A method for laser keyhole welding a stack of metal foils to a metal tab is disclosed. The method independently adjusts power in a focused center beam and power in a focused annular beam to form a weld through all the foils and the tab. The annular beam provides sufficient power to heat the metal to about melting temperature, widen a mouth of a keyhole, and stabilize a melt pool. The center beam provides sufficient additional power to form the keyhole. The power of the annular beam is sustained for a longer time than the power of the center beam. A plurality of such welds is formed to provide mechanical strength and electrical conductivity.

In a method for the manufacture of a transmissive optical system from a blank, material ablation is achieved on the blank with an ablative laser, and the pulse duration of the ablative laser is less than 1 ns, and preferably lies between 3 fs and 100 fs, or between 100 fs and 10 ps.

A method is provided for additively manufacturing an object. This method includes: depositing a layer of material on a build surface; consolidating at least a portion of the layer of material together to form a portion of the object, the consolidating comprising directing an energy beam onto the material to form a melt pool; directing a beam of light onto the melt pool; detecting a response from the beam of light interacting with the melt pool; and determining a parameter of the melt pool based on the detected response.

Disclosed are a method of controlling a size of a molten pool formed during a 3D printing process in real time and a system for the same. A thermal image of the molten pool is taken by a thermal imaging camera. A temperature interface exceeding a melting point of a base metal is specified in the thermal image. A size of the molten pool is obtained by estimating a length, a width, and a depth of the molten pool using the temperature interface. A predicted size of the molten pool is obtained using an artificial neural network model. An actually measured size of the molten pool is derived from a surface temperature of the molten pool. An error between the predicted size and the measured size of the molten pool is calculated to be used for controlling the size of the molten pool in real time.

A laser reflow apparatus reflows solder bumps disposed on a side of a semiconductor chip in a workpiece and included in an irradiation range on the workpiece by applying a laser beam to an opposite side of the semiconductor chip. The laser reflow apparatus includes a spatial beam modulation unit including a laser power density setting function to locally set the laser power density in the irradiation range of a laser beam emitted from a laser beam source, and an image focusing unit including an image focusing function to focus the laser beam emitted from the laser beam source and apply the focused laser beam to the irradiation range on the workpiece.

Proposed is a substrate heating unit including: a laser generator providing a laser beam for heating a substrate; and a beam shaper processing the laser beam from the laser generator and selectively providing one of a first beam having a uniform energy distribution and a second beam having an edge-enhanced energy distribution to the substrate.

A thin layer etching apparatus includes an etchant supply unit configured to supply an etchant onto a substrate to etch a thin layer formed on the substrate, a temperature measuring unit configured to measure a temperature of the substrate while an etching process is performed by the etchant, a laser irradiating unit configured to irradiate a first laser beam on a first portion including a central portion of the substrate and to irradiate a second laser beam in a ring shape on a second portion surrounding the first portion so that the temperature of the substrate is maintained at a predetermined temperature during the etching process, and a process control unit configured to control power of the first and second laser beams based on the temperature of the substrate measured by the temperature measuring unit to reduce a temperature difference between the first and second portions of the substrate.

The present invention discloses a method for producing a component containing copper by selective laser sintering, comprising the following method steps: —providing (S1) a metal power containing a copper-chromium alloy; —selectively melting (S2) the metal powder by laser radiation to produce the component; —heating (S3) the component to a temperature in the temperature range between 900° C. and 1000° C. in an oxygen-containing atmosphere; and —removing (S4) a chromium oxide layer formed on the surface of the component.

The invention relates to a method for laser beam plastic welding, having the following steps: arranging a first mold part which substantially absorbs laser radiation on a receiving area, irradiating the first mold part using an electromagnetic radiation source, detecting the heat of the first mold part by means of a detector, generating an absorption profile of the first mold part, arranging a second mold part which is substantially transparent to laser radiation on the first mold part, and irradiating the two mold parts along the contour of a welding seam to be produced using a machining laser such that the energy input produced by the machining laser is controlled by a controller on the basis of the generated absorption profile of the first mold part.

For the production of fibre waveguides mounted in a metal hollow profile, a flat metal strip is supplied to a deforming unit. The deforming unit is configured for continuously deforming the supplied flat metal strip into a shape corresponding to the hollow profile. The hollow profile is continuously welded along a longitudinal seam by means of a laser. A filler gel with a viscosity which increases with decreasing temperature, and one or more fibre waveguides, are introduced into the welded hollow profile in a continuous process via a guide or protective tube. In order to introduce the one or more fibre waveguides with an excess length into the hollow profile, the welded hollow profile is elastically stretched, is cooled, and is relaxed again. The finished product is received in a receiving unit. The continuous closed-loop control of the excess length of the fibre waveguides is performed inter alia through continuous open-loop control of the gel temperature, of the laser power and of the force exerted on the hollow profile for the elastic stretching.