An end-effector system is disclosed for use with a programmable motion device. The end-effector system includes an arm attachment portion for attachment to an arm of the programmable motion device, an end-effector attachment portion for attachment to an end-effector for grasping objects, a rotational shaft portion for rotational attachment to the arm attachment portion, said rotational shaft portion being coupled to the end-effector attachment portion at a distal end thereof, and a motor system providing rotation of the rotational shaft portion as well as the end-effector attachment portion with respect to the arm attachment portion.

A screwing device includes a screwdriver and a connection element for coupling the screwdriver to a robot arm. The connection element has a first robot-side transmission element, a second tool-side transmission element, a restoring element arranged between the first and second transmission elements, and a distance measuring element. The two transmission elements can be moved towards each other against a restoring force of the restoring element in an actuation direction. The distance measuring element measures a distance that represents the spacing between the transmission elements in the actuation direction and is used to control the actuating force acting on the screwdriver.

According to an aspect of the disclosure, a robot arm gripper device includes a grip unit capable of gripping an object by a hinge movement, a power transmission unit coupled to the grip unit and transmitting power to the grip unit, and a buffer unit having one side connected to the power transmission unit and another side connected to a robot arm body, wherein the power transmission unit is movable on the buffer unit.

A vacuum gripping system for grabbing and releasing an object has a base frame for operably engaging a robotic arm. The base frame includes a pneumatic source connector. The system also includes an extendable member configured to extend and retract relative to the base frame. The extendable member has a distal end and a proximal end. The extendable member also has an extended position and a retracted position defining a range of motion therebetween. The system further includes a vacuum cup coupled to the distal end of the extendable member. Still further, the system includes a pneumatic pathway extending from the vacuum cup to the pneumatic source connector. The pneumatic pathway passes through the extendable member such that the vacuum cup remains in pneumatic communication with the pneumatic source connector throughout the range of motion of the extendable member.

A construction robot for mounting a member with a changeable height on a body at a predetermined height includes: a manipulator; an end effector provided at a distal end of the manipulator; a recognizing unit configured to recognize positions of the member and the body; and a measuring unit configured to measure a positional relation between the member and the body. The end effector includes a holding unit configured to hold the member in a releasable manner, and a height adjusting unit configured to adjust a height of the member by moving the member in contact with the body in a direction moving closer to or in a direction moving away from the body.

A method for operating a picking robot comprising an end effector assembly and a vision assembly, and related controller device is disclosed, the method comprising picking a subject with the end effector assembly from a bin comprising a plurality of subjects; moving the subject to a delivery station; and releasing the subject on the delivery station, wherein the method comprises locking a joint connection of the end effector assembly prior to and/or during the act of moving the subject to the delivery station.

A control apparatus of a robot that includes a flexible portion and a locking mechanism for fixing the flexible portion, the control apparatus including: a lock control unit configured to control locking and unlocking of the flexible portion; and an operation control unit configured to control operation of the robot using different types of control policies depending on whether the flexible portion is locked or unlocked. With this control apparatus, it is possible to effectively control a robot in which locking and unlocking of the flexible portion can be switched.

Magnetic coupling mechanisms for robotic arm end effectors are disclosed. In particular, a magnetic coupling mechanism couples a detachable tool, such as a suction gripper, to a tool changer base of a robotic arm tool of an end effector. Magnetic coupling between the robotic arm tool and the detachable tool allows for breakaway when a sufficient force is applied to the robotic arm tool and/or the detachable tool to separate the two. The decoupling may be achieved via a tool rack. An exemplary system for coupling a detachable tool to a motion device includes a first magnetic ring affixed to a distal end of the motion device, where an inside of the first magnetic ring forms a first hollow chamber; and a second magnetic ring affixed to a proximal end of the detachable tool, where an inside of the detachable tool forms a second hollow chamber.

An article boxing system includes an image processing apparatus, a first robot, and a first controller. The image processing apparatus detects edges of an article based on an image of the article. The image processing apparatus calculates information relating to a conveyance state. The first robot includes a hand unit and an arm adjusting three-dimensional coordinates and an inclination of the hand unit with respect to a conveyance direction. The first controller controls an operation of the arm to move the hand unit in correspondence with the information relating to the conveyance state and causes the hand unit to adsorb the article, when the article reaches an operation range of the first robot.

The present invention discloses a riveting robot, comprising: a robot part provided on a chassis, and detachably coupled with a riveting tool part through a hydraulically quick change disk; a visual position identification part provided on a side of the hydraulically quick change disk and secured on the sixth axis of the front end of the robot part; an automatic rivet feeding part provided on a mounting baseplate which is secured on a chassis through a two-stage vibration damping structure; a riveter tailing material collection part used for collecting tailing materials produced during riveting; a riveting quality judgment part used for collecting riveting data, and processing and generating a riveting curve to realize judgment of the riveting quality. A riveting robot system provided in the present invention can realize unmanned quick mounting of a pulling rivet at a specific riveting position; a vibration damping structure effectively isolates interference of riveting operation of a robot from a vibration source; radial and axial damping mechanisms can absorb axial and radial impact energies during the process of rivet pulling and mounting, ensuring that the operating accuracy of the riveting robot system and service life of the riveting robot mechanism.