An abrasive for jet cutting including particles of a stainless steel is provided, the stainless steel includes a microstructure, the microstructure including at least martensite, in a range of ≥20 wt. % to ≤100 wt. %, austenite in a range of ≥0 wt % to ≤50 wt %, and chromium carbide, chromium nitride and/or mixtures thereof, together in a range of ≥0 wt % to ≤45 wt % based on the microstructure, the proportions being selected such that together they amount to ≤100 wt % based on the microstructure. The abrasives for jet cutting exhibit particularly good lifetime and recyclability. Also provided is a suspension for jet cutting including at least the proposed abrasive for jet cutting and a suspending agent, as well as the use of the abrasive for jet cutting for cutting a workpiece.

Disclosed herein are components, systems, and methods for accessing and disassembling components of hazardous articles. A cutting head of a fluid jet system generates a fluid jet that exits an outlet toward a workpiece to be cut by the fluid jet. A shroud of the fluid jet system radially surrounds the outlet, and contains an inert substance through which the fluid jet travels between the outlet and the workpiece. A fluid jet system includes a sensor to capture an acoustic parameter of the impact of a fluid jet with a workpiece, and upon detection of a change in the acoustic parameter, discontinues generation of the fluid jet. A fluid jet system includes a sensor to measure thicknesses of various regions of the workpiece and a processor to select a path to cut the workpiece based on the measured thicknesses.

A process for terminating an optical fiber with a ferrule includes the steps of: (a) providing an optical fiber and ferrule with an end of the optical fiber extending beyond a surface of the ferrule; and (b) directing a jet comprising an air-abrasive mixture at the end of the optical fiber to cleave the end of the optical fiber from the remainder of the optical fiber.

A method for removing a component fixed to an aeronautical part, the aeronautical part comprising a first material, and the component comprising a second material different from the first material, the method comprising steps of determining the thicknesses of the component as a function of the position on the component, and of removing the component by means of a pressurized water jet moving over the component as a function of the thicknesses determined in the determination step.

A fluid jet cutting device for sectioning materials is provided. The device includes a compact and portable body having an equipment chamber accessible through a first panel, a working chamber accessible through a second panel and a receptacle in communication with the working chamber. A pump assembly and motor are removably positioned on a base in the equipment chamber. A guide assembly is positioned in the working chamber and a cutting head having a nozzle is movably coupled to the guide assembly for movement along three axes. A drive assembly moves the cutting head along the guide assembly. A clamp for holding a work piece includes a first face and a second face movable relative to the first face so as to secure regular, irregular or complex shaped work pieces. A basket is positioned in the receptacle below the clamp and the device may be controlled by way of a touch screen user interface.

A system for cutting an underwater structure, the system comprising: a cutting head, said cutting head comprising: an abrasive water jetting nozzle; a cryogenic nozzle; said abrasive water jetting nozzle and cryogenic nozzle mounted in fixed spaced relation; said cutting head arranged to position tips of the nozzles proximate to a cutting surface, and arranged to form a cutting zone defined by the nozzle tips and cutting surface; wherein a water repelling shield is located about said cutting zone and arranged to hinder water entering said cutting zone.

A collecting and discharge device for the cutting jet of a fluid jet cutting system, comprises a cutting jet collector and a discharge for the cutting medium flow collected the cutting jet collector. The cutting jet collector has a jet discharge channel with an inlet region for introducing the cutting jet. The cutting jet is in flow connection with an outlet region via an discharge line. The jet discharge channel leads into a suction chamber disposed underneath the outlet region, said suction chamber having an enlarged cross section in the outlet region compared with the cross section of the jet discharge channel. The suction chamber additionally connects the jet discharge channel with the discharge line and with a suction channel as well as being otherwise closed. The suction channel provides suction at a suction opening forming a suction mouth in a suction region surrounding the inlet region of the jet discharge channel.

The invention relates to a method for producing molded bodies from a silicon alloy, comprising the production of plates and the water jet cutting of the plates to form a plurality of molded bodies. The thus obtained molded bodies contain in particular additional inoculant additives and are used in particular as inoculant for metal casting.

A water-abrasive suspension cutting facility (1) includes a high-pressure source (3) for providing (301) water at a high pressure, a high-pressure conduit (5) which is connected to the high-pressure source (3) and a pressure tank (11) for providing (303) an abrasive agent suspension (13) which is at a high pressure. The pressure tank (11) is fluid-connected to the high-pressure conduit (5) via a regulatable throttle (17). The throttle (17) is arranged at the entry side of the pressure tank (11) and is configured to regulate the feed flow into the pressure tank (11) from the high-pressure conduit (5) in dependence on at least one control variable.

An apparatus to recover incoherent material present in a process fluid to be treated (F1) comprises a separation device (13) to separate, by means of centrifugal action, the incoherent material (M) from the process fluid (F) and a pumping unit (12) configured to remove the process fluid to be treated (F1) from a collection zone (11) and send it to the separation device (13).