Abstract: The invention relates to a method for producing, in particular generatively producing, and coding a three-dimensional component. Said method comprises the following steps: providing a starting material, supplying a process gas to the starting material, melting the starting material by means of a heat source, and repeating the aforementioned steps. The method according to the invention is characterized in that, at least at a predetermined time interval during the melting of the starting material, a coding component or a coding gas containing a coding component is added to the process gas such that the use of the coding component in the finished object is detectable, and coding information is logged which describes the coding information and the location thereof in the component.

Abstract: The invention relates to a method for coding metal powder. Said method comprises the following steps: providing a melt, forming a melt stream, spraying the melt stream by means of a spraying fluid, and forming metal powder particles from the melt stream. The method is characterized in that, during the spraying of the melt and/or the spraying fluid, a coding component or a coding gas is added in such a way that the use of the coding component in the metal powder can be detected, wherein the gaseous coding component comprises one or more isotopes of at least one gas and the fraction of the at least one isotope is changed in comparison with the naturally occurring fraction of said isotope in the gas and/or wherein the gaseous coding component contains gaseous alloying elements.

Abstract: The invention relates to a method for producing, in particular generatively producing, and coding a three-dimensional component. Said method comprises the following steps: providing a starting material, supplying a process gas to the starting material, melting the starting material by means of a heat source, and repeating the aforementioned steps. The method according to the invention is characterized in that, at least at a predetermined time interval during the melting of the starting material, a coding component or a coding gas containing a coding component is added to the process gas such that the use of the coding component in the finished object is detectable, and coding information is logged which describes the coding information and the location thereof in the component.

Abstract: The invention relates to a method for coding metal powder. Said method comprises the following steps: providing a melt, forming a melt stream, spraying the melt stream by means of a spraying fluid, and forming metal powder particles from the melt stream. The method is characterized in that, during the spraying of the melt and/or the spraying fluid, a coding component or a coding gas is added in such a way that the use of the coding component in the metal powder can be detected, wherein the gaseous coding component comprises one or more isotopes of at least one gas and the fraction of the at least one isotope is changed in comparison with the naturally occurring fraction of said isotope in the gas and/or wherein the gaseous coding component contains gaseous alloying elements.

Abstract: A method for processing powdered starting materials includes a powdered material created and packaged under a protective gas atmosphere such that a protective gas is also present in the package, and the packaged powdered material is unpacked by a user and sent for further processing, wherein a gas detectable with sensors is supplied to the protective gas during packaging and/or in the packaging, or the protective gas is a gas that can be detected with sensors and the manufacturer and packager of the powdered material and/or the end user will examine the package with sensors to detect an escape of the detectable gas.

Abstract: A method of manufacturing an article comprising titanium and/or titanium alloy using an additive manufacturing method comprising: providing a substrate; providing a feedstock; and fusing the feedstock to the substrate using a heat source, wherein the substrate and/or feed stock comprises titanium and/or titanium alloy, and the fusing is conducted under a shielding gas comprising an inert gas and an oxidant gas.

Abstract: A method is provided for the gas assisted laser cutting of a metal, metal ahoy, plastic material, composite, ceramic or wooden workpiece with laser light of a wavelength between 300 nm and 2500 nm utilising carbon dioxide as the assist gas. Alternatively, an assist gas supply system is provided wherein a source of assist gas selected from the group consisting of one or more single gas cylinders, connected gas cylinders and gas cylinder bundles is used for supplying the assist gas to a gas assisted laser cutting device able to perform laser cutting.

Abstract: A laser apparatus comprises a laser having a lasing chamber an inlet to the lasing chamber for a lasing gas containing a heavy noble gas and an outlet from the lasing chamber for the discharge of a flow of lasing gas, wherein the outlet is able to be paced in communication with the atmospheric through an adsorptive trap containing a selective adsorbent of the heavy noble gas. In operation, the heavy noble gas (xenon or krypton) is adsorbed in the trap. The trap may be taken to a remote site for the recovery of the heavy noble gas when it is approaching saturation.

Abstract: A laser cutting head includes a lens for producing a waist in a laser beam, an internal chamber having an inlet for pressurised gas, an outlet nozzle for both the laser beam and a jet of pressurised gas which communicates with the internal chamber, an inner hollow generally cylindrical lens holder which holds the lens. The lens holder has a body which (i) makes sliding engagement with an outer sleeve, (ii) holds the lens and (iii), in use, is axially displaceable away from the nozzle. A plurality of transverse pins extends through slots in the outer sleeve to engage the body of the lens holder, and an outermost adjustable limit ring the axial position of which is able to be reproducibly set, and which engages the sleeve, the adjustable limit ring defining the axial position of the lens holder.

Abstract: A laser apparatus comprises a laser having a lasing chamber an inlet to the lasing chamber for a lasing gas containing a heavy noble gas and an outlet from the lasing chamber for the discharge of a flow of lasing gas, wherein the outlet is able to be paced in communication with the atmospheric through an adsorptive trap containing a selective adsorbent of the heavy noble gas. In operation, the heavy noble gas (xenon or krypton) is adsorbed in the trap. The trap may be taken to a remote site for the recovery of the heavy noble gas when it is approaching saturation.