Thomas W. Penrice scite author profile

Tungsten, discovered in 1755 and produced as a metal in 1783, is notable for having a very low vapor pressure, the highest melting point of any metal, and the highest tensile strength of any metal above 1650°C. It is used in the manufacture of high speed steels and as a metal filament in electric lamps, where it is fabricated by powder metallurgy using the Coolidge process. The largest application is in the manufacture of cemented carbide cutting tools. Tungsten is rated as a strategic material in the U.S. economy. Tungsten occurs in a number of mineral forms, the most important being scheelite and wolframite. The beneficiation and hydrometallurgy are described, together with the principal intermediate compounds used to make the metal powder by hydrogen reduction. Technically it is possible to process compacted powder by arc or electron‐beam melting, but commercially the power metallurgy process of compaction, sintering, and working is used exclusively. The largest reserves of ores occur in China, which has, in more recent years, become the principal source of supply not only for ores but for metal powder and intermediates at prices that have caused most U.S. mines to be closed. About 65% of tungsten usage is as tungsten carbide in cutting and mining tools. The instability of the market as well as economic and environmental factors have favored development of recycling processes. Used cutting tools can be treated with molten zinc and both tungsten carbide and cobalt binder are recovered as mixed powders after vacuum‐distillation of the zinc. It is estimated that 25% of cutting tools are recycled in this way in the United States. Tungsten alloyed with nickel and iron is used for a range of high density compositions that find applications as counterweights in aircraft, as armor‐piercing penetrators, and for collimators and shielding in x‐ray machines. These alloys are characterized by high density and high modulus, which make them suitable for use in critical dynamic structures. Tungsten forms only a few alloys; tungsten–rhenium is important for thermocouples and as a tough lamp filament alloy. Insoluble tungsten has relatively low toxicity, but aerosols with cobalt and with impurities found in mining can have some effect and require controls of exposure level.

show abstract

Some characteristics of the binder phase in cemented carbides

Penrice¹

1997

International Journal of Refractory Metals and Hard Materials

View full text Add to dashboard Cite

Tungsten and Tungsten Alloys

Penrice

2010

View full text Add to dashboard Cite

Tungsten is a silvery‐gray metallic element. It was first discovered in 1775 and as a metal in 1783. Metallic tungsten was first produced by the carbon reduction of tungstic acid and was termed wolfram. Tungsten is now the name used, but the chemical symbol remains as W. Tungsten has a very low vapor pressure, the highest melting point of any metal, and the highest tensile strength of any metal above 1650 degrees C. Tungsten occurs in a number of mineral forms, the most important are scheelite and wolframite. The benefication and hydrometallurgy are described along with the principal intermediate compounds used to make the metal powder. The highest reserves of tungsten are found in China. The instability of the market and economic conditions favor recycling of the metal. Tungsten's main use is in production of cemented carbides for cutting and wear resistant materials. It is also used to produce alloys for applications requiring high density such as eleclrodes, filaments and wires, and in other electronic components and in the manufacture of superalloys.

show abstract

Tungsten and Tungsten Alloys

Penrice¹

2000

View full text Add to dashboard Cite

Tungsten, discovered in 1755 and produced as a metal in 1783, is notable for having a very low vapor pressure, the highest melting point of any metal, and the highest tensile strength of any metal above 1650°C. It has been used formerly in the manufacture of high speed steels and as a metal filament in electric lamps, where it was fabricated by powder metallurgy using the Coolidge process. The largest modern application is in the manufacture of cemented carbide cutting tools. Tungsten is rated as a strategic material in the U.S. economy. Tungsten occurs in a number of mineral forms, the most important being scheelite and wolframite. The beneficiation and hydrometallurgy are described, together with the principal intermediate compounds used to make the metal powder by hydrogen reduction. Technically it is possible to process compacted powder by arc or electron‐beam melting, but commercially the power metallurgy process of compaction, sintering, and working is used exclusively. The largest reserves of ores occur in China, which has, in more recent years, become the principal source of supply not only for ores but for metal powder and intermediates at prices that have caused most U.S. mines to be closed. About 65% of tungsten usage is as tungsten carbide in cutting and mining tools. The instability of the market as well as economic and environmental factors have favored development of recycling processes. Used cutting tools can be treated with molten zinc and both are recovered tungsten carbide and cobalt binder as mixed powders after vacuum‐distilling off the zinc. It is estimated that 25% of cutting tools are recycled in this way in the United States. Tungsten alloyed with nickel and iron is used for a range of high density compositions that find applications as counterweights in aircraft, as armor‐piercing penetrators, and for collimators and shielding in x‐ray machines. These alloys are characterized by high density and high modulus, which make them suitable for use in critical dynamic structures. Tungsten forms only a few alloys; tungsten–rhenium is important for thermocouples and as a tough lamp filament alloy. Insoluble tungsten has relatively low toxicity, but aerosols with cobalt and with impurities found in mining can have some effect and require controls of exposure level.

show abstract

scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.

Contact Info

customersupport@researchsolutions.com

10624 S. Eastern Ave., Ste. A-614

Henderson, NV 89052, USA

This site is protected by reCAPTCHA and the Google Privacy Policy and Terms of Service apply.

Blog Terms and Conditions API Terms Privacy Policy Contact Cookie Preferences Do Not Sell or Share My Personal Information

Made with 💙 for researchers

Part of the Research Solutions Family.

Thomas W. Penrice

Alternative binders for hard metals

Tungsten and Tungsten Alloys

Some characteristics of the binder phase in cemented carbides

Tungsten and Tungsten Alloys

Tungsten and Tungsten Alloys

Contact Info

Product

Resources

About