A chuck apparatus includes a pair of grip members driven by a piston via a pair of levers, and the levers are rotatably supported by a body via lever shafts. A lever shaft protrudes from the attachment surface of the body to the transport device, and positioning with respect to the transport device is performed by using the protruding portion.

A gripping device comprises an electric linear motor having a motor stator and a motor slider which is movable in a longitudinal direction, a first gripper finger and a second gripper finger, a redirecting mechanism which is coupled to the motor slider as well as to at least one of the first and second gripper fingers, and a constant force generator having a stator and a slider which is movable relative to the stator in the longitudinal direction. The stator has a magnetically conductive or permanently magnetic stator region, and the slider has a permanently magnetic or magnetically conductive slider region. In a gripping position, the slider region and the stator region only partly overlap in the longitudinal direction, while in an open position, the slider region and the stator region do not overlap in the longitudinal direction.

An end effector control system that controls a plurality of end effectors connectable to a robot arm, the end effector control system including: an image acquisition unit that acquires an image of an end effector connected to the robot arm among the plurality of end effectors; an identification information acquisition unit that acquires identification information that identifies the end effector; a control unit that controls the end effector; and a memory having control information including a target position of each of the plurality of end effectors. The control unit acquires the identification information from the identification information acquisition unit, determines a target position of the end effector in accordance with the identification information and the control information, and controls the end effector to be located at the target position based on the image acquired by the image acquisition unit.

The hand apparatus includes: a grasper that grasps a work; a grasper driving portion that causes the grasper to operate at a first position at which the grasper grasps the work, a second position at which the grasper is open widest, and a third position between the first position and the second position; a hand mechanism portion having a pair of hand portions that holds both ends in a width direction of the work grasped by the grasper and capable of varying an opening position of the pair of hand portions; an operating portion provided so as to be interlocked with an operation of the grasper and being connectable to the hand mechanism portion; and an actuator that causes the grasper to advance and retract, wherein when the grasper is at the second position, the hand mechanism portion is connected to the operating portion to vary the opening position of the pair of hand portions by being interlocked with the advancing and retracting movement of the grasper according to the actuator, and when the grasper is at the first position or the third position, the hand mechanism portion is disconnected from the operating portion to fix the opening position of the pair of hand portions.

Disclosed are various embodiments of a three-dimensional perception and object manipulation robot gripper configured for connection to and operation in conjunction with a robot arm. In some embodiments, the gripper comprises a palm, a plurality of motors or actuators operably connected to the palm, a mechanical manipulation system operably connected to the palm, a plurality of fingers operably connected to the motors or actuators and configured to manipulate one or more objects located within a workspace or target volume that can be accessed by the fingers. A depth camera system is also operably connected to the palm. One or more computing devices are operably connected to the depth camera and are configured and programmed to process images provided by the depth camera system to determine the location and orientation of the one or more objects within a workspace, and in accordance therewith, provide as outputs therefrom control signals or instructions configured to be employed by the motors or actuators to control movement and operation of the plurality of fingers so as to permit the fingers to manipulate the one or more objects located within the workspace or target volume. The gripper can also be configured to vary controllably at least one of a force, a torque, a stiffness, and a compliance applied by one or more of the plurality of fingers to the one or more objects.

A robot arm assembly for detecting a pose and force associated with an object is provided. The robot arm assembly includes an end effector having a plurality of fingers, and a deformable sensor provided on each finger. The deformable sensor includes a housing, a deformable membrane coupled to the housing, an enclosure filled with a medium, and an internal sensor disposed within the housing having a field of view directed through the medium and toward an internal surface of the deformable membrane. A processor is configured to receive an output from each internal sensor, the output including a contact region of the deformable membrane as a result of contact with the object. The processor determines an amount of displacement of the contact region based on the output from each internal sensor, and determines the pose and the force associated with the object based on the amount of displacement.

An air chuck includes: a finger support part including a pair of fingers; a chuck main body part including an operation mechanism operable to open and close the pair of fingers; and linking mechanisms that detachably link the finger support part to the chuck main body part. The linking mechanisms each include: a linking shaft that extends from the finger support part; a shaft insertion hole formed in a body of the chuck main body part; a catch body that becomes elastically caught on a catch surface of the linking shaft when the linking shaft is inserted into the shaft insertion hole; and a delinking member that is manually operated so as to release the catch body caught on the catch surface when the finger support part is detached from the chuck main body part.

A robot gripper includes two fingers of a grasper assembly configured to perform grasping motions via actuation of independent cable ends of a plurality of cables, and configured to move toward or away from each other to perform the grasping motion. Wherein each gripper finger is actuated by a pair of cables, a cable of the pair slides in a flexible sheath when actuated by a motor, moving the gripper finger in an opposite direction of another cable of the pair also in a flexible sheath, providing equal motions of each cable in the pair in opposite directions. A motor assembly including the motors is mounted at a location separate from the grasper assembly with the flexible sheathing extending between the assemblies. Such that the separate assembly mounting arrangement provides an improved ratio between a gripping force of the grippers versus the robot-lifted mass of the grasper assembly.

A gripper and a robot are provided. The gripper may include a shell and at least two finger assemblies. The finger assemblies are utilized to grasp an object on two opposite sides of the object. Each finger assembly may include a connecting rod, a pad portion and a layer of synthetic fibrillar adhesive. The connecting rod may be movably connected to the shell. The pad portion may be connected to the connecting rod, and the connecting rod may move the pad portion towards the object under a driving force. The layer of synthetic fibrillar adhesive may be attached to the pad portion. Microfibers of the layer of synthetic fibrillar adhesive may be inclined away from the shell.

This gripping hand has a base member and a number of fingers arranged about an axis line passing through the base member, wherein each of the fingers has a flexible finger part having flexibility and a finger base member for supporting the basal end side of the flexible finger part, the gripping hand is provided with a number of link mechanisms that are supported by the base member and that support the respective number of finger base members, and each of the link mechanisms allows the finger base member supported thereby to move relative to the base member such that the orientation of the finger base member supported thereby does not substantially change relative to the base member.