The present invention discloses a 3D diffraction coating process, the operation is simple, due to the principle of newton's rings of single light sources, superimposition of optical wave-wavlet vibration during wave transmission of light and diffraction, refraction, reflection, transmission, transmission increase and reflection increase of the light, slit diffraction generated by a round hole, a rectangular hole and a line in a pattern internally coated in the product is conducted to an outer glass layer to form a diffraction layer, and finally, a muitilayered 3D visual effect is generated, and the manufactured finished product has a good 3D effect, and is very exquisite and high-class.

An alloy comprising about 0.5 weight percent to about 2 weight percent carbon, about 15 weight percent to about 30 weight percent chromium, about 4 weight percent to about 12 weight percent nickel, up to about 3 weight percent manganese, up to about 2.5 weight percent silicon, up to about 1 weight percent zirconium, up to about 3 weight percent molybdenum, up to about 3 weight percent tungsten, up to about 0.5 weight percent boron, up to about 0.5 weight percent impurities, and iron.

An insulation film peeling method which radiates laser light onto a front end portion of an insulation film-coated conducting wire including a conducting wire and an insulation film in a longitudinal direction, and which peels a part of the insulation film up to a peeling boundary of a predetermined regulated peeling length, includes performing a rectilinear scan of a first region, in which a radiation position of the laser light moves from one side toward the other side and then moves from the other side toward the one side upon reaching the other side, and performing a unidirectional scan of a second region, in which the radiation of the laser light is performed from one side toward the other side and then the radiation position returns to the one side in a state in which the radiation of the laser light stops upon reaching the other side.

A welding system includes at least one high intensity energy source to create a weld puddle during a root pass on a narrow joint of a workpiece with a clad layer. The system also includes a controller to control a weld ramp out process such that, as the molten puddle advances to a start of an existing root pass weld, the controller at least one of decreases an energy output of the at least one high intensity energy source and reduces an interaction time between the at least one high intensity energy source and the weld puddle. After completion of the root pass, a thickness of a root pass weld in a region that is at or near the start point of the existing root pass weld is in a range of 100 percent to 130 percent of a nominal root pass thickness of a remainder of the root pass weld.

Provided is a device for assembling a fuel supply pipe of which a joint portion between a pipe body and a short cylindrical member has a high strength and which has high anti-corrosion performance. Specifically, while a laser beam in a defocused state is being emitted to impinge on an end portion of the pipe body that overlaps the short cylindrical member, the pipe body and the short cylindrical member are rotated through one complete turn relative to the laser beam, thereby melting the entire periphery of the end portion. While the laser beam in a defocused state is being emitted to impinge on the melted end portion, the pipe body and the short cylindrical member are rotated through at least one further complete turn, thereby joining by welding the end portion to the outer periphery of the short cylindrical member.

A method for removing a plastics coating from a block of food, in particular a whole cheese, operates with the following steps: the block of food, in particular the whole cheese with its plastics coating is fed to the method. A laser beam is then directed onto the plastics coating of the block of food. Herein the output of the laser which emits the laser beam is adjusted so that a removal of the plastics coating takes place by separation of a region of the plastics coating and/or by erosion or vaporisation of the plastics coating. A device for removing a plastics coating from a block of food, in particular a whole cheese, comprises a transport apparatus for the block of food and a laser apparatus for applying a laser beam to the block of food.

A method for processing a foil comprising lithium includes irradiating the foil with a laser beam having a wavelength of between 200 nm and 1 μm.

The present invention relates to a composite container comprising a bottom film layer and a top film layer at least partially adhered to the bottom film layer. The top film layer is scored to form at least one resealable flap and at least one pull tab which is not adhered to the bottom film layer. The bottom film layer comprises at least one cavity opening. A cardboard layer is adhered on its lower surface to the upper surface of the top film layer, wherein the cardboard layer has at least one cavity opening which is substantially aligned with the scoring of the top film layer resealable flap and the cardboard layer is perforated to define a perimeter of at least one pull tab which is substantially aligned with and adhered, on its underside, to the upper surface of the top film layer pull tab.

The invention relates to a method for producing an optical component (1) by means of laser radiation. The object of the invention is that of providing a method that is improved compared with the prior art, which method allows for the correction of deviations of the optical functionality of the component from specified target parameters. For this purpose, the method according to the invention comprises the following method steps: generating a structure in the material of the component (1) which gives the component (1) an optical functionality, and modifying the refractive index in the material of the component (1) by means of laser beams in a pre- and/or post-processing step, i.e. before or after the generation of the structure, in order to correct deviations of the optical functionality of the component (1) from specified target parameters.

A joint structure formed by resistance welding a plurality of superposed steel sheets includes a high tensile strength steel sheet having a tensile strength of at least 590 MPa and containing a chemical component having a carbon equivalent Ceq of at least 0.53%. The high tensile strength steel sheet has a decarburized layer between a base plate and a galvanized layer formed on at least one of a surface on a superposition surface side and a surface on a welding electrode side of the high tensile strength steel sheet, or has a decarburized layer on a superposition surface of the high tensile strength steel sheet adjacent to a galvanized layer of a galvanized steel sheet to be superposed. The decarburized layer has a thickness of at least 5 μm and at most 200 μm, and the carbon equivalent Ceq is a value defined by a formula: Ceq=C+Si/24+Mn/6.