By optimizing equipment and processing, magnetic domain miniaturization efficiency can be increased, workability can be improved, and processing ability can be increased through same. Provided is a method for miniaturizing the magnetic domains of a directional electric steel plate, the method comprising: a steel plate supporting roll position adjusting step of controlling the vertical direction position of a steel plate while supporting the steel plate progressing along a production line; and a laser emitting step of melting the steel plate by emitting a laser beam to form grooves on the surface of the steel plate, wherein the laser emitting step includes an angle changing step of changing an emitting line angle of the laser beam with respect to a width direction of the steel plate while an optical system emitting the laser beam onto the steel plate is rotated with respect to the steel plate, and a focal distance maintaining step of changing a tilt of the steel plate supporting roll which supports the steel plate according to a change in focal distance of the laser beam in the width direction of the steel plate.

A laser machining method includes, before laser machining: calculating the amount of focus movement on the basis of a first measurement value measured with the external optical system warmed up and being the amount of energy of a laser beam passing through a small-diameter hole and a first reference value (database D1) predetermined depending on the type of contamination of the external optical system in relation to the first measurement value; and compensating the focus position in laser machining on the basis of the calculated amount of focus movement.

The present disclosure provides three-dimensional (3D) printing methods, apparatuses, systems and/or software to form one or more complex three-dimensional objects. The three-dimensional object may be formed by three-dimensional printing one or more methodologies. The three-dimensional object may comprise an overhang portion and/or cavity ceiling with diminished deformation and/or auxiliary support structures.

A laser welding method and a laser welding apparatus capable of preventing formation of blowholes and obtaining an excellent welled state are provided. An embodiment is a laser welding method for a component to be welded 40 including a third metal component 40c sandwiched between first and second metal components 40a and 40b, in which the metal components are welded to each other by scanning a laser beam in a first direction perpendicular to a direction in which the third metal component 40c is sandwiched, in which a welded part 42 is formed by applying a first laser beam 12a while scanning it in the first direction and thereby melting and then solidifying the component to be welded 40.

Additive manufacturing can involve dispensing a powdered material to form a layer of a powder bed on a support surface of a build platform. A portion of the layer of the powder bed may be selectively melted or fused to form one or more temporary walls out of the fused portion of the layer of the powder bed to contain another portion of the layer of the powder bed on the build platform.

A laser processing head includes first and second contact points connected to a power source. The power source generates a current to flow through an electrode wire between the first and second contact points to heat the electrode wire. A laser source generates one or more laser beams having lasing power sufficient to at least partially melt the electrode wire. A coaxial laser head focuses the one or more laser beams at one or more focal points on a workpiece to at least partially melt the electrode wire.

A laser welding method includes a welding process of irradiating a multiple laser beam so as to weld together a first member and a second member at a boundary. The multiple laser beam includes a first beam that is advanced while forming a first molten pool in which the first member is melted, a second beam that is advanced while forming a second molten pool in which the second member is melted, and a main beam that is advanced subsequently to the first beam and the second beam and irradiated to an integrated molten pool formed by integration of the first molten pool and the second molten pool. The first beam and the second beam do not swing, while the main beam swings with respect to the boundary.

A simultaneous laser welding apparatus of a vehicle light comprising a placement support for a container body and a lenticular body of a vehicle light to be welded together at reciprocal perimeter profiles associated at a welding interface, a plurality of laser sources suitable for emitting light beams, a plurality of optical fibres associated with the laser sources at input ends and suitable for transmitting said light beams, a fibre-holder support device for the optical fibres, suitable for blocking output ends of said optical fibres in predetermined positions, spaced apart by a pitch, a light guide provided with at least one seat which extends from a light input wall, which receives the light beams coming from the output ends of the optical fibres, to a light output wall which sends the light beams towards the welding interface. Advantageously, a single optical fibre is associated at its input end with each laser source so as to receive, channel and transmit towards the welding interface, the light beam produced by said corresponding laser source.

To provide a galvanometer scanner that increases reliability by reducing burden on a mechanism unit. A galvanometer scanner converts a command for machining position on a machining target to movement commands for a rotary motor, a rotary motor, and a direct drive mechanism. If the movement command for the direct drive mechanism contains a weak direct drive component depending on the movement command for the rotary motor, and falling within an amplitude range not exceeding a predetermined amplitude and within a frequency range not falling below a predetermined frequency, the galvanometer scanner removes the weak direct drive component from the movement command for the direct drive mechanism, and then outputs control signals corresponding to the movement commands for the rotary motors and the direct drive mechanism. The galvanometer scanner controls the rotary motors and the direct drive mechanism based on the control signals.

Disclosed are a laser scribing apparatus, an equipment and a control method thereof. The laser scribing apparatus includes: a light source configured to emit a laser, and a beam splitter unit including a beam splitter and a light control component, the beam splitter and the light control component are sequentially provided along the optical path of the laser, the beam splitter is configured to split the laser into multiple scribing beams, and the light control component is configured to control the multiple scribing beams to pass along a same path in sequence.