An example system includes a laser tool configured for downhole movement. The laser tool includes an optical assembly configured to shape a laser beam for output. The laser beam may have an optical power of at least one kilowatt (1 kW). A housing contains the optical assembly. The housing is configured for movement to direct the output laser beam within a wellbore. The movement includes rotation of the laser tool around a longitudinal axis of the housing and tilting the housing relative to a longitudinal axis of the wellbore. A control system is configured to control at least one of the movement of the housing or an operation of the optical assembly to direct the output laser beam within the wellbore.

An optical arrangement for direct laser interference structuring. A laser beam is directed to a reflecting mirror with inclined surface and strikes a first beam splitter, it is divided into two partial beams and one partial beam is deflected to a focusing element. The second partial laser beam is directed to a first pentamirror and after multiple reflection and/or refraction, the focusing element, or it is directed to a second beam splitter and is divided into a first partial beam and a third partial beam. The partial beams are directed to the focusing element by the first pentamirror and are directed by the focusing element to the surface to be structured interfering with each other. The reflecting mirror is moved in a translational manner, maintaining a 45° angle parallel to the optical axes of the emitted laser beam influencing the interference period Λ.

A laser processing system and a laser processing method that reduce irregularities on a cutting surface caused by a variation in a heat affected zone or a difference in the heat affected zone due to processing by a laser beam. The laser processing system is provided with: a laser processing device that scans a composite material containing reinforced fibers and a resin with a laser beam to process the composite material; and a control device that controls the laser processing device. The control device calculates a scanning angle formed by a fiber direction that is a direction of the reinforced fibers and a scanning direction that is a direction in which the laser beam is caused to scan, calculates a scanning condition of the laser beam on the basis of the calculated scanning angle, and controls scanning of the laser beam on the basis of the calculated scanning condition.

According to one implementation, a laser peening processing apparatus includes a laser oscillator, a condensing lens, an optical element, a liquid tank and a beam expander. The laser oscillator oscillates laser light. The condensing lens condenses the laser light on a surface of an object. The optical element changes a travelling direction of the laser light. The liquid tank inputs the laser light into liquid, and emits and ejects the laser light and the liquid from an exit to the surface. The beam expander adjusts a magnifying ratio of a beam diameter of the laser light entering into the condensing lens. By adjusting the magnifying ratio, a beam diameter of the laser light irradiating the surface becomes a diameter required for laser peening processing of the surface. The adjusting the magnifying ratio also prevents the laser light, having an excess beam diameter, from entering into the optical element.

A filler feed wire (20) including both a laser conductive element (26) and a filler material (22) extending along a length of the wire. Laser energy (30) can be directed into a proximal end (32) of the laser conductive element for melting a distal end (34) of the feed wire to form a melt pool (24) for additive fabrication or repair. The laser conductive element may serve as a flux material. In this manner, laser energy is delivered precisely to the distal end of the feed wire, eliminating the need to separately coordinate laser beam motion with feed wire motion.

A system and method for automated laser ablation includes an end effector for performing laser ablation at a location with restricted access. The systems and methods of the present disclosure specifically provide for a miniature laser end effector which may be inserted through a port or bore in order to ablate the surface of an internal component of a complex assembly. In several embodiments of the present subject matter, the end effector is mounted on a machine and coupled to a laser system.

The present invention provides an online laser leveling detection method of a 3D printer. The method comprises: (1), arranging a bar-shaped triangular reflecting prism and a bar-shaped photoelectric receiver; (2), fixedly mounting a laser emitter and a plane mirror on the side face of a printer head; (3), with the aid of a detection laser beam, fine tuning the mounting azimuths of an X-axis guide rail, a Y-axis guide rail, and the printer head till the motion levelness of the printer head is adjusted to meet requirements of the design accuracy of the printer; (4), with the aid of the detection laser beam, fine tuning the mounting azimuth of a printing platform till the mounting levelness of the printing platform is adjusted to meet the requirements of the design accuracy of the printer; (5), starting the 3D printing program; (6), in the printing process, detecting in real time whether a nozzle of the printer head generates faults including material blockage, shortage, and breakage. The present invention communicates detection signals of a laser detection system with a printer control system and designs the signal processing program to achieve detection of the motion levelness and the mounting levelness as well as monitoring of extrusion faults of the printer head.

A device for fabricating a quartz microfluidic chip by a femtosecond pulse cluster. The device includes: a femtosecond pulse cluster laser source configured to output a femtosecond pulse cluster; a beam splitting and interference system, configured to split the femtosecond pulse cluster into a plurality of parts, and to converge split parts to form a femtosecond pulse cluster plasma or a femtosecond pulse cluster plasma grating; a sample system configured to move the electronic displacement platform where a quartz glass is placed to control a position where the parts of the femtosecond pulse cluster are converged on the quartz glass; and a hydrofluoric acid immersion system configured to immerse the quartz glass in a diluent hydrofluoric acid solution to remove an ablated part of the quartz glass to form the quartz microfluidic chip.

The present invention relates to a laser apparatus using optical fibers for stable laser welding and a laser welding method using same. Hybrid ring mode-shaped laser beams, in which a central beam using fiber laser is positioned at the center of outer beams using diode laser, are used to perform welding by irradiating a to-be-welded portion of an object with the outer beams, the central beam, and the outer beams in this order. Thus, since the welding is performed using the central beam as a heat source in a state in which the to-be-welded portion of the object has been heated with a sufficient amount of heat input, the temperature gradient of the to-be-welded portion is low and solidification cracking does not occur. Also, problems such as spatter and voids can be minimized, and the laser welding is stable, and thus a quality of welding that is uniform and stable overall can be obtained.

Systems, devices, apparatuses and methods for formation of multiple separate light spots with adjustable intensity due to lossless redistribution of the light energy between the separate spots, and with a variable geometry of the multi-spot pattern; advantageously, for laser processing of materials by focusing the laser radiation on a workpiece. The multi-spot pattern is created due to angular polarization splitting of the light beam into several beamlets using a beam splitter and further focusing these beamlets onto a workpiece by a focusing optical system, advantageously by the scanning focusing optics. The beam splitter can include optical birefringent prisms, prism groups and waveplates capable to operate simultaneously at two different wavelengths. Some of these optical elements are rotatable, and their rotations are used for lossless redistribution of light energy between the spots and for a change in the geometric shape of the multi-spot patterns. Embodiments can provide various geometrical configurations of 2, 3, 4, 9 and more separate focused spots: linear, rhombus-shaped, square, parallelogram, rectangular patterns composed in the form of a line or a matrix, with the ability to vary portions of the light energy at the specified separate spots.