• Title/Summary/Keyword: soda-roasted

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Leaching of Vanadium and Tungsten from Spent SCR Catalysts for De-NOx by Soda Roasting and Water Leaching Method (소다배소(焙燒) 및 수침출법(水浸出法)에 의한 탈질용(脫窒用) 폐(廢) SCR 촉매(觸媒)로부터 바나듐과 텅스텐 침출(浸出))

  • Kim, Hye-Rim;Lee, Jin-Young;Kim, Joon-Soo
    • Resources Recycling
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    • v.21 no.6
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    • pp.65-73
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    • 2012
  • Selective catalytic reduction(SCR) catalysts are obtained from de-NOx system of thermoelectric power plant. A process was developed for valuable metals such as vanadium and tungsten recovery from spent SCR catalyst by using soda roasting followed by water leaching. Spent SCR catalyst having $V_2O_5$(1.23 mass %) and $WO_3$(7.73 mass %). For getting soluble metal forms of the targeted metals like vanadium and tungsten soda roasting process was implemented. In soda roasting process, sodium carbonate added 5 equivalent ratio at roasted temperature $850^{\circ}C$ with 120 min roasted time for $544{\mu}m$ particle size of spent SCR catalyst. After soda roasting process moved to water leaching for roasted spent catalyst. Before leaching process the roasted spent catalyst was grinded up to $-45{\mu}m$ size. The leaching time is 30 min at $40^{\circ}C$ temperature, 10 % pulp density. The final leaching efficiency obtained 46 % of vanadium and 92 % of tungsten from present process.

Titanium Dioxide Recovery from Soda-roasted Spent SCR Catalysts through Sulphuric Acid Leaching and Hydrolysis Precipitation (소다배소 처리된 탈질 폐촉매로부터 황산침출과 가수분해 침전반응에 의한 TiO2의 회수)

  • Kim, Seunghyun;Trinh, Ha Bich;Lee, Jaeryeong
    • Resources Recycling
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    • v.29 no.5
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    • pp.48-54
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    • 2020
  • Sulphuric acid (H2SO4) leaching and hydrolysis were experimented for the recovery of titanum dioxide (TiO2) from the water-leached residue followed by soda-roasting spent SCR catalysts. Sulphuric acid leaching of Ti was carried out with leachate concentration (4~8 M) and the others were fixed (temp.: 70 ℃, leaching time: 3 hrs, slurry density: 100 g/L, stirring speed: 500 rpm). For recovering of Ti from the leaching solution, hydrolysis precipitation was conducted at 100 ℃ for 2 hours in various mixing ratio (leached solution:distilled water) of 1:9 to 5:5. The maximum leachability was reached to 95.2 % in 6 M H2SO4 leachate. on the other hand, the leachability of Si decreased dramatically 91.7 to 3.0 % with an increase of H2SO4 concentration. Hydrolysis precipitation of Ti was proceeded with leaching solution of 8 M H2SO4 with the lowest content of Si. The yield of precipitation increased proportionally with a dilution ratio of leaching solution. Moreover, it increased generally by adding 0.2 g TiO2 as a precipitation seed to the diluted leaching solution. Ultimately, 99.8 % of TiO2 can be recovered with the purity of 99.46 % from the 1:9 diluted solution.

A Study on Improvement of Recycling Process of Waste Fluorescent Lamps (폐형광등 재활용 공정의 개선 연구)

  • Lee, Gee Hun;Lee, Dong Hoon;Song, Young Jun;Kim, Chang Kwon
    • Resources Recycling
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    • v.29 no.3
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    • pp.61-74
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    • 2020
  • This study was conducted to improve the recycling process of waste fluorescent lamp, and investigate the possibility of using the waste fluorescent lamp glass as a raw material for glass beads, the leaching method of rare earth from the waste phosphor powder, and the possibility of solvent extraction of rare earth from the rare earth leaching solution. The waste phosphor contained 28.9% yttrium oxide, 3.46% cerium oxide, 1.95% europium oxide, 1.76% terbium oxide, and 1.43% lanthanum oxide. As a result of the trial production of glass beads using waste fluorescent lamp glass, it was judged that the production yield and quality were excellent, so that waste fluorescent lamp glass could be used as a raw material for glass beads. The soda roasted waste phosphor was leached in water and thereby the aqueous solution was blown with CO2 to drop the pH to about 7, Then, Al, Si and residual N2CO3 were dissolved, and NaAlCO3(OH)2 and SiO2 were precipitated in the aqueous solution. In the solvent extraction of cyanex272-hydrochloric acid, cyanex272-sulfuric acid, D2EHPA-hydrochloric acid, D2EHPA-sulfuric acid, Ionquest290-hydrochloric acid, Ionquest290-sulfuric acid, p507-hydrochloric acid using xylene as a diluent, the extraction yield of Y, Eu, Ce, La, and Tb are close to 100%. However, in this conditions, the difference in extraction yield for each element, that is, selectivity is 16% or less.