A method for machining at least one workpiece surface to apply a texture pattern to at least one section of the workpiece surface using a laser, based on image data specifying an image of the texture pattern applied to the at least one section of the workpiece surface and model data specifying a three-dimensional geometry of a surface form corresponding to the at least one section of the workpiece surface. Control data and segment data are generated based on the image and model data. The control data specify one or more segment sequences for each track line. Each segment sequence has track segments where the laser guides the texture pattern application to the at least one section of the workpiece surface; wherein the track segments of a segment sequence include one or more laser track segments where the laser travels in the switched-on state at a constant machining setpoint speed.

A method according to one aspect of the present disclosure is a laser marking method for a powder compact containing metal powder, which includes: a first step of scanning with laser light of first power which is weaker over a predetermined area in a surface of the powder compact, to melt and smooth inside of the predetermined area; and a second step of scanning with laser light of second power which is greater, to form a dot formed of a recess of a predetermined depth at a predetermined location in the predetermined area.

A joined article includes a first component having a laser-treated surface portion and a second component having a laser-treated surface portion. An adhesive joins the first component to the second component at the treated surface portion. A method of making a joined article form components and a system for making joined articles are also disclosed.

The disclosure relates to maskless, laser-assisted methods for making a metal surface comprising at least one of hydrophobic and hydrophilic regions; and at least one of micro- and nanostructured regions.

A device configured for a treatment with a laser, including a support transparent for the laser and at least one optoelectronic circuit including at least one optoelectronic component having a three-dimensional semiconductor element covered with an active layer, the three-dimensional semiconductor element including a base bonded to the support, the device including a region absorbing for the laser resting on the support and surrounding the base.

A system for manufacturing elastomeric components is provided. The system may include a molding station having a mold configured to receive an elastomeric material, form a pad that includes a plurality of untrimmed elastomeric components, and cure the pad. The system may further include an automated marking station comprising a laser and a camera. The automated marking station may be configured to remove the cured pad from the molding station, present the cured pad to the laser to form a mark on each of the untrimmed elastomeric components, and present the cured pad to the camera to capture an image of each mark. A process for manufacturing the elastomeric components is also provided.

A textured surface of oil and gas equipment includes a first substrate, an antiwear coating, and a second substrate, and further includes a texture, where the texture includes a first texture and/or a second texture; the first substrate and the second substrate are capable of moving relative to each other when operating, the first texture is arranged on a surface of the first substrate that is in contact with the antiwear coating, the second texture is arranged on a surface of the antiwear coating that is in contact with the second substrate. A method for machining the textured surface of oil and gas equipment is provided, which improves various performances of the oil and gas equipment such as antifriction, wear resistance, and corrosion resistance by combining a coating with a texture, so as to prolong the service life of the oil and gas equipment, increase oil and gas production efficiency.

Provided are a magnetostrictive torque sensor shaft with excellent processing accuracy and stability of quality and a preferred method for manufacturing the shaft. The magnetostrictive torque sensor shaft has an amorphous thermal spray coating on the surface of a substrate made of a metal material, the amorphous thermal spray coating having a magnetostrictive property and being formed by thermal spraying, and the substrate surface being subjected to surface roughening by laser irradiation. The laser irradiation is performed in the surface roughening process prior to the amorphous thermal spraying and in pattern formation process after the thermal spraying.

A product includes a fine periodic structure having a plurality of projection portions extending parallel to each other in a first direction in each of a first region and a second region adjacent in the first direction on a surface of a substrate. The fine periodic structure formed in an inner portion of the first region and the fine periodic structure formed in an inner portion of the second region are substantially the same periodic structures. End portions of the plurality of projection portions formed in the first region and end portions of the plurality of projection portions formed in the second region are formed in a boundary portion between the first region and the second region.

A manufacturing process may comprise: stacking a plurality of friction discs together, each friction disc comprising a lug defining a surface; and depositing a composition to bond to the surface of a first friction disc in the plurality of friction discs to form a wear pad defining a wear surface.