Provided is a die lift system comprising an end effector capable of lifting and manipulating a die, creating a safe and efficient way to do so free off all physical exertion by the worker associated with the lifting and maneuvering of the die; the end effector having the ability to engage a die; the end effector having at least one series of tines capable of grasping the die; the end effector having the ability to be securely coupled to the die; and the end effector having the ability to disengage from the die.

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.

A method and system for piece-picking or piece put-away within a logistics facility. The system includes a central server and at least one mobile manipulation robot. The central server is configured to communicate with the robots to send and receive piece-picking data which includes a unique identification for each piece to be picked, a location within the logistics facility of the pieces to be picked, and a route for the robot to take within the logistics facility. The robots can then autonomously navigate and position themselves within the logistics facility by recognition of landmarks by at least one of a plurality of sensors. The sensors also provide signals related to detection, identification, and location of a piece to be picked or put-away, and processors on the robots analyze the sensor information to generate movements of a unique articulated arm and end effector on the robot to pick or put-away the piece.

A seat frame assembling unit includes: a setting device and a setting robot. The setting device is driven in a state where side frames, a connecting frame, a pan frame, a member frame and an upper frame are arranged. The setting robot installs the side frames side by side and subsequently installs the connecting frame, the pan frame, the member frame and the upper frame between the side frames. The setting device moves the side frames to positions in which the side frames are to be assembled with the connecting frame, the pan frame, the member frame and the upper frame.

A prosthetic attachment for a prosthetic limb. A base is attached to the prosthetic limb. The base has a magnet that is surrounded by base valleys and base peaks. An attachment piece is attached to the prosthetic attachment. The attachment piece also has a magnet that is surrounded by attachment piece valleys and attachment piece peaks. The magnetic force between the base magnet and the attachment piece magnet attracts the prosthetic attachment to the prosthetic limb so that the base peaks and valleys mates with the attachment piece peaks and valleys for a secure removable attachment. In a preferred embodiment a locking device is used to further secure the prosthetic attachment to the prosthetic limb. In a preferred embodiment the prosthetic attachment is a prosthetic hand and the prosthetic limb is a prosthetic arm.

The present invention provides a smart stick assembly comprising a rod comprising a plurality of telescopic sections, wherein the rod having a proximal end and an opposing distal end. An illumination portion, disposed at the distal end of the rod, configured to illuminate. A camera, disposed at the distal end of the rod, configured to capture an image, or a video, or both. A sensor coupled to the camera to stabilize the camera during motion. The camera is configured to transmit the captured image and video to a remote communication device through the wireless transceiver. Further, detachable end effector coupled to the distal end of the rod and configured to perform an action.

An interactive laboratory robotic system is described that includes devices for use in a laboratory including a robotic assistant that can perform tasks and that can be controlled and configured by humans. The robot may assist personnel in performing repetitive tasks within a laboratory, and capture and store transactional and analytical data, such as during a DNA sequencing process. The robot may include sensors and/or cameras to detect, recognize, and track objects in an environment, and a manipulable arm having a hand for grasping objects. Other components of the system may include a sample tray graspable by the robot; a tray carriage for holding sample trays within equipment; an interactive shelf for holding sample trays; a mobile cart for mating with and charging the robot; and an accessory unit to enable the robot to open doors of equipment. The system may help to reduce or eliminate mistakes by personnel.

Some embodiments provide a magnet gripper system, comprising: a gripper base comprising a magnetically attractive face; at least two slide plate retaining systems; and two or more slide plates wherein at least one of the slide plates is movably cooperated with each of the at least two slide plate retaining systems such that the slide plates are configured to move between a retracted position with the slide plates retracted relative to the face of the gripper base and an extended position with the slide plates extended relative to the face of the gripper base with an end of each of the slide plates being positioned further from the face of the gripper base when in the extended position than when the slide plates are in the retracted position.

A magnetic end effector utilizing a switchable Halbach array includes a pair of opposing members that can move towards and away from each other. The switchable Halbach arrays are located on or near the inner surface of the opposing members. A mechanical switching system is used to control the switchable Halbach arrays by moving one or more magnets that make up the switchable Halbach arrays. When manipulated in a certain way, the switchable Halbach arrays cause the opposing members to move towards each other, and when manipulate in a different manner, cause the opposing members to move away from each other.

A robot hand and a robot having the robot hand, the robot hand having a mechanism configured to appropriately carry out surface matching between an electrical magnet and an adsorbed surface of a workpiece, corresponding to the posture of the adsorbed surface. The robot hand has: a hand base; a holder attached to the hand base; a spherical bearing arranged in the holder so that a rotational center of the spherical bearing is positioned on a hand center axis; a connecting member attached to the holder via the spherical bearing, the connecting member having a protruding portion which protrudes from the holder in a direction opposed to the hand base; a holder base fixed to an attachment surface opposed to an adsorbing surface of the electrical magnet; and a posture restoring member for restoring the posture of the holder base so that the holder base represents a neutral posture.