A method of heating a selected portion of an object includes the steps of projecting an energy beam onto a surface of the object and repetitively scanning the beam in accordance with a scanning pattern so as to establish an effective spot on the surface, and displacing the effective spot along a track to progressively heat a selected portion of the object. The selected portion has a first width at a first position along the track and a second width at a second position along the track. The second width is less than 75% of the first width.

The scanning pattern is repeated with a first frequency in correspondence with the first position and with a second frequency in correspondence with the second position, the second frequency being more than 60% and less than 140% of the first frequency.

A method of heating a selected portion of an object includes the steps of projecting an energy beam onto a surface of the object and repetitively scanning the beam in accordance with a scanning pattern so as to establish an effective spot on the surface, and displacing the effective spot along a track to progressively heat a selected portion of the object. The selected portion has a first width at a first position along the track and a second width at a second position along the track. The second width is less than 75% of the first width.

The scanning pattern is repeated with a first frequency in correspondence with the first position and with a second frequency in correspondence with the second position, the second frequency being more than 60% and less than 140% of the first frequency.

Provided is a combined fabricating method for gradient nanostructure in the surface layer of a metal workpiece. A plastic deformation layer in great depth is induced by laser shock peening, then the surface of the metal workpiece is nanocrystallized by surface mechanical attrition treatment, and finally a gradient nanostructure is obtained in the surface layer of the metal workpiece with desirable layer thickness and optimized micro-structure distribution.

Provided is a combined fabricating method for gradient nanostructure in the surface layer of a metal workpiece. A plastic deformation layer in great depth is induced by laser shock peening, then the surface of the metal workpiece is nanocrystallized by surface mechanical attrition treatment, and finally a gradient nanostructure is obtained in the surface layer of the metal workpiece with desirable layer thickness and optimized micro-structure distribution.

A method and a device produces a pressing tool. A pressing tool is provided for producing a workpiece, which pressing tool includes a structured pressing surface of metal with elevations and recesses. Subsequently, a laser or an electron beam device is controlled such that a laser beam generated by the laser and/or an electron beam generated by the electron beam device is directed onto the pressing surface and hits it, such that the pressing surface is laser hardened and/or electron beam hardened.

A method and a device produces a pressing tool. A pressing tool is provided for producing a workpiece, which pressing tool includes a structured pressing surface of metal with elevations and recesses. Subsequently, a laser or an electron beam device is controlled such that a laser beam generated by the laser and/or an electron beam generated by the electron beam device is directed onto the pressing surface and hits it, such that the pressing surface is laser hardened and/or electron beam hardened.

Disclosed is a method for manufacturing stress-relief-annealing-resistant, low-iron-loss grain-oriented silicon steel, the method comprising: carrying out, by means of a pulse laser, scanning grooving on a single surface or two surfaces of a silicon steel sheet after cold rolling, or after decarburizing annealing, or after high temperature annealing or after hot stretching, temper rolling and annealing, and forming several grooves parallel with each other in a rolling direction of the silicon steel sheet, wherein a single pulse time width of the pulse laser is 100 ns or less, and a single pulse peak energy density is 0.05 J/cm.sup.2 or more; the energy density of a single scan of a single laser beam is 1 J/cm.sup.2 to 100 J/cm.sup.2; a beam spot of the pulse laser is a single beam spot or a combination of a plurality of beams spots, the shape of the beam spot is circular or elliptic, and the diameter of the beam spot in a scanning direction is 5 μm to 1 mm, and the diameter thereof in a direction perpendicular to the scanning direction is 5 μm to 300 μm; and when scanning grooving is carried out at the same position on the silicon steel sheet, the product of the number of beam spots of the pulse laser and the scan times is 5 or more.

A method for treating a Yankee cylinder, where the Yankee cylinder has a cylinder shell made of steel with a ferritic-pearlitic structure. In the disclosed method, the outer surface of the cylinder shell is heat-treated with a laser beam and hardened as a result.

A method for treating a Yankee cylinder, where the Yankee cylinder has a cylinder shell made of steel with a ferritic-pearlitic structure. In the disclosed method, the outer surface of the cylinder shell is heat-treated with a laser beam and hardened as a result.

A component manufacturing method includes: disposing, in a fluid, an unprocessed component having a hole that has an opening in an outer surface of the unprocessed component; creating a flow of the fluid such that air bubbles resulting from laser peening performed by irradiating an inner wall of the hole of the unprocessed component with a laser beam in the fluid flow along the hole; setting an irradiation area of the laser beam in an inner surface of the hole; and in the fluid of which the flow has been created, irradiating the irradiation area with the laser beam from the side of the outer surface through the opening.