Provided is a method for processing electronic and electrical device component scrap according to an embodiment of the present invention includes a smelting raw material sorting step of sorting a processing raw material containing valuable metals processable in a smelting step from the electronic and electrical device component scrap, wherein the method comprises removing lump copper wire scrap contained in the electronic and electrical device component scrap using a parallel link robot.

A remote center manipulator for use in minimally invasive robotic surgery includes a base link held stationary relative to a patient, an instrument holder, and a linkage coupling the instrument holder to the base link. First and second links of the linkage are coupled to limit motion of the second link to rotation about a first axis intersecting a remote center of manipulation. A parallelogram linkage portion of the linkage pitches the instrument holder around a second axis that intersects the remote center of manipulation. The second axis is angularly offset from the first axis by a non-zero angle other than 90 degrees.

A deep-sea mining apparatus for retrieving deep-sea nodules is provided. The deep-sea mining apparatus includes a buoyancy system, a payload hopper, an underwater autonomous vehicle (UAV), and a collector system. The collector system includes a controller system and a perception system communicatively coupled to the controller system and configured to track the deep-sea mining system as the deep-sea mining system hovers over ore nodules laying on a seabed. The collector system further includes one or more robotic arms controlled via the controller system, wherein each of the one or more robotic arms is attached to a bottom surface of the UAV and is equipped with a grasping mechanism configured to pick up the ore nodules from the seabed.

A driving device includes a corrector, an actuator, and a position sensor. The actuator includes a nut connected to a movable part, a ball screw shaft onto which the nut is screwed, and a pulse motor that drives to rotate the ball screw shaft. The corrector includes a correction amount map in which a position correction amount for calibrating a predictable error is mapped for each position of the movable part. The corrector estimates an ideal movement position to which the movable part moves based on a command signal and refers to the correction amount map to calculate the position correction amount corresponding to a present position detected by the position sensor. The corrector generates a correction signal by correcting the command signal so as to reduce the difference between a corrected present position obtained by correcting the present position by the position correction amount and the ideal movement position.

The invention includes a method and a handling system for manipulating and/or for handling piece goods (2) moved one after another in at least one row (1, 1a, 1b) in a transport direction (TR) on a horizontal conveying device (6). In each work cycle, seizing at least one transported piece good (2) from the at least one row (1, 1a, 1b) by at least one handling device (10); spatially separating it from the row (1, 1a, 1b); and bringing it into a specified relative target position and/or target alignment relative to subsequent piece goods (2). After a failure event with an at least a temporary standstill of the horizontal conveying device (6) and/or of the handling device (10), the handling device (10) is initialized, and, after the failure has been remedied, the horizontal conveying device (6) automatically restarts and continues the previously interrupted process.

A method determines a wrapping configuration of a film wrapped around products to form a palletized load to be moved along a path. The method includes using a defined wrapping configuration, measuring physical quantities acting on the load as a result of movements and/or stresses when the load is moved along different test paths, obtaining a path as a suitable composition of base elementary path stretches, obtaining physical quantities acting on the load along the path as physical quantities associated to the base elementary path stretches, positioning the load on a motion platform, operating the motion platform based on the physical quantities to simulate movements and/or stresses acting on the load moved along the path, checking if the load has remained stable and/or compact, modifying the wrapping configuration if the load did not remain stable and/or compact, and repeating the steps.

In one embodiment, a robotic system comprises: a robot comprising a robotic actuator and at least one robotic arm mechanically coupled to the robotic actuator; a suction gripper mechanism that comprises: a linear shaft element; an internal airflow passage within the linear shaft configured to communicate an airflow between an airflow application port at a first end of the linear shaft and a gripping port positioned at an opposing second end of the linear shaft; a suction cup assembly comprising a suction cup element coupled to the gripping port; and an actuator configured to rotate the linear shaft in order to articulate an orientation of the suction cup assembly.

A robotic system includes a support structure, a platform, a center serial chain, outer serial chains, motors, a sensor, and a control module. The center serial chain connects a center of the platform to the support structure and includes first joints connected to a linear sliding shaft. The outer serial chains are disposed radially outward of the center serial chain. Each of the outer serial chains includes second joints connecting a bar to the platform and the supporting structure. The motors are connected to the outer serial chains. The sensor is connected to the platform and detects at least one of force or torque applied by a human operator on the platform and generates a signal indicative thereof. The control module controls the motors based on the signal to assist the human operator in at least one of moving or rotating the platform.

A single-layer three-section rail-type planar robot containing a double parallelogram, is composed of a stationary platform, a motion platform and three branched chains with the same structure connecting the stationary platform and the motion platform, the stationary platform is provided with three planar curved rails, each planar curved rail is connected to the motion platform through a branched chain, and each branched chain includes a slider, two link bars I arranged in parallel, two link bars II arranged in parallel, and link bar III, select one revolute joint I in each branched chain to form three revolute joints I as the main driving joint or three sliders as the driving parts.

A geared parallel manipulator of the SCARA type is provided that consists of a pair of motors, each driving in a controlled manner a pinion. The two pinions mesh each with a rack, said two racks being joined together via a revolute, or via a flexure hinge. The proposed parallel manipulator is simple in design and can be fabricated inexpensively of stamped sheet metal or of extruded parts. It can also be fabricated as a microelectromechanical system (MEMS) using thin film technologies.