A water-abrasive suspension cutting facility includes a pressure tank (11) for providing a water-abrasive agent suspension (13) which is under pressure, a lock chamber (21), and a refilling valve for refilling abrasive agent into the pressure tank via the lock chamber (21). The refilling valve (21) includes a valve entry (49), a valve exit (51), a valve space (71) which is arranged between the valve entry (49) and the valve exit (51), and a valve body (67) which is located in the valve space (71). The valve entry (49) is connected to the lock chamber (21) and the valve exit (51) to the pressure tank (11). The refilling valve (19) can assume a first closure position, a first open position and a second open position. In the first closure position the lock chamber (21) is fluid-separated from the pressure tank.

A translatable, ultra-high pressure liquid jet system includes a translatable frame configured to maintain mechanical contact with a rail. The liquid jet system includes a liquid jet processing head affixed to the frame and configured to maintain a distance from the rail and provide a liquid jet that contacts the rail. The liquid jet system also includes an ultra-high pressure liquid pump in fluid communication with the liquid jet processing head. The ultra-high pressure liquid pump is configured to supply pressurized liquid to the liquid jet processing head.

A processing device for processing a material with a focused blasting medium, having at least a blasting medium source for generating the blasting medium and a conveying device for the material, or additionally a deflecting means for deflecting the blasting medium emitted by the blasting medium source toward the material; wherein the conveying device is arranged opposite the blasting medium source or the deflecting means in such a way that the material, at least with a region to be processed by the blasting medium, can be processed by the conveying device on a circular path opposite the blasting medium source or the deflecting means, so that the material, when the blasting medium source or the deflecting means is moved, can be processed along the circular path with a constant focus position of the blasting medium. A method for processing a material with a focused blasting medium in a processing device.

A conveyance system 14 carries food products 12 past the scanning system 16 for scanning the food products and generating data pertaining to various parameters of the food products. Thereafter, the food products 12 are transported past a processing station 18 for cutting, trimming, portioning, etc. using a cutting apparatus 20 in the form of a robotic actuator 22 onto which is mounted a dual headed cutter assembly 24 capable of independently and simultaneously cutting/trimming/portioning two separate food products 12, for example, located in side-by-side lanes on the conveyance system or capable of independently and simultaneously cutting/trimming the opposite sides of the same food product.

A waterjet system in accordance with at least one embodiment of the present technology includes a cutting head and an associated catcher assembly. The cutting head directs an abrasive-containing waterjet toward a workpiece supported by a cutting deck of the catcher assembly. The catcher assembly also includes a tank and a container fluidly connected to the tank. The tank contains abrasive-containing liquid in which the waterjet diffuses after the waterjet passes through the workpiece. The container collects abrasive at least primarily by shielding abrasive-containing liquid within the container from at least some turbulence of abrasive-containing liquid within the tank during operation of the waterjet system. The catcher assembly also includes a quick-release coupling through which the container is removably connected to the cutting deck. Operating the quick-release coupling allows the container to be removed to dispose of the collected abrasive.

The invention relates to an abrasive wateget cutting system (2) including: an abrasive watcrjct cutting head (14) comprising: a nozzle (16) adapted for guiding an abrasive wateget (6) intended to cut a metallic workpiece (4); an abrasive wateget flow direction (12); a monitoring device (28) including at least an upstream sensor and a downstream sensor which are distributed along the abrasive wateget flow direction (12) downstream the inlet end of the nozzle (16), and which are adapted for measuring at least one wear characteristic of the nozzle (16) or a characteristic of the abrasive wateget (6), or an alignment characteristic of the nozzle (16) with an orifice (18). The sensors comprise a set of accelerometers (40; 42) and a set of microphones (44; 46). The wear monitoring device (28) being configured to monitor at least one characteristic of the abrasive wateget cutting system (2) through at least the upstream sensor and the downstream sensor.

A method cuts a, in particular flat, workpiece by a cutting beam and a cutting fluid. A workpiece part to be cut away is consecutively cut into at least two smaller portions which fall or are lowered downwards from a surrounding remaining workpiece after they have each been cut away. The division into smaller portions and the execution of the cut for separating the first smaller portion occur such that the point at which the first-cut, first smaller portion is cut away lies within the outer contour of the workpiece part to be cut away.

A machine for separative machining of a plate-shaped workpiece by a processing beam. The machine has a first movement unit for moving the workpiece in a first direction, a second movement unit for moving a processing head in a second direction, two workpiece bearing supports for bearing the workpiece, and a parts chute. The two workpiece bearing supports are separated from each other by a gap that extends along the second direction. The parts chute is movable between a first chute position and a second chute position so as to move a cut-free workpiece part that has dropped into the gap, laterally away from the gap. The machine includes a receiving unit movable in the second direction, to receive the cut-free workpiece part at a transfer position and transport the workpiece part to one or more discharging positions of the machine along the second direction.

A method for centering device on a cutting device using an ultrahigh pressure (UHP) hose carrying UHP fluid that is designed to be inserted into a pipe or tube and cut the same from the inside out. In one example, the cutting device is for insertion into a wellbore for cutting the casing of the wellbore from within the wellbore with a revolvable UHP hose. The cutting head which effectuates the cut may be centered by the centering device that is generally conical in shape such that a portion of the centering device remains exterior to the pipe or tube as the UHP revolves during the cutting action.

In some aspects, material processing head can include a body; an antenna disposed within the body; a first tag, associated with a first consumable component, disposed within a flux communication zone of the body at a first distance from the antenna, the first tag having a first resonant frequency; and a second tag, associated with a second consumable component, disposed within the flux communication zone of the body at a second distance from the antenna, the second tag having a second resonant frequency that is different than the first resonant frequency, where the first and second resonant frequencies are tuned based upon at least one of: i) a difference between the first distance and the second distance; or ii) a characteristic (e.g., shape) of the flux communication zone in which the first tag and/or the second tag is disposed.