuration and select sets of commands. If a set of pickup actions are received, compare to the corresponding object configuration to identify a set of pickup actions using the received set of pickup actions, and select a set of pickup actions. Compare the sets of commands to identify a corresponding first set of commands corresponding to a set of pickup actions using the set of pickup actions and select the first set of commands. If the received set of pickup actions are absent, then select a second set of commands.

Provided is a robot hand including: gripping portions disposed with spacings between each other in a circumferential direction about an axis, and that grip a workpiece; driving portions, each of which is provided so as to correspond to one of the gripping portions, cause the corresponding gripping portions to be linearly moved in closing directions in which the gripping portions are brought close to the axis and opening directions in which the gripping portions are moved away from the axis; and a center-of-gravity detecting unit detects a center-of-gravity position of the workpiece being gripped by the gripping portions. Each of the driving portions adjust, based on the center-of-gravity position of the workpiece, the position of the corresponding gripping portion in a direction in which the center-of-gravity position is brought closer to the axis.

A method for controlling a gripping device (2) for a robot (20) comprising two or more gripping structures (4, 4′) movably arranged relative to each other and being configured to grip an object (8, 16) is disclosed. The method comprises actively restricting the displacement (ΔD) of at least one of the two or more gripping structures so that said displacement is less than or equal to a predefined maximum displacement (ΔD.sub.max). The method comprises the steps of detecting when at least one of the gripping structures is in contact with the object and increasing the force (F) exerted by at least one of the two or more gripping structures to the object from a predefined first level (F.sub.1) to a predefined second level (F.sub.2) when it has been detected that at least one of the two or more gripping structures is in contact with the object.

Provided is a robot hand including: gripping portions disposed with spacings between each other in a circumferential direction about an axis, and that grip a workpiece; driving portions, each of which is provided so as to correspond to one of the gripping portions, cause the corresponding gripping portions to be linearly moved in closing directions in which the gripping portions are brought close to the axis and opening directions in which the gripping portions are moved away from the axis; and a center-of-gravity detecting unit detects a center-of-gravity position of the workpiece being gripped by the gripping portions. Each of the driving portions adjust, based on the center-of-gravity position of the workpiece, the position of the corresponding gripping portion in a direction in which the center-of-gravity position is brought closer to the axis.

The present disclosure generally relates to a robotic gripper comprising: a body; a plurality of displacement mechanisms; a plurality of finger modules removably connected or connectable to the body, such that each finger module engages with a respective displacement mechanism; each finger module comprising a finger actuator cooperative with the other finger actuators for gripping an object; and each displacement mechanism is configured for moving the respective finger module to adjust its arrangement on the body, thereby configuring the robotic gripper for gripping the object.