A gripping tool, which can be used by a manipulator device for picking-up and handling pieces, includes a plurality of gripping devices (50), distributed in groups, each group consisting of one or more gripping devices. The gripping devices (50) of each group of gripping devices are mounted on a same supporting body (P), which is made in one-piece by an additive manufacturing technology.

A cleaning apparatus includes at least one detection device for detecting soiling on a vehicle to be cleaned and at least one cleaning device for cleaning the vehicle. A control device controls the at least one cleaning device in dependence on the detected soiling. The at least one cleaning device includes at least one multi-axis robot for positioning a cleaning element relative to the vehicle. The cleaning apparatus enables simple, fast and reliable automatic cleaning of the vehicle.

System and method for non-contact manipulation of objects via ultrasonic levitation are presented herein. In one embodiment, a method for a non-contact manipulation of an object includes: generating ultrasound field by an array of ultrasound transducers; lifting the object off a dispensing device by the ultrasound field; and levitating the object by the ultrasound field.

A continuum arm robot system comprising at least a first continuum arm robot and a second continuum arm robot, each continuum arm robot being controlled by its own actuator pack, and each actuator pack being coupled to a single control computer, wherein at least the second continuum arm robot comprises a releasable connection mechanism to engage in gripping the first continuum arm robot in a workspace, so as to link the at least two continuum arm robots into a single redundant robotic system with at least the second continuum arm robot providing support for the first continuum arm robot.

Disclosed is a method for the automated transfer of an intraocular lens (1) comprising an optical lens body (10) and two haptics (11) attached to a peripheral edge of the optical lens body (10) and extending outwardly from the peripheral edge of the optical lens body (10). The method comprises the steps of: picking the intraocular lens (1) up at a start location; moving the intraocular lens (1) to a destination location; releasing the intraocular lens (1) at the destination location,
wherein picking the intraocular lens (1) up at the start location comprises gripping the intraocular lens (1) only at the haptics (11) of the intraocular lens (1).

A vacuum chuck system may include a vacuum chuck and a vacuum stopper collection and dispensing system. The vacuum chuck may include a ceramic plate with a retaining surface. The retaining surface may include a plurality of depressions and a plurality of openings, each of the openings being disposed on a bottom surface of one of the depressions and fluidly coupled to a vacuum pump. Vacuum stoppers may be used to seal one or more of the openings so as to restrict the vacuum area of the vacuum chuck. The vacuum stopper collection and dispensing system may be used to collect vacuum stoppers from and dispense vacuum stoppers onto the retaining surface. In addition or in the alternative, an electromagnet or a robotic arm may be used to move a vacuum stopper from a blocking position to a non-blocking position on the retaining surface.

A computer-implemented dynamic supporting base creation method that interacts with a three-dimensional (3D) printer that prints an object, the method including providing a physical support, via a first robotic gripper, for an object during three-dimensional (3D) printing using a printing head of the 3D printer and transferring the object to a second robotic gripper to provide a physical support at a different location on the object.

A method includes steps of: capturing an image of a container; recognizing at least one object in the container based on the image; determining at least one first coordinate set corresponding to the at least one object; determining at least one second coordinate set that corresponds to target one (s) of the at least one first coordinate set and that relates to a fixed picking device of a robotic arm; adjusting position(s) of unfixed picking device(s) of the robotic arm if necessary; controlling the robotic arm to pick up one (s) of the at least one object that correspond(s) to the at least one second coordinate set with the fixed picking device and/or at least one unfixed picking device.

The robot hand holds a wire harness having a long harness main body and a connector connected to an end of the harness main body. The robot hand includes a fixed holding portion which holds the harness main body a vicinity of the end thereof, a pressing portion movable relative to the fixed holding portion in a longitudinal direction of the harness main body held by the fixed holding portion, and a driving unit which moves the pressing portion in a direction away from the fixed holding portion such that the pressing portion presses the connector outwardly in the longitudinal direction of the harness main body.

An unpacking device (4) for unpacking an additively manufactured three-dimensional object (2) from the unsolidified construction material (3) surrounding it after completion of an additive construction process, wherein the unpacking device (4) is formed as a robot (7) having at least three robot axes (A1-A6), especially an industrial robot, wherein at least one unpacking tool (10) is arranged or formed on a robot axis (A6), which is provided for unpacking an additively manufactured three-dimensional object (2) from the unsolidified construction material (3) surrounding it after completion of an additive construction process, or the unpacking device (4) comprises at least one such robot (7).