Everything about Cold Welding totally explained
Cold or
contact welding was first recognized as a general materials phenomenon in the 1940s. It was then discovered that two clean, flat surfaces of similar
metal would strongly adhere if brought into contact under
vacuum.
Cold welding is a solid-state welding process in which joining takes place without fusion at the interface of the two parts to be welded. Unlike in the fusion-welding processes, no liquid or molten phase is present in the joint.
Process
In cold welding, pressure is applied to the workpieces through dies or rolls. Because of the plastic deformation involved, it's necessary that at least one (but preferably both) of the mating parts be ductile. Prior to welding, the interface is degreased, wire-brushed, and wiped to remove oxide smudges. Cold welding can be used to join small workpieces made of soft, ductile metals.
It is now known that the force of
adhesion following first contact can be augmented by pressing the metals tightly together, increasing the duration of contact, raising the
temperature of the workpieces, or any combination of the above. Research has shown that even for very smooth metals, only the high points of each surface, called
asperities, touch the opposing piece. Perhaps as little as a few thousandths of a percent of the total surface is involved. However, these small areas of taction develop powerful
molecular connections;
electron microscope investigations of contact points reveal that an actual welding of the two surfaces takes place after which it's impossible to discern the former asperitic interface. If the original surfaces are sufficiently smooth the subatomic attractions between contact points eventually draw the two pieces completely together and eliminate even the macroscopic interface.
Exposure to
oxygen or certain other reactive compounds produces surface layers that reduce or completely eliminate the cold welding effect. This is especially true if, for example, a metal
oxide has mechanical properties similar to those of the parent
element (or softer), in which case surface deformations don't crack the oxide film. The reason this doesn't normally happen between metals on earth is because there's a very fine layer of oxidized metal due to the atmosphere, and even earth-made metals taken to space would retain this layer and not cold-weld.
Applications
Applications include wire stock and electrical connections.
In space
Mechanical problems in early satellites were sometimes attributed to cold welding. However, there are no
documented cases of it actually occurring in orbit, except in experiments deliberately designed to provoke it (with susceptible materials, great care to avoid contamination, deliberate mechanical removal of oxide layers, etc.).
While cold welding is real, an unqualified claim that "in space metals stick" should be treated as an
urban legend.
Further Information
Get more info on 'Cold Welding'.
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