A focusing state measuring apparatus for measuring a focusing state of a working apparatus with respect to a target object so as to perform work includes: a base plate installed in the working apparatus performing work on the target object and spaced apart from the target object; a first line beam generation unit provided on one side of the base plate and configured to irradiate a first line beam toward the target object; and a second line beam generation unit provided on one side of the base plate so as to be spaced apart from the first line beam generation unit in a first direction and configured to irradiate a second line beam toward the target object. The focusing state of the working apparatus with respect to the target object is determined according to states of the first line beam and the second line beam.

Methods, devices, apparatus, and systems are described for separating workpiece parts from workpieces using a focused machining beam. The methods include creating a trough in the workpiece using the focused machining beam, the trough being created along at least one section of a contour of the at least one workpiece part to be separated from the workpiece, altering a focal position of the machining beam such that the machining beam has a smaller beam diameter on the workpiece, and creating a gap in the workpiece using the machining beam with the altered focal position along at least one section of the contour of the at least one workpiece part to be separated from the workpiece. The gap is created at least partially within the trough.

The invention relates to a machining head (1) for laser machining machines, in particular for laser cutting machines, having an interface to a laser light source (3), preferably to fiber-coupled or fiber-based laser sources. Said laser sources are designed for more than 500 W of average output power in the near infrared region. The interface is preferably designed for coupling an optical waveguide (2) for the working laser beam (6). The machining head (1) also has a focusing optical unit (11) having preferably only one imaging lens. A deflecting assembly (9, 10) for at least one single deflection of the working laser beam (6) is arranged between the interface and the focusing optical unit (11). Said deflecting assembly (9, 10) is designed as a passive optical element that changes the divergence of the working laser beam (6) in dependence on power.

A unit vector calculating unit of a laser machining device obtains a unit vector based on respective current rotational positions of an A-axis and a B-axis. A movement command calculating unit, a speed command calculating unit, or a torque command calculating unit generates a command signal for maintaining a gap amount at a constant value, based on the unit vector, and the gap amount between a machining nozzle and a workpiece. With a servo control unit, on the basis of the command signal, an X-axis motor, a Y-axis motor, and a Z-axis motor are controlled, whereby the machining nozzle is moved relatively in three-dimensional directions with respect to the workpiece.

Disclosed embodiments include a head attached to a gantry. The head includes an optical assembly to focus a laser beam onto a surface of a material to be processed by a CNC machine and a measurement assembly with emitter(s) and detector(s), where the detector(s) are for measuring intensity of light emitted from the emitter(s) and reflected off the surface of the material. Processors are configured to (i) determine a material type of the material, (ii) determine a distance between the optical assembly and the material surface based on (a) measurement(s) of the intensity of the light emitted from the emitter(s) and reflected off the material surface, and (b) measurement parameter(s) associated with the determined material type, and (iii) control focusing of the laser beam onto the surface of the material based on the determined distance between the optical assembly and the surface of the material.

A laser cutting apparatus includes a laser oscillator; an output control unit for a laser beam; a cutting head configured to emit the laser beam; a gap sensor; an axial mechanism configured to activate the cutting head; an axial control unit; a detection unit configured to detect reflected light intensity; a storage unit configured to store an output value of the laser beam, reflected light intensity, a detection value of the gap sensor, and positional information of the axial mechanism; and a correlation table generation unit configured to output an instruction to operate the axial mechanism and the laser oscillator, and generates a correlation table configured to obtain a correlation between the output value of the laser beam and the reflected light intensity, a correlation between the positional information and the reflected light intensity, and a correlation between the detection value and the positional information.

In known methods for through-cut detection in the thermally assisted through cutting of a workpiece, the workpiece is subjected to a first alternating signal. Starting therefrom, to indicate a method which allows a fast and accurate detection of a through-cut made, it is suggested according to the invention that the method comprises the following method steps:

a) detecting a second alternating electrical signal caused by the first alternating electrical signal in a measurement electrode spaced from the workpiece,

b) determining the phase shift between first and second alternating electrical signal with output of a phase shift signal,

c) detecting a temporal evolution of the phase shift electrical signal or a measurement variable derived therefrom in a predetermined time interval,

wherein a workpiece through-cut made is detected in that the phase shift signal or the measurement variable derived therefrom is in the time interval within a predetermined fluctuation range.

A laser processing method which can efficiently perform laser processing while minimizing the deviation of the converging point of a laser beam in end parts of an object to be processed is provided. This laser processing method comprises a preparatory step of holding a lens at an initial position set such that a converging point is located at a predetermined position within the object; a first processing step (S11 and S12) of emitting a first laser beam for processing while holding the lens at the initial position, and moving the lens and the ltd object relative to each other along a main surface so as to form a modified region in one end part of a line to cut; and a second processing step (S13 and S14) of releasing the lens from being held at the initial position after forming the modified region in the one end part of the line to cut, and then moving the lens and the object relative to each other along the main surface while adjusting the gap between the lens and the main surface after the release, so as to form the modified region.

Laser material processing systems having beam positioning assemblies with fluidic bearing interfaces and associated systems and methods are disclosed herein. In one embodiment, a laser material processing system includes a beam positioning assembly configured to position a laser beam. The beam positioning assembly includes a first linear guide having first guide surfaces and a second linear guide having second guide surfaces. The first linear guide is moveably coupled to the first linear guide via the first guide surfaces. The second linear guide is moveably coupled to a carriage via the second guide surfaces. At least one fluidic bearing interface is positioned to prevent direct physical contact between the second linear guide and at least one of the first guide surfaces and/or between the carriage and at least one of the second guide surfaces.

A laser machining method includes a first piercing process of forming a non-through piercing hole extending from a top surface to a central portion of a workpiece; a workpiece cooling process; a second piercing process of making the piercing hole pierce to a bottom surface of the workpiece; and a workpiece cutting process. The second piercing process includes performing piercing by irradiating the workpiece with a laser beam while changing the output of the laser beam from a second output value to a third output value, which is smaller than the first output value and larger than the second output value, the focal position from a first in-focus position to a second in-focus position having a larger in-focus amount than the first in-focus position, and the depth of focus from a second depth deeper than a first depth to a third depth deeper than the second depth.