An apparatus for unstacking plate-like parts with at least one supply station, in which at least one part stack of plate-like parts is located and with an unstacking device which is assigned to the supply station and is for the singularised unstacking of the part stack and for bringing an unstacked part along a run-through direction onto a function station which is arranged downstream. The unstacking device includes a carrier device with at least one runner rail which is aligned along the run-through direction and on which an unstacking slide is movably guided in the run-through direction between the supply station and the function station. The unstacking slide includes a carrier structure on which several gripping units are arranged. The gripping units each include at least one gripping head which can be moved in the height direction for lifting the parts out of the part stack.

A produce packing robot is provided comprising a plurality of heads for picking up items of produce from a plurality of pick-up locations, and moving the items of produce and dropping them off at a plurality of drop-off locations. The plurality of heads move together in a first direction on a common rail. The robot may also comprise a range imaging camera and controller for sensing the location of the drop-off points dynamically.

A two-phase liquid immersion cooling system is described in which heat generating computer components cause a dielectric fluid in its liquid phase to vaporize. Advantageously an absorption/desorption unit is employed having a carbon element and a controller configured to regulate the absorption unit.

A two-phase liquid immersion cooling method is described in which heat generating computer components cause a dielectric fluid in its liquid phase to vaporize. The dielectric vapor is then condensed back into a liquid phase and used to cool the computer components. Using a pressure controlled vessel and pressure controller, a cooling system may be operated at less than ambient pressure. By controlling the pressure at which the system operates, the user may influence the temperature at which the dielectric fluid vaporizes and thereby achieve increased performance from a given computer component.

Systems and methods for automated assembly of a B.sub.0 magnet assembly for use in a point-of-care MRI system are provided herein. A gripper capable of gripping a permanent magnet with a high clamping force is provided for positioning the permanent magnet in the B.sub.0 magnet assembly in accordance with a permanent magnet layout. A robot having multiple degrees of freedom is provided for positioning the gripper. Components of the system described herein have been developed to withstand the effects of strong magnetic forces generated by high-strength magnetic fields surrounding the B.sub.0 magnet assembly.

A robotised construction system is provided that includes a cartesian robot that can be automatically lifted as the construction is becoming higher, that is provided with a system of robotic supply of the materials and of the electric and electronic installations and that is provided with specific fabrication tools which work some by the contribution of layers of fluid construction materials. In a cement-based usage in which the cement is setting and having been deposited, by projection of these same materials and others by forming and placing construction elements in a determined position.

A trajectory control device includes: a contact sensor that can contact side surfaces of a workpiece; an actuator that moves a trajectory tracking member and the contact sensor; and a trajectory controller that calculates XY coordinates of a trajectory on the workpiece that is placed in an arbitrary position, by transforming XY coordinates of the trajectory on the workpiece in a reference position, based on positional information about the side surfaces of the workpiece in the reference position and positional information about the side surfaces of the workpiece placed in the arbitrary position. The positional information about the side surfaces of the workpiece placed in the arbitrary position is obtained by the contact sensor.

A method for synchronous control of a gantry mechanism with online inertia matching is applicable to a machine tool equipped with a gantry mechanism. The gantry mechanism includes two rails, a crossbeam and a saddle, in which the saddle is disposed on the crossbeam, and the crossbeam is disposed by crossing the two rails. Each of the two rails is furnished with a driving apparatus for synchronously driving the crossbeam, and the driving apparatus includes a drive motor and a lead screw. This method includes the steps of: obtaining gantry-mechanism information; detecting position information of the saddle on the crossbeam; evaluating the position information and the gantry-mechanism information to derive load-inertia variety information; and, evaluating the load-inertia variety information to adjust torque-output information of the drive motor corresponding to the respective driving apparatus.

Feedback information is an important aspect in all machine learning systems. In robot systems that are picking objects from a plurality of objects this has been arranged by acquiring images of objects that have been picked. When images are acquired after picking they can be imaged accurately and the information about picking and also dropping success can be improved by using acquired images as a feedback in the machine learning arrangement being used for controlling the picking and dropping of objects.

A method of processing objects using a programmable motion device is disclosed. The method includes the steps of perceiving identifying indicia representative of an identity of a plurality of objects and directing the plurality of objects toward an input area from at least one input conveyance system, acquiring an object from the plurality of objects at the input area using an end effector of the programmable motion device, and moving the acquired object toward an identified processing location using the programmable motion device. The identified processing location is associated with the identifying indicia and the identified processing location is provided as one of a plurality of processing locations along a first direction. The step of moving the acquired object includes moving the programmable motion device along a second direction that is substantially parallel with the first direction.