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Fabrication of 4N5 Grade Tantalum Wire from Tantalum Scrap by EBM and Drawing

Ji-Won Yu Sang-Hoon Choi Jae-Jin Sim Jae-Hong Lim Kyoung-Deok Seo Soong-Keon Hyun Tae-Youb Kim Bon-Woo Gu Kyoung-Tae Park
Archives of Metallurgy and Materials | 2019 | vol. 64 | No 3 | 935-941 | DOI: 10.24425/amm.2019.129476
Keywords recycling Electron Beam Melting Drawing Tantalum Scrap High-Purity
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Abstract

Electron beam melting(EBM) is a useful technique to obtain high-purity metal ingots. It is also used for melting refractory metals such as tantalum, which require melting techniques employing a high-energy heat source. Drawing is a method which is used to convert the ingot into a wire shape. The required thickness of the wire is achieved by drawing the ingot from a drawing die with a hole of similar size. This process is used to achieve high purity tantalum springs, which are an essential component of lithography lamp in semiconductor manufacturing process. Moreover, high-purity tantalum is used in other applications such as sputtering targets for semiconductors. Studies related to recycling of tantalum from these components have not been carried out until now. The recycling of tantalum is vital for environmental and economic reasons. In order to obtain high-purity tantalum ingot, in this study impurities contained in the scrap were removed by electron beam melting after pre-treatment using aqua regia. The purity of the ingot was then analyzed to be more than 4N5 (99.995%). Subsequently, drawing was performed using the rod melted by electron beam melting. Owing to continuous drawing, the diameter of the tantalum wire decreased to 0.5 mm from 9 mm. The hardness and oxygen concentration of the tantalum ingot were 149 Hv and less than 300 ppm, respectively, whereas the hardness of the tantalum wire was 232.12 Hv. In conclusion, 4N5 grade tantalum wire was successfully fabricated from tantalum scrap by EBM and drawing techniques. Furthermore, procedure to successfully recycle Tantalum from scraps was established.

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Authors and Affiliations

Ji-Won Yu
Sang-Hoon Choi
Jae-Jin Sim
Jae-Hong Lim
Kyoung-Deok Seo
Soong-Keon Hyun
Tae-Youb Kim
Bon-Woo Gu
Kyoung-Tae Park
ORCID: ORCID

Study on Preparation Technology and Heat Conduction Mechanism of High-Purity & Ultra-Fine Alumina Powder from Scrap Aluminum Cans

Chengmin Wang Anatoly Politov Xiuhui Wang Jinlong Yang
Archives of Foundry Engineering | 2024 | vol. 24 | No 1 | 158-164 | DOI: 10.24425/afe.2024.149264
Keywords Waste cans Purification of metal alkoxides High-purity alumina Water heat treatment Heat conduction
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Abstract

In view of the increasing scarcity of bauxite resources in China, the high energy consumption and high pollution of electrolytic aluminum, and the requirements for energy conservation and environmental protection, aluminum recycling and high-value utilization of its derivatives have evolved into a crucial development requirement for the aluminum industry in the future. As an important part of the development of recycled aluminum resources, the high-value application of scrap aluminum cans has always been a hot research topic in various recycled aluminum processing enterprises and scientific research units. The traditional regeneration system of waste cans includes a series of complex technological processes such as pretreatment, paint removal, smelting system and casting system, which is difficult to control in the middle of the process. Most of the recycled scrap aluminum cans are cast and downgraded for later use, except for a part of them used as alloy materials for new cans. In this paper, combined with the research on the preparation of metal aluminum alkoxide, combined with recrystallization heat conduction to further study the effective dissolution or adsorption how to remove impurity elements to obtain high-purity aluminum alcohol salt mechanism research, and thermal effect of alcohols with different carbon chains on the synthesis of high-purity aluminum alkoxide was further investigated. Moreover, the changes in morphology and pore size distribution of hydrolyzed alumina precursor materials under different hydrothermal temperature conditions were discussed by means of the alkoxide hydrolysis-sol-gel process. Eventually, the aluminum alkoxide was obtained by the reaction of waste cans with isopropanol and heavy crystal thermal conductivity, and the high-purity aluminum alkoxide was purified by vacuum distillation. Under the hydrothermal condition of 160°C, the high-purity alumina material with a purity of 99.99% and an original crystal size of 200nm was prepared.
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Bibliography

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Authors and Affiliations

Chengmin Wang
1
Anatoly Politov
2
Xiuhui Wang
1
Jinlong Yang
3
  1. Dalian Jiaotong University, China
  2. Institute of Solid State Chemistry and Mechanochemistry, Russia
  3. State Key Laboratory of New Ceramics & Fine Processing, China

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