A first metal powder is supplied to a substrate to form a beginning part of a clad layer. After the beginning part is formed, the second metal powder is supplied to the substrate. A concentration of at least one of Si, Ni, Mo, and Al in the first metal powder is lower than a concentration thereof in the second metal powder.

A pair of separators is overlapped and placed on a base jig and thereby positioned with each other. Respective through-holes thereof are positioned to the position of a pin hole provided in the base jig. When a main jig is pressed against the base jig to clamp the pair of separators, and a pin of a sub-jig is inserted into the pin hole to clamp the pair of separators by a head, an annular light guiding path is formed by a gap generated between an opening provided in the main jig and the head of the sub-jig, and hence a laser welding position which surrounds the through-holes is exposed. The surrounding of each through-hole is seamlessly laser-welded when the laser welding position is irradiated with a laser beam.

A pair of separators is overlapped and placed on a base jig and thereby positioned with each other. Respective through-holes thereof are positioned to the position of a pin hole provided in the base jig. When a main jig is pressed against the base jig to clamp the pair of separators, and a pin of a sub-jig is inserted into the pin hole to clamp the pair of separators by a head, an annular light guiding path is formed by a gap generated between an opening provided in the main jig and the head of the sub-jig, and hence a laser welding position which surrounds the through-holes is exposed. The surrounding of each through-hole is seamlessly laser-welded when the laser welding position is irradiated with a laser beam.

There is provided high power laser systems, high power laser tools, and methods of using these tools and systems for cutting, sectioning and removing structures objects, and materials, and in particular, for doing so in difficult to access locations and environments, such as offshore, underwater, or in hazardous environments, such as nuclear and chemical facilities. Thus, there is also provided high power laser systems, high power laser tools, and methods of using these systems and tools for removing structures, objects, and materials located offshore, under bodies of water and under the seafloor.

Method for structuring a substrate (11) and comprising the following steps: —providing a device (100) comprising a light source (33), an optical system (2) for obtaining an outgoing light beam (7) spatially offset in relation to the incoming light beam (1), and capable of modifying this spatial offset, focusing means (9) for focusing the outgoing light beam (7), a substrate holder (59), a movement device (60) for generating a movement (41) between the outgoing light beam (7) and the substrate (11); —providing and placing the substrate (11) on the substrate holder (59); —etching the substrate with the focused outgoing light beam (7) having an angle of attack (107) greater than 1° for any spatial offset between outgoing light beam (7) and incoming light beam (1) imposed by the optical system (2).

Method for structuring a substrate (11) and comprising the following steps: —providing a device (100) comprising a light source (33), an optical system (2) for obtaining an outgoing light beam (7) spatially offset in relation to the incoming light beam (1), and capable of modifying this spatial offset, focusing means (9) for focusing the outgoing light beam (7), a substrate holder (59), a movement device (60) for generating a movement (41) between the outgoing light beam (7) and the substrate (11); —providing and placing the substrate (11) on the substrate holder (59); —etching the substrate with the focused outgoing light beam (7) having an angle of attack (107) greater than 1° for any spatial offset between outgoing light beam (7) and incoming light beam (1) imposed by the optical system (2).

In a method for laser welding of workpieces W1 and W2, a laser beam is generated and a workpiece W1 is irradiated. An irradiation point of the laser beam is swung within a predetermined heating area on the workpiece W1 encompassing a welding location where laser welding is to be executed, heating the mating surface area of the workpieces W1 and W2 corresponding to the heating area to a temperature higher than or equal to the boiling point of the coating material of the workpiece W2 and lower than the melting point of the base material of the workpiece W1, forming a gap between the workpieces W1 and W2 by vaporizing the coating material by the heating, discharging the coating material through the gap to the outside of the mating surface area, and melting and welding together the welding location of the base materials of the workpieces W1 and W2.

In a method for laser welding of workpieces W1 and W2, a laser beam is generated and a workpiece W1 is irradiated. An irradiation point of the laser beam is swung within a predetermined heating area on the workpiece W1 encompassing a welding location where laser welding is to be executed, heating the mating surface area of the workpieces W1 and W2 corresponding to the heating area to a temperature higher than or equal to the boiling point of the coating material of the workpiece W2 and lower than the melting point of the base material of the workpiece W1, forming a gap between the workpieces W1 and W2 by vaporizing the coating material by the heating, discharging the coating material through the gap to the outside of the mating surface area, and melting and welding together the welding location of the base materials of the workpieces W1 and W2.

Methods and systems for forming vacuum insulated containers, such as beverage and food containers, are described. The methods and systems include using a laser to close openings in walls of the container while the container is held at vacuum conditions. The closing of the opening forms the vacuum space within the walls of the container.

Methods and systems for forming vacuum insulated containers, such as beverage and food containers, are described. The methods and systems include using a laser to close openings in walls of the container while the container is held at vacuum conditions. The closing of the opening forms the vacuum space within the walls of the container.