Recycling of Secondary Tungsten Resources

Tungsten and its alloys find critical applications in several important sectors, such as defence, aerospace, mining, manufacturing, telecommunications etc., which are key to economic development and national security. Global tungsten deposits are limited (~3.3 million tonnes) and highly localized; C...

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Bibliographic Details
Published in:Transactions of the Indian Institute of Metals 2017-03, Vol.70 (2), p.479-485
Main Authors: Mishra, Devabrata, Sinha, Shivendra, Sahu, Kamla Kanta, Agrawal, Archana, Kumar, Rakesh
Format: Article
Language:English
Subjects:
Aerospace industry
Chemistry and Materials Science
Commercial spacecraft
Commercialization
Corrosion and Coatings
Defense programs
Economic development
Materials Science
Metal powders
Metal scrap
Metallic Materials
Mineral deposits
Product specifications
Recycling
Sodium tungstate
Strategic materials
Technical Paper
Tribology
Tungsten carbide
Tungsten ores
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Summary:Tungsten and its alloys find critical applications in several important sectors, such as defence, aerospace, mining, manufacturing, telecommunications etc., which are key to economic development and national security. Global tungsten deposits are limited (~3.3 million tonnes) and highly localized; China dominates the supply with more than 84% share. India doesn’t have any economic tungsten ore deposits, and produces meagre quantities of tungsten in comparison to its demand of ~1500 tonne/year. In order to lessen the import burden and supply risk to the country’s defence programmes, India is required to focus on producing this important metal from various available secondary and lean grade resources such as scraps and tailings. This article presents some of the recently developed and commercialized tungsten recycling technologies by CSIR-NML, which include: (1) recycling of tungsten carbide (WC) hard metal scraps for production of high pure yellow tungsten oxide (WO 3 ) and W-metal powder; and (2) production of high pure sodium tungstate (Na 2 WO 4 ·2H 2 O) from spent hydro-refining catalysts. Besides describing the process flow-sheets and product specifications, the paper highlights the advantages of CSIR-NML technologies over the presently practiced technologies.
ISSN:0972-2815
0975-1645
DOI:10.1007/s12666-016-1003-8