矿冶工程
礦冶工程
광야공정
2014年
2期
104-107
,共4页
李贻成%刘越%章长生%乐为和%喻亮%罗鲲
李貽成%劉越%章長生%樂為和%喻亮%囉鯤
리이성%류월%장장생%악위화%유량%라곤
区域熔炼%高纯铟%制备%杂质分布%形貌
區域鎔煉%高純銦%製備%雜質分佈%形貌
구역용련%고순인%제비%잡질분포%형모
zone refining%high-purity indium%preparation%impurity distribution%morphology
为获得高纯金属铟,对区域熔炼装置和工艺条件进行了优化。在熔区移动速度为3 cm/h时,根据熔炼次数( n)改变熔区宽度与料锭长度比(l/L),即n=1~4时l/L=0.2,n=5~9时l/L=0.1,n=10~16时l/L=0.05,在高纯氩气保护下将含量约为99.98%的原料铟提纯至99.999%,其杂质总量从211.003μg/g降低至9.864μg/g。此外,还利用电感耦合等离子质谱( ICP-MS)、扫描电镜( SEM)、X射线衍射( XRD)和差热分析( DSC)等方法讨论了区熔过程中金属铟杂质分布与金属微观结构演变之间的关系。
為穫得高純金屬銦,對區域鎔煉裝置和工藝條件進行瞭優化。在鎔區移動速度為3 cm/h時,根據鎔煉次數( n)改變鎔區寬度與料錠長度比(l/L),即n=1~4時l/L=0.2,n=5~9時l/L=0.1,n=10~16時l/L=0.05,在高純氬氣保護下將含量約為99.98%的原料銦提純至99.999%,其雜質總量從211.003μg/g降低至9.864μg/g。此外,還利用電感耦閤等離子質譜( ICP-MS)、掃描電鏡( SEM)、X射線衍射( XRD)和差熱分析( DSC)等方法討論瞭區鎔過程中金屬銦雜質分佈與金屬微觀結構縯變之間的關繫。
위획득고순금속인,대구역용련장치화공예조건진행료우화。재용구이동속도위3 cm/h시,근거용련차수( n)개변용구관도여료정장도비(l/L),즉n=1~4시l/L=0.2,n=5~9시l/L=0.1,n=10~16시l/L=0.05,재고순아기보호하장함량약위99.98%적원료인제순지99.999%,기잡질총량종211.003μg/g강저지9.864μg/g。차외,환이용전감우합등리자질보( ICP-MS)、소묘전경( SEM)、X사선연사( XRD)화차열분석( DSC)등방법토론료구용과정중금속인잡질분포여금속미관결구연변지간적관계。
In order to prepare high-purity indium, the zone-refining device and conditions were optimized. The purity of indium was increased from 99.98% to 99.999% with the decrease of total impurity content from 211.003 μg/g to 9.864μg/g under the protection of high-purity argon at a treating rate of 3 cm/h by changing the ratio of melting zone width to ingot length( l/L) according to the melting frequency( n) , that is, l/L=0.2, 0.1 and 0.05 at n=1~4, 5~9 and 10~16, respectively. The relationship between impurity distribution and metal microstructure variation in the process of zone-refining of the indium ingot was also discussed based on the results of ICP-MS, SEM, XRD and DSC analyses.
