Chlorination-Volatilization Behavior of Titanium Metal Scraps during Recycling Using Reaction-Mediating Molten Salt

Taninouchi, Yu Ki; Hamanaka, Yuki; Okabe, Toru H.

doi:10.2320/matertrans.m-m2016818

Cited by 15 publications

(5 citation statements)

References 22 publications

(51 reference statements)

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“…Deoxidation by Ca/CaO [154] Effective deoxidation Low or insufficient capability for deoxidation VIM with CaAl 2 [155] Short process time Low or insufficient capability for deoxidation Hydrogen plasma arc melting [156] Short process time Low or insufficient capability for deoxidation Deoxidation of Ti alloy by HDH [157] Simple process Low or insufficient capability for deoxidation Electrochemical deoxidation [158] Ultra-high capability for deoxidation Required a molten salt bath Chlorination with reaction-mediating molten salt [99] Applicable to most titanium alloys Required a molten salt bath FFC process [159] Titanium production directly from oxides The process time is too long [163] Inexpensive deoxidant Titanium with a high percentage of Si Leaching after hydrogenation [164] Suitable for Ti-6Al-4V alloy Toxic waste solutions are generated Electrorefining in molten salt [165] The process can remove almost all impurities There is contamination from molten salt Chlorination with FeCl x chloride waste [166] It was possible to control impurities High volatility of FeCl x…”

Section: Methods Advantage Disadvantagementioning

confidence: 99%

See 1 more Smart Citation

Sustainable Recovery of Titanium Alloy: From Waste to Feedstock for Additive Manufacturing

Tebaldo,

Gautier di Confiengo,

Duraccio

et al. 2023

Sustainability

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Titanium and its alloys are widely employed in the aerospace industry, and their use will increase in the future. At present, titanium is mainly produced by the Kroll method, but this is expensive and energy-intensive. Therefore, the research of efficient and sustainable methods for its production has become relevant. The present review provides a description of the titanium recycling methods used to produce mostly aeronautical components by additive manufacturing, offering an overview of the actual state of the art in the field. More specifically, this paper illustrates that ilmenite is the main source of titanium and details different metallurgic processes for producing titanium and titanium alloys. The energy consumption required for each production step is also illustrated. An overview of additive manufacturing techniques is provided, along with an analysis of their relative challenges. The main focus of the review is on the current technologies employed for the recycling of swarf. Literature suggests that the most promising ways are the technologies based on severe plastic deformation, such as equal-channel angular pressing, solid-state field-assisted sintering technology-forge, and the Conform process. The latter is becoming established in the field and can replace the actual production of conventional titanium wire. Titanium-recycled powder for additive manufacturing is mainly produced using gas atomization techniques.

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Section: Methods Advantage Disadvantagementioning

confidence: 99%

“…Because of the contamination due to the stainless-steel vessel, a small part of the sponge cannot be employed. It is estimated that there is a residue of 10-20% of titanium sponge in each production [99], causing an energy consumption of 42.96 MJ/kg.…”

Section: Energy Consumption For Titanium Preparationmentioning

confidence: 99%

Sustainable Recovery of Titanium Alloy: From Waste to Feedstock for Additive Manufacturing

Tebaldo,

Gautier di Confiengo,

Duraccio

et al. 2023

Sustainability

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show abstract

“…Thus, by reducing the Fe and especially O content of TiA scrap the need for additional virgin material and down-cycling could be reduced. Technologies for removal of these contaminants are mostly still in the fundamental stage of research [82][83][84][85][86][87]. If further development proves successfully, they could have a high commercial potential.…”

Section: Improving Materials Performancementioning

confidence: 99%

Holistic evaluation of the suitability of metal alloys for sustainable marine construction from a technical, economic and availability perspective

Kappenthuler

Seeger

2021

Ocean Engineering

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“…Taninouchi et al developed an efficient chlorination process that uses a reaction-mediating molten salt. [88] Ti Titanium metal is efficiently chlorinated in this process because both the chlorination agent and the reaction product are dissolved species in molten salts. This process can be applied not only to pure titanium but also to titanium alloys.…”

Section: Current Status Of Research and Development In Titanium Scmentioning

confidence: 99%

Recent Progress in Titanium Extraction and Recycling

Takeda

Ouchi

Okabe

2020

Metall Mater Trans B

Self Cite

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This paper presents a brief review of the history of titanium smelting and the current trends in related research and development. Presently, both electrolytic and metallothermic reduction processes utilizing various feed materials such as titanium oxide are widely studied. However, many challenges remain to be addressed before realizing the practical application of smelting processes utilizing oxide feed. To make titanium a ''common metal'', a new reduction process that is high speed, energy-efficient, low cost, and of low environmental impact is required. The current status of titanium recycling is likewise outlined, and the development of the recycling process is discussed. Low-grade titanium scraps heavily contaminated by oxygen and iron are currently used for producing additive alloys (ferro-titanium) in the steel industry. In the near future, if the demand for titanium metal increases dramatically, there could be an oversupply of low-grade titanium scraps in the market. Therefore, the development of anti-contamination and efficient removal processes for oxygen and iron is essential for the efficient utilization of titanium. The development of these technologies is vital for expanding the titanium industry through innovation in both titanium smelting and recycling technologies.

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Chlorination-Volatilization Behavior of Titanium Metal Scraps during Recycling Using Reaction-Mediating Molten Salt

Cited by 15 publications

References 22 publications

Sustainable Recovery of Titanium Alloy: From Waste to Feedstock for Additive Manufacturing

Sustainable Recovery of Titanium Alloy: From Waste to Feedstock for Additive Manufacturing

Holistic evaluation of the suitability of metal alloys for sustainable marine construction from a technical, economic and availability perspective

Recent Progress in Titanium Extraction and Recycling

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