A computer numerically controlled machine may include a source of electromagnetic energy. A beam of electromagnetic energy from the source may be delivered to a destination such as, for example, a material positioned in a working area of the computer numerically controlled machine. The beam of electromagnetic energy may be susceptible to interferences while traveling from the source to the destination. The computer numerically controlled machine may include a beam detector configured detect an interference of the beam by measuring a power of the beam of electromagnetic energy at a location between the source and the destination. An interference of the beam may be detected if the power of the beam is less than a threshold value. A controller at the computer numerically controlled machine may perform one or more actions in response to the beam detector detecting the interference of the beam of electromagnetic energy.

A test device to calibrate the pulse energy of a laser device which provides pulsed laser radiation includes a measuring head with multiple measuring probes. The test device is used in such a way that by means of the laser radiation, multiple test ablations are made on a test surface, in an arrangement corresponding to the relative spatial arrangement of the measuring probes, and the depths of the test ablations are then measured, with simultaneous use of the multiple measuring probes of the measuring head.

This shaping apparatus is equipped with: a movement system which moves a target surface; a measurement system for acquiring position information of the target surface in a state movable by the movement system, a beam shaping system that has a beam irradiation section and a material processing section which supplies a shaping material irradiated by a beam from beam irradiation section; and a controller. On the basis of 3D data of a three-dimensional shaped object to be formed on a target surface and position information of the target surface acquired using the measurement system, the controller controls the movement system and the beam shaping system such that a target portion on the target surface is shaped by supplying the shaping material while moving the target surface and the beam from beam irradiation section relative to each other.

The purpose of the present invention is to provide a method for measuring the inclination of a waterjet relative to a machine coordinate system of a laser machining device. The present invention provides a method for measuring the inclination of a waterjet of a laser machining device in which a laser beam that has been introduced and guided into a waterjet jetted from an optical head is moved relative to a workpiece fixed to a table so as to machine the workpiece, wherein measured is the inclination of the waterjet relative to the table which is within a stable-length range in which the laser beam passing through the inside of the waterjet can be reflected so as to advance in the axial direction.

Disclosed herein is a laser beam spot shape detection method for detecting a spot shape of a laser beam oscillated by laser beam oscillator and collected by a condenser in a laser machining apparatus, the laser beam spot shape detection method including: a concave mirror holding step of holding a concave mirror having a spherical face forming a reflecting face with a chuck table; a focal point positioning step of positioning the focal point of the condenser in a proximity including the center of the spherical face forming the reflecting face of the concave mirror held by the chuck table; a laser beam irradiation step of irradiating a laser beam onto the held concave mirror, and an imaging step of capturing images of reflected light with a camera.

A laser power control device includes a storage unit that stores relational data having a measurement value of a heat radiation sensor, which measures intensity of heat radiation of an irradiation object irradiated with a laser beam from a laser machining device in association with a power value of the laser beam on a machining surface of the laser machining device.

A laser processing method is performed in a laser processing apparatus which outputs a laser beam from a processing head to a workpiece, to perform laser processing while controlling reflected light of the output laser beam to a prescribed value or less. The laser processing method includes the step of, before performing laser processing for the workpiece, increasing laser power stepwise from laser power lower than laser power included in a processing condition of the laser processing, to emit a laser beam from a laser oscillator, and measuring reflected light by a reflected light sensor, and the step of deciding an output condition for decreasing reflected light based on a measured value of the reflected light and the prescribed value, and the step of decreasing reflected light before performing the laser processing by irradiating the workpiece with a laser beam for a predetermined period of time on the decided output condition.

A laser processing device has a preprocessing controller which issues a command to perform preprocessing of a workpiece under high output conditions, which are previously found by an experiment or calculation in accordance with at least some of processing conditions and which include the irradiation intensity and irradiation time, at which a workpiece is melted, changed in shape, or denatured; a command to irradiate the workpiece with a laser beam under low output conditions, which are previously found by an experiment or calculation in accordance with at least some of the processing conditions and which include the irradiation intensity and irradiation time, at which a workpiece is not melted, changed in shape, or denatured; and a command of whether to start the laser processing, based on a first light quantity of light reflected or emitted from a processing point irradiated with a laser beam under the low output conditions.

A laser processing device having a function for reducing intensity of a reflected laser beam, without stopping laser oscillation, in order to avoid a malfunction due to the reflected beam. A controller for controlling a laser oscillator has: a laser processing commanding part configured to output a laser processing command; a memory configured to store monitored intensity of the reflected beam and a laser output condition; a pre-processing commanding part configured to command a pre-processing prior to the laser processing command; a comparing part configured to compare the stored intensity of the reflected beam to a first judgment value and/or a second judgment value lower than the first judgment value; an output condition changing part configured to set or change the laser output command of the pre-processing command based on a comparison result; and a pre-processing terminating part configured to terminate the pre-processing based on a predetermined condition.

The present invention relates to a technique to assess dependence of laser machining on laser light intensity with high accuracy by a simple method. First, machining state information showing a machining state by laser machining at a machining position on a workpiece is acquired. Before or after that, or at the same time as that, intensity distribution information showing intensity distribution of laser light at the machining position is acquired. Dependence of the laser machining of the workpiece on the laser light intensity is assessed based on the acquired machining state information and intensity distribution information. For example, it is possible to acquire a breakage threshold for a workpiece in laser machining in a highly accurate and simply manner.