The cam-type timepiece component (1) has at least one portion of substantially planar shape, having a material hardness greater than or equal to 600 HV, the portion having a thickness greater than or equal to 200 microns, or even greater than or equal to 350 microns, or even greater than or equal to 400 microns, and at least one functional flank (3) which is substantially perpendicular to a main surface (2) of the portion and has a roughness Ra of less than or equal to 50 nm.

The disclosure relates to methods and systems for deep welding a workpiece, a surface of the workpiece being irradiated by a first laser beam and a second laser beam. In a workpiece surface plane (OE) a first beam width B1 of the first laser beam is larger than a second beam width B2 of the second laser beam and in at least the workpiece surface plane (OE) the second laser beam lies inside the first laser beam. The intensity of the first laser beam alone is sufficient to produce a keyhole in the workpiece. The keyhole produced in the workpiece has a width KB in the workpiece surface plane (OE), KB substantially equaling B1, and B2≤0.75*KB. The methods and systems provide good seam quality, high penetration depth, and high welding speed.

A substrate stack includes: at least two substrates including a base substrate and a cover substrate; at least one first laser weld line for welding the base substrate and the cover substrate; and at least one second beam spot or at least one second laser weld line at least one of situated next to the at least one first laser weld line or positioned such that a stress reduction in the at least one first laser weld line is achieved by the at least one second beam spot or second laser weld line, thus improving the mechanical stability of the substrate stack.

A method for manufacturing a peeled substrate has a laser condensing step for focusing laser light at a prescribed depth from the surface of a substrate and a positioning step for moving and positioning a laser condenser relative to the substrate, the method involving forming a processed layer in the substrate. The laser condensing step includes a laser light adjustment step in which a diffraction optical element is used to branch the laser light into a plurality of branched laser beams, and at least one of the branched laser beams is branched such that the intensity thereof differs from the other branched laser beams. The processed layer is elongated using the branched laser beam having a relatively high intensity among the plurality of branched laser beams to process the substrate, and the elongation of the processed layer is restrained using the branched laser beams having a relatively low intensity.

A method for processing a transparent workpiece comprises forming an optically modified region in or on a transparent workpiece and forming a contour in the transparent workpiece, the contour comprising a plurality of defects in the transparent workpiece positioned laterally offset from the optically modified region. Forming the contour comprises directing a primary laser beam comprising a quasi-non diffracting beam oriented along a beam pathway onto the transparent workpiece such that a first caustic portion of the primary laser beam is directed into the transparent workpiece, thereby generating an induced absorption within the transparent workpiece to produce a defect within the transparent workpiece and a second caustic portion of the primary laser beam is modified by the optically modified region. Further, translating the transparent workpiece and the primary laser beam relative to each other along a contour line and laterally offset from the optically modified region.

The invention relates to a method for the generative production of at least one component, a device for performing the method and a motor vehicle, in particular a passenger car. In a method for the generative production of at least one component, a powder of a material is irradiated by means of laser radiation so that it is heated and at least partially melted and the molten material solidifies in order to at least partially form the component. Information relating to the temperature of the material irradiated and/or to be irradiated, in particular thermal radiation, is detected and used for influencing the laser intensity. The laser radiation is conducted at least in sections by means of a light guide to the material and the information relating to the temperature is transmitted in the inner region of the light guide for the purpose of its detection.

A method for laser keyhole welding of metal alloys is disclosed. The method independently adjusts power in a focused center beam and power in a concentric focused annular beam. At the termination of a weld, the power in the center beam is initially ramped up and then ramped down, while the power in the annular beam is ramped down. Increasing the power in the center beam enables a controlled and prolonged contraction of the keyhole and melt pool, thereby preventing undesirable cracking.

An additive manufacturing system is disclosed that comprises two or more lasers for precisely heating a fiber-reinforced thermoplastic feedstock and a fiber-reinforced thermoplastic workpiece in preparation for depositing and tamping the feedstock onto the workpiece. The system employs feedforward, a variety of sensors, and feedback to ensure that the feedstock and workpiece are properly heated.

An additive manufacturing system is disclosed that comprises two or more lasers for precisely heating a fiber-reinforced thermoplastic feedstock and a fiber-reinforced thermoplastic workpiece in preparation for depositing and tamping the feedstock onto the workpiece. The system employs feedforward, a variety of sensors, and feedback to ensure that the feedstock and workpiece are properly heated.

A light source apparatus 1 includes: a light emitter 2 having a plurality of laser diode devices 22 and packages 24 to hold the respective laser diode devices; a collimator 3 disposed on an optical path of a laser beam emitted from each of the laser diode devices; a focusing lens 5 disposed on a downstream side in a direction of an optical axis of each laser diode device relative to the collimator 3 and configured to condense the laser beams; a light guide 6 disposed on the downstream side in the direction of the optical axis relative to the focusing lens 5; and a magnification optical system 4 disposed between the collimator 3 and the focusing lens 5 to bring a beam diameter Wα2-1 in a slow axis direction of the laser beam transmitted through the collimator 3 close to a beam diameter Wα1-2 in a fast axis direction.