The invention relates to a fuel cell membrane handling device comprising a first membrane storage station (A1) and a receiving station (C) as well as a first manipulator (B1) comprising means (68) for gripping a membrane (12) from a free face thereof, the first manipulator (B1) being articulated so as to be capable of moving between a position for taking a membrane (12) from the storage station (A1) and a position for placing a membrane (12) in the receiving station (C). According to the invention, the receiving station (C) comprises a tray for receiving a membrane (12) comprising at least one opening (C2) wherein the gripping means (68) and a portion of the manipulator are capable of fitting into a first position for placing a membrane (12) wherein the membrane (12) is received on the receiving tray (C1).

Methods of operating a gripper are provided. The methods include providing a robot including the gripper, the gripper moveable by the robot and including gripper fingers, providing a sample rack including receptacles accessible by the gripper, at least some of the receptacles adapted to contain specimen containers, providing data, obtained by imaging, regarding the sample rack and the specimen containers therein, and determining, based on the data, an accessible target receptacle for one of a pick operation or a place operation. Apparatus and systems configured to carry out the methods are provided, as are other aspects.

A robotic arm assembly having an arm with at least one end effector pivotally connected to the end of the arm. The robotic arm assembly has a continuous belt driven by two motors. Manipulation of the speed and direction of the two motors controls the length of the arm and the tilt of the end effector. A third motor controls the tilt of the arm.

The invention discloses an automatic-sensing transfer device based on an edge-tracing alignment algorithm, which is characterized by comprising a device body, a rotating device, a lifting device, a stretchable device, a sensing device, a gripping device and a control device. The rotating device, the stretchable device, the lifting device, the sensing device, the gripping device and the control device are all arranged on the device body. The control device is connected to the rotating device, the stretchable device, the lifting device, the gripping device and the sensing device. Accurate positioning of the gripping device can be realized through the transfer device, so that the production efficiency is improved.

A construction robot for a ceiling is provided. The construction robot includes: a robot base having an upper plate; a targeting unit on the upper plate, wherein the targeting unit moves a robotic arm assembly combined with the targeting unit, and wherein the robotic arm assembly includes: a first robotic arm where a drill is mounted, wherein a first elevating unit of the first robotic arm is elevated or lowered according to information on the ceiling, a second robotic arm where an anchor bolt inserting equipment is mounted, wherein a second elevating unit of the second robotic arm is elevated or lowered according to the information, and a third robotic arm where an impact wrench is mounted, wherein a third elevating unit of the third robotic arm is elevated or lowered likewise; and a loading unit on the upper plate or the targeting unit for providing anchor bolt assemblies.

The present disclosure provides a smart grabbing device including: a controller, a container configured to accommodate articles, a grabber configured to grab the articles, and a movable mover. The mover is at a bottom of the container; the grabber is on the container; and both of the grabber and the mover are electrically coupled with the controller. The controller is configured to, control the mover to drive the smart grabbing device to move to a target position, and control the grabber to grab a target article and place the target article in the container.

A fully autonomous mobile robot is provided that transports items from one area to another. The mobile robot includes a variety of mechanisms that capture an item from a first surface and moves the item within the confines of the mobile robot. The item can then be transported to another surface either within the confines of the mobile robot or to another location.

Methods of performing a plurality of operations within a region of a part utilizing an end effector of a robot and robots that perform the methods are disclosed herein. The methods include collecting a spatial representation of the part and aligning a predetermined raster scan pattern for movement of the end effector relative to the part with the spatial representation of the part. The methods also include defining a plurality of normality vectors for the part at a plurality of predetermined operation locations for operation of the end effector. The methods further include moving the end effector relative to the part and along the predetermined raster scan pattern. The methods also include orienting the end effector such that an operation device of the end effector faces toward each operation location along a corresponding normality vector and executing a corresponding operation of the plurality of operations with the operation device.

A film peeling method is disclosed to peel off a film covered on the surface of an object. The method includes the steps of: setting a fulcrum located at outer side of the object; setting a lift-off position on the film; and picking up the film from the lift-off position with the fulcrum as the axis, and applying a circular traction force with a variable radius on the film for peeling off the film from the object. The film peeling method can peel off the film covered on the surface of the object by different peeling stages, to reduce the peeling path and reduce the force required for peeling the film, thereby reducing the peeling time and improving the peeling efficiency.

A fully autonomous mobile robot is provided that transports items from one area to another. The mobile robot includes a variety of mechanisms that capture an item from a first surface and moves the item within the confines of the mobile robot. The item can then be transported to another surface either within the confines of the mobile robot or to another location.