Science, Tech, Math › Science Beryllium-Copper Alloys Share Flipboard Email Print Maximilian Stock Ltd. / Getty Images Science Chemistry Chemistry In Everyday Life Basics Chemical Laws Molecules Periodic Table Projects & Experiments Scientific Method Biochemistry Physical Chemistry Medical Chemistry Famous Chemists Activities for Kids Abbreviations & Acronyms Biology Physics Geology Astronomy Weather & Climate By Terence Bell University of British Columbia Carleton University Terence Bell wrote about commodities investing for The Balance, and has over 10 years experience in the rare earth and minor metal industries. our editorial process Twitter Twitter LinkedIn LinkedIn Terence Bell Updated April 02, 2018 Beryllium-copper alloys are known for their unique combination of strength, hardness and corrosion resistance. One important characteristic of this alloy is that beryllium-copper can be softened or hardened at will by two simple heat treatment processes. In a fully heat-treated preparation, beryllium-copper alloys are the hardest and strongest of all copper-rich alloys (to 1400MPa), to the extent that it is similar to many high-grade alloy steels. The Advantage Over Steel Of course, its advantage over steel is a higher resistance to corrosion, higher thermal and electrical conductivity and its non-sparking qualities. It is also non-magnetic and can be formed from strips or wires in the soft condition, and later hardened by heat treatment. Generally, alloys that contain from 1.7 to 1.9 percent beryllium and are precipitation hardened for two hours within a temperature range of 315°C to 350°C will provide properties ideal for most commercial purposes. For softer grades, higher temperatures can be used. A high elastic limit, along with a low modulus of elasticity and fatigue resistance is valued in specific technical applications. The alloy is also ductile, weldable and machinable. Beryllium copper is most often used for producing small springs, pressure responsive diaphragms, flexible bellows, Bourdon tubes and components of measuring instruments for electrical and barometric applications. Castings and Forgings Castings and forgings of the alloy are used in areas that require high strength combined with good electrical and thermal conductivity. Examples include electrodes for resistance welding appliances and dies for moulding plastics. Applications for beryllium-copper can be classified into four groups based on the unique qualities each requires: Spring, diaphragms, and pressure sensitive instruments (elasticity and strength)Dies for deep drawing and forging metals and moulding plastics (high strength and hardness)Resistance welding electrodes (strength, resistance to corrosion and conductivity)Non-sparking tools (non-sparking, strength, and hardness) While most alloys contain about 2 percent beryllium, this can range from 1.5 to as high as 3.0 percent depending on the application. Pressure sensitive uses, including springs, generally use a lower amount of beryllium, which is itself brittle. While dies, which require greater hardness, contain an amount of beryllium at the higher end of this spectrum. Cobalt and nickel are also regularly included in such alloys, in very low quantities, to improve the response to heat treatment. Low beryllium alloys contain much less beryllium (less than 1 percent) and a greater amount of cobalt (2 to 3 percent). While these alloys have lower strength and hardness, they have a much higher conductivity. Newer, proprietary alloys have also been developed with compositions falling in between regular and low beryllium copper alloys. Commercial Grades of Beryllium Copper All commercial grades of beryllium copper are precipitation hardening alloys. That is, they can be softened by quenching and hardened by heating to a moderate temperature. In both normal and saltwater environments, beryllium coppers resistance to corrosion is very similar to that of pure copper. While applications for the metal (e.g. in springs and pressure sensitive applications) are most often in competition with steel, this provides a significant comparative advantage. While beryllium-copper is attacked by sulfur and compounds of the element, it can be safely exposed to most organic liquids, including petroleum products, refined oils, and industrial solvents. Like copper, beryllium-copper alloys form a protective oxide layer on their surface that resists against oxidization and deterioration. Sources Beryllium Copper. Copper Development Association. CDA Publication No. 54, 1962URL: www.copperinfo.co.ukBauccio, Michael (Ed.). ASM Metals Reference Book, Third Edition. Materials Park, Ohio: ASM International. p. 445.