http://chineseinput.net/에서 pinyin(병음)방식으로 중국어를 변환할 수 있습니다.
변환된 중국어를 복사하여 사용하시면 됩니다.
조건준,김윤종,박현혜,조성백,Cho, Keon-Joon,Kim, Yun-Jong,Park, Hyun-Hae,Cho, Sung-Baek 한국재료학회 2009 한국재료학회지 Vol.19 No.4
A study on the dry beneficiation of sericite occurring in the Daehyun Mine of the Republic of Korea region as performed by applying selective grinding and air classification techniques. Quartz and sericite occurred in the raw ore as major components. The results of liberation using a ball mill and an impact mill showed that the contents of $R_2O$ were increased while $SiO_2$ was decreased in proportion to decreasing particle size. According to the XRD, XRF analysis and the EDS of SEM analysis, the ball mill gave a better grade product in $R_2O$ content than the impact mill when the particle size was the same. When the raw ore was ground by the impact mill with arotor speed 57.6 m/sec and then followed by 15,000rpm classification using an air classifier, the chemical composition of the over flowed product was 49.65wt% $SiO_2$, 32.15wt% $Al_2O_3$, 0.13wt% $Fe_2O_3$, 10.37wt% $K_2O$, and 0.14wt% $Na_2O$. This result indicates that the $R_2O$ contents were increased by 49.5% compared to that of the raw ore. From these results described above, it is suggested that hard mineral such as Quartz little ground by selective grinding using impact mill whereas soft mineral such as sericite easily ground to small size. As a result of that hard minerals can be easily removed from the finely ground sericite by air classification and the $R_2O$ grade of thus obtained concentrate was improved to higher than 10wt% which can be used for ceramics raw materials.
김상배,조성백,조건준,김윤종,이재천,김원백,Kim Sang-Bae,Cho Sung-Baek,Cho Keon-Joon,Kim Yoon-Jong,Lee Jae-Chun,Kim Won-Baek 한국자원리싸이클링학회 2003 資源 리싸이클링 Vol.12 No.3
폐 탄탈륨 콘덴서에 함유된 탄탈륨 anode를 물리적인 방법으로 회수하고자 파쇄, 입도분리, 건식 자력선별 그리고 공기 분급 실험을 수행하였다. 단체분리를 위해 롤 크럿셔를 사용하여 폐회로 공정에서 8mesh 이하로 파쇄하면. 대부분의 탄탈륨 anode는 레진과의 단체분리는 이루어지나 일부 금속과의 단체분리가 되지 않은 상태로 남게된다. 파쇄된 시료를 8/10 mesh, 10/18 mesh, -18 mesh 로 분립한 결과, 금속물질은 8/10 mesh 입자에, 탄탈륨 anode는 +18 mesh에 주로 분포하며, -l8 mesh에는 레진의 함량이 71.5%로 레진이 탄탈륨 anode나 금속물질보다 미립화가 쉽게 이루어짐을 알 수 있었다. 자력선별에 의한 금속 물질의 분리효율은 원료의 입도에 따라 크게 차이가 있으나, 일부 금속물질이 약자성체이거나 탄탈륨anode와 단체분리가 이루어지지 않아 금속물질 제거율은 62.3%로 비교적 저조하였다. 탄탈륨 anode와 레진의 분리를 위한 입도별 공기 분급실험 결과, 각 입도별 최적 공기량은 각각 39㎥/h, 32㎥/h, 20㎥/h로 나타났다. 최적의 조건으로 회수한 탄탈륨 anode 생산율은 49.39wt.%, 각 성분의 함량은 97.47wt.% 탄탈륨 anode, 0.93wt.% 레진. 1.51 wt.% 금속으로 탄탈륨 anode 실수율은 94.45%이었다. Physical separation containing grinding, sieving, dry magnetic separation and air classification were carried out in order to recover Ta anode from waste Ta condenser. Roll crusher wat used for the liberation of resin and metals in closed circuit system. The liberation between Ta anode and resin was easily achieved, whereat some of metals did not liberated from the Ta anode when the waste condenser was crushed below 8 mesh. When the crushed sample were divided into 8/10 mesh, 10/18 mesh and -18 mesh, metals was mainly remained in 8/10 mesh in contrast to Ta anode was in +18 mesh. It was shown that resin was more easily crushed rather than metals from the result of that resin content was 71.5% in -18 mesh. The liberation efficiency was different with the input size of the crushed sample and average efficiency was 62.3% due to the locked Ta anode particles. The results of air classification test for the crushed samples showed that optimal air flow are 39㎥/h, 32㎥/h, 20㎥/h. respectively. When the sample were separated with optimal condition, 94.45% Ta anode containing 97.47 wt.% Ta anode, 0.93 wt.% resin. 1.61 wt.% metal was recovered with 49.39 wt.% yield.