A laser machining method performing cutting machining to cut a composite material over a thickness direction thereof by applying a laser beam to the composite material. The method includes applying the laser beam from one side in the thickness direction of the composite material so as to form a first cutout in the composite material; and applying the laser beam from the other side in the thickness direction of the composite material, forming a second cutout in the composite material at a position opposing the first cutout, connecting the second cutout to the first cutout, and cutting the composite material. The first cutout is formed by applying the laser beam through a plurality of machining paths arranged in the width direction of the first cutout. The second cutout is formed by applying the laser beam through a plurality of machining paths arranged in the width direction of the second cutout.

A method for performing cutting machining by applying a laser beam to the surface of a base material formed from a composite material and cutting the base material to be cut out a product from the base material, a machining line, serving as a boundary between the product to be cut out and a remainder which is the base material after the product is cut out, is set to the base material before the cutting machining, and a plurality of machining paths along the machining line are set to be arranged from the machining line side to the remainder side with the machining line side as a reference. In the cutting machining, the base material is cut by repeatedly executing a laser beam application step for applying the laser beam to the surface of the base material on the basis of the plurality of machining paths having been set.

An additive manufacturing system is disclosed that heats a feedstock and a workpiece in preparation for depositing and tamping the feedstock onto the workpiece. The system comprises a first laser/optical instrument pair for precisely heating the feedstock and a second laser/optical instrument pair for precisely heating the workpiece. The laser beam from each laser is shaped into an ellipse and each beam is rotated around an angle of rotation to ensure that the feedstock and the workpiece are properly heated. The system employs feedforward, a variety of sensors, and feedback to adjust the angle of rotation of each laser beam.

An additive manufacturing system is disclosed that heats a feedstock and a workpiece in preparation for depositing and tamping the feedstock onto the workpiece. The system comprises a first laser/optical instrument pair for precisely heating the feedstock and a second laser/optical instrument pair for precisely heating the workpiece. The laser beam from each laser is shaped into an ellipse and each beam is rotated around an angle of rotation to ensure that the feedstock and the workpiece are properly heated. The system employs feedforward, a variety of sensors, and feedback to adjust the angle of rotation of each laser beam.

A composite member having an excellent heat resistance is provided. The composite member includes: a substrate composed of a composite material including a non-metal phase and a metal phase; and a metal layer that covers at least a portion of a surface of the substrate, wherein a metal included in each of the metal phase and the metal layer is mainly composed of Ag, and a ratio of a content of Cu to a total content of Ag and Cu in a boundary region of the metal layer with the substrate is less than or equal to 20 atomic %.

A method for laser soldering includes selecting a copper-containing material as a filler material, supplying the filler material at a butt joint of two components, and melting the filler material in a main process zone by means of laser radiation in an advancement direction. The filler material in the main process zone is melted by means of laser radiation of a wavelength λH in the blue or green spectral range with 400 nm≤λH≤600 nm.

Methods for welding a particle-matrix composite body to another body and repairing particle-matrix composite bodies are disclosed. Additionally, earth-boring tools having a joint that includes an overlapping root portion and a weld groove having a face portion with a first bevel portion and a second bevel portion are disclosed. In some embodiments, a particle-matrix bit body of an earth-boring tool may be repaired by removing a damaged portion, heating the particle-matrix composite bit body, and forming a built-up metallic structure thereon. In other embodiments, a particle-matrix composite body may be welded to a metallic body by forming a joint, heating the particle-matrix composite body, melting a metallic filler material forming a weld bead and cooling the welded particle-matrix composite body, metallic filler material and metallic body at a controlled rate.

A laser machining device includes: a laser irradiation unit that forms a machining groove that has one end opening to an end section of a workpiece and the other end thereof closed, as a result of scanning a workpiece surface from an end section of the workpiece and laser machining the workpiece; and a nozzle unit that sprays a gas across an irradiation zone of the workpiece surface created by the laser irradiation unit. The nozzle unit is configured so as to increase the flowrate of the gas supplied to the irradiation zone, from one end to the other end of the machining groove.

A method of manufacturing a high-pressure fluid vessel includes forming a first portion of a high-pressure fluid vessel with a molding process. The high-pressure fluid vessel includes a stack of capsules. Each capsule includes a first domed end, a second domed end, and a semicylindrical portion extending between and connecting the first domed end to the second domed end. The method further includes forming a second portion of a high-pressure fluid vessel with the molding process. The second portion of the high-pressure fluid vessel is positioned adjacent to the first portion of the high-pressure fluid vessel. The second portion of the high-pressure fluid vessel is welded to the first portion of the high-pressure fluid vessel.

According to one aspect, the present disclosure provides a system for manufacturing transition structures including fiber threads embedded within a metal component. The system may include a supply of base sheet metal. The system may include a conveyor supported on a plurality of rollers and configured to move the base sheet metal in a production direction. The system may include a plurality of stages arranged in the production direction. Each stage may include a channel forming device configured to form a channel in the base sheet metal, a fiber inserting device configured to insert a portion of a fiber material into the channel, and one or more ultrasonic welders configured to consolidate a layer of metal foil over the fiber. The disclosure includes methods of using the system to produce transition structures and reinforced components.