An Introduction to Nickel and Nickel Alloys
Nickel is a versatile element and can alloy with many other metals, each with its benefits. This makes nickel a practical metal, with artefacts such as coins and weapons showing its potential in early civilizations.
Due to its properties, nickel has a whole host of applications, but the majority of these involve corrosion or heat resistance. Typical uses may include aircraft gas turbines, steam turbine power plants, medical devices, nuclear power systems and chemical and petrochemical industries.
Special-purpose nickel-base also referred to as « high-nickel alloys » are also characterized by specific properties; these include electrical resistance, shape memory, low-expansion and soft magnetic.
These industrial forms of nickel, as well as nickel-base alloys, are austenitic. They are usually picked for usage due to their resistance to heat and aqueous corrosion.
‘Commercially pure’ and low-alloy nickels
‘Commercially pure’ and the group called ‘low-alloy nickels’ can be found with nickel levels that range from about 94% to almost 100%. This makes them high-density materials affording the user electronic and magnetic capabilities in addition to excellent resistance to corrosion to chemically reducing environments and moderate thermal transfer characteristics.
Nickel-copper alloys are exceptional in reducing environments and seawater. Their ability to resist corrosion means that they are common in nuclear submarines as well as surface vessels. Corrosion-resistant varieties include: Alloy 625 and Alloy C276
Altering the proportions of nickel and copper in the alloy provides greater flexibility by offering a spectrum of electrical resistivities and Curie points. Common industrial nickel-copper alloys include Alloy 400, and Alloy K-500.
Nickel-chromium and nickel-chromium-iron alloys
These nickel alloys provide higher strength and resistance to elevated temperatures. They are invaluable in today’s commercial and military power systems. Nickel-chromium alloys or alloys containing greater than 15% Cr can be used to provide both oxidation and carburization resistance at temperatures over 760°C. Iron-nickel-chromium alloys of importance include: Nickel 200 and Nickel 201
Iron-nickel-chromium alloys are also prominent in high-temperature petrochemical arenas where sulfur-containing feedstocks such as naphtha as well as heavy oils, are cracked into component parts for commercial usage. Here the alloys have proved resistant to chloride-ion stress-corrosion breaking in addition to polythionic acid cracking.
For more information on nickel alloys and their uses, or to discuss your application, please contact us today – we’re happy to help.