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 Welding
In laser welding we must distinguish between two main processes:
thermal conductivity welding and deep penetration welding.
In thermal conductivity welding, the materials to be joined melt
as a result of absorption of the laser beam on the surface of the
material, and the associated conduction of heat. The solidified
smelt joins the materials. The depth of the weld in this process
is typically < 1 mm.
Deep penetration welding, which begins at an energy density of
approx. 106 W per cm2, is based on the creation
of a vapor capillary in the material. To achieve this, it is necessary
to heat the material locally to its evaporation point. The resulting
vapor pressure in the material creates a capillary approx. 1.5 times
the diameter of the focal spot of the laser beam, which is moved
through the material by the movement system, following the contour
to be welded. The hydrostatic pressure, the surface tension of the
smelt, and the vapor pressure in the capillary compensate each other,
so that the capillary (often referred to as the "keyhole") does
not collapse. The total reflection within the keyhole guides the
applied laser beam deep into the material, in such a way that today,
given sufficient laser power, weld depths of up to 25 mm (steel)
can be achieved.
Steels and aluminum are the classic area for laser welding. But
in principle, all materials that can be welded using traditional
methods can also be welded with lasers, often at higher speed and
quality compared with the traditional processes.
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