The present invention provides a capture mechanism for capturing and locking onto the Marman flange located on the exterior surfaces of spacecraft/satellites. The capture mechanism achieves its goal of quickly capturing a target spacecraft by splitting the two basic actions involved into two separate mechanisms. One mechanism performs the quick grasp of the target while the other mechanism rigidises that grasp to ensure that the target is held as firmly as desired. To achieve a speedy grasp, the grasping action is powered by springs and an over-centre mechanism triggered either mechanically by a plunger or electronically by sensors and a solenoid. This forces two sets of jaws, one on either side of the object to be grasped, to close quickly over the target object. The jaws can be set up to grasp gently, firmly, or even not close completely on the target. The key is that they must close tightly enough so that the protrusions on the target cannot escape from the jaws due to any possible motions of the target. Once the jaws have sprung shut, a second mechanism draws the jaws (and their closing mechanism) back into the body of the tool pulling the captured target onto two rigidisation surfaces. The mechanism keeps pulling backwards until a pre-established preload is reached at which point the target is considered suitably rigidised to the capture mechanism.

A carrier plate assembly has a carrier plate and multiple gaskets. The carrier plate has a first end, a second end, and a carrier surface between the first end and the second end. The carrier surface forms multiple accommodating recesses. The gaskets are accommodated in the accommodating recesses. The gaskets prevent the wafer from sliding. Besides, with top surfaces of the gaskets aligning with the carrier surface and an edge of each gasket connected to an edge of an opening of the accommodating recess, the accommodating recess is filled by the gasket, and thus the gasket is securely accommodated in the accommodating recess and may not deform upward.

A machine (10) to automatically transport, from and to one or more working stations (12), one or more components (11) to make a package, comprises a reference surface (13), with which electric energizing members (14) are associated to selectively generate one or more magnetic fields, and at least a pair of support members (15) each provided with magnetic means (16) configured to interact with the magnetic fields. The machine (10) comprises control means (17) configured to energize selectively and in a coordinated manner the electric energizing members (14) to cause the selective movement of each support member (15) from one point to another of the reference surface (13). Each support member (15) is also provided with respective gripping means (18) comprising at least one support arm (19), wherein the support arm (19) of the first support member (15) is configured to cooperate with the support arm (19) of the second support member (15) to selectively temporarily grip and support at least one or more components (11).

This load reduction device is provided with: a shock absorption mechanism configured to absorb impact force generated when a user moves; a drive mechanism configured to output torque for reducing a load applied to the user at a joint of a leg of the user; and a torque control unit configured to control the torque output by the drive mechanism on the basis of operation of the shock absorption mechanism.

Provided is a robot hand that has a simple structure, can be used in a versatile way, changes shape depending on a physical object, and is less likely to damage the physical object. A robot hand that includes two or more finger portions making contact with a physical object and grips the physical object between the finger portions, wherein a gripping direction is nearly orthogonal to an extension direction of the finger portion and an outer shape of at least one phalanx portion is formed of a wire rod group configured with a plurality of loop-like wire rods having elasticity and arranged at predetermined intervals, and, wherein, in the wire rod group, the wire rods are arranged such that a loop shape extends in the extension direction of the finger portion and have an opening, which extends in the extension direction of the finger portion, between the wire rods.

A multipurpose machine for cultivating trees, comprising an inverted U-shape structure that enables the machine to pass over existing trees or fruit trees to carry out pruning, disinfection or fruit picking tasks, provided at the bottom with wheels, driven by at least one motor that autonomously facilitates the movement thereof, and respective upper frames that telescopically couple to each other, being driven by means of respective cylinders to move the portion of the structure on the right with respect to the one on the left in order to vary the width of the machine. Likewise, the machine has the ability to raise or lower the upper structure of the same to adapt it to the height of the trees to be cultivated.

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.

The invention relates to a charging infrastructure comprising a charging station (1) for charging a vehicle (10) having a vehicle-side charging interface (20), wherein the charging station (1) comprises a robot (50) that carries a robot-side charging interface (100) for establishing a charging connection with the vehicle-side charging interface (20), wherein the robot comprises a base frame (51), a movable carrier (60) carrying the robot-side charging interface, and at least three displacement assemblies (71-76) between the base frame and the movable carrier that form a mechanism to move the movable carrier with at least three degrees of freedom with respect to the base frame, wherein the displacement assemblies comprise an actuator (80) and a compliance assembly (90) in series with an actuator and the robot-side charging interface for resiliently absorbing or releasing a displacement between the actuator and the robot-side charging interface over a compliance stroke or angle.

In an apparatus for detecting a collision of a handling device with an obstacle, comprising at least one gas-filled chamber, which is surrounded by a flexible sheath that is deformable by collision with an obstacle and has a flexible supporting structure, wherein the supporting structure forms a damping element, which, together with the sheath, mechanically damps the forces that act in the event a collision, and also comprising a pressure sensor for measuring the gas pressure inside the chamber, wherein the apparatus is able to be attached to the handling device in a manner covering at least a first and a second region of the handling device, the sheath and the supporting structure are formed in one piece with one another and provide different degrees of damping from one another in the first and the second region.

The three-dimensional measuring method includes: a conveying step of conveying a workpiece to be measured by a robot arm configured to change an attitude of the workpiece; a measuring step of performing three-dimensional measurement on the workpiece by a probe configured to be movable relative to the surface plate in a state in which the workpiece is held by the robot arm; a relative-position change detecting step of detecting a change in a relative position between the surface plate and the robot arm; and a vibration correcting step of correcting a result of the measurement performed on the workpiece in the measuring step based on a result of detection performed in the relative-position change detecting step.