[Object] To provide the method of manufacturing the friction material that is capable of uniformly scorching into the deep part of the surface layer of the friction material in a short period of time. [Means to Resolve] In the method of manufacturing the friction material including the scorching step of scorching the surface of the friction material with the laser, the friction material contains 5 to 25% by weight of one or more types of black materials relative to the total amount of the friction material composition, and the L* of the CIE Lab of the surface of the friction material before scorching is 20 to 60.

A method for improvement of adhesion and distribution along the surface of coatings using a femtosecond laser is described. The process starts from chemical preparation or cleaning of the target material, surface predetermination, laser irradiation of the surface until a certain surface geometry is obtained, which gives the surface improved wetting properties and chemical surface activation which results in improved adhesion of the coatings on the target material surface. The surface geometries and dimensions to be obtained during irradiation are selected according to the properties of the coating and target material, including the laser parameters and/or the environment to obtain the desired surface geometry, considering possible geometry errors without compromising essential adhesion.

A method for improvement of adhesion and distribution along the surface of coatings using a femtosecond laser is described. The process starts from chemical preparation or cleaning of the target material, surface predetermination, laser irradiation of the surface until a certain surface geometry is obtained, which gives the surface improved wetting properties and chemical surface activation which results in improved adhesion of the coatings on the target material surface. The surface geometries and dimensions to be obtained during irradiation are selected according to the properties of the coating and target material, including the laser parameters and/or the environment to obtain the desired surface geometry, considering possible geometry errors without compromising essential adhesion.

A multi-tubular beam for a vehicle, such as a vehicle structure or a bumper reinforcement, includes an elongated beam formed with a metal sheet. The metal sheet has a central section and outer sections extending along a length of the metal sheet. The outer sections are disposed in opposing directions from the outer edges of the central section to provide adjacent first and second tubular portions. The central section forms a common center wall between the adjacent first and second tubular portions. A first edge portion of the metal sheet is disposed along and in parallel alignment with the center wall. The first edge portion is attached to the center wall at a first weld joint to form the first tubular portion. The first weld joint includes a weld material that extends through a thickness of the center wall and into a thickness of the first edge portion.

Provided is a laser processing apparatus configured to machine a corner portion of a sample by causing the corner portion to relatively approach a laser, the laser being emitted such that an optical axis of the laser extends in a predetermined direction, the corner portion being formed by a plurality of adjacent surfaces of the sample, the laser processing apparatus including: a detection unit provided at a position at least outside an irradiation region of the laser, the irradiation region extending in a tubular shape in a plan view intersecting the optical axis, the detection unit being configured to detect intensity of light reaching the position; approach control means for controlling an actuator relatively displacing the sample along a direction intersecting the optical axis such that the sample relatively approaches the optical axis; value acquisition means for acquiring the intensity of the light defined as a value detected by the detection unit in a predetermined positional relationship in which a tip of the corner portion has reached the irradiation region; and relationship determination means for determining a positional relationship between the laser and the sample based on the intensity of the light detected by the detection unit while the sample relatively approaches the optical axis.

A method for comparing laser machining systems is provided, wherein a laser machining system comprises a laser machining head and a sensor module having at least one photodiode for detecting process radiation, said method comprising: detecting radiation emitted from a light source by means of the photodiode and generating a corresponding intensity signal, wherein the radiation is guided from the light source to the photodiode by at least one optical element in the laser machining head and/or by at least one optical element of the sensor module; aligning the laser machining head and the light source with one another so that the intensity signal assumes a maximum value; and comparing the intensity signal with at least one predetermined reference value. A method for monitoring a laser machining process and an associated laser machining system are also provided.

A laser processing apparatus of the present disclosure controls outputs of a blue laser oscillator and an infrared laser oscillator such that before a surface melting is detected on a workpiece, the workpiece is irradiated with at least blue laser light, and after the surface melting is detected on the workpiece, a power of infrared laser light with which the workpiece is irradiated is increased as compared to before the surface melting is detected.

A laser processing apparatus of the present disclosure controls outputs of a blue laser oscillator and an infrared laser oscillator such that before a surface melting is detected on a workpiece, the workpiece is irradiated with at least blue laser light, and after the surface melting is detected on the workpiece, a power of infrared laser light with which the workpiece is irradiated is increased as compared to before the surface melting is detected.

A hot wind is blown to a land and a lead from the underside of a printed board, to perform preheating. At the start of preheating or after start of preheating, a laser beam is applied to a soldering point, and meanwhile, wire solder is fed to a position contacting with the soldering point. The fed wire solder is melted by the laser beam. After soldering is finished, feeding of the wire solder is stopped. Application of the laser beam is stopped, to solidify the melted solder.

A method for cutting machining of a plate-shaped workpiece, including determining the position of the support points either by measuring or inferring the position of the support points and/or the relative position of the workpiece, establishing starting-point-free regions, establishing end-point-free regions, establishing starting-point-free and end-point-free regions depending on the inferred or measured position of the support points and/or the relative position of the workpiece, establishing a grid of possible starting points and end points, omitting the starting-point-free and end-point-free regions determined in advance, either calculating a torque in a stabilizing and/or tilting direction or calculating a tilt height and/or a tilt depth for each of the points on the grid, setting a priority of points on the grid, transmitting the priority of points to a route planning means of the cutting head, and selecting one of the points on the grid and carrying out the cutting machining.