Determination of total rare earths in intermediate alloy of rare earth aluminum by EDTA titration
LONG Xu-dong1,2, GAO Li-hong1,2, ZHANG Hong1,2, LIU Xiao-jie1,2
1. Rui Ke National Engineering Research Centre of Rare Earth Metallurgy and Function Materials Co., Ltd., Baotou 014030, China; 2. Baotou Research Institute of Rare Earths, Baotou 014030, China
Abstract:The accurate determination of total rare earths in intermediate alloy of rare earth aluminum is of great significance to effectively control the production technology and product quality.The sample was dissolved with 400g/L sodium hydroxide solution. At this time, rare earths reacted with sodium hydroxide to form rare earth hydroxide precipitates, while aluminum was remained in sample solution in the form of metaaluminates. The separation of aluminum from rare earths could be reached by filtration. The precipitate was dissolved with hydrochloric acid. Then hydrofluoric acid was added to react with rare earths to form rare earth fluoride precipitates, while iron would be remained in solution in the form of complex. The separation of interference element (i.e., iron) from rare earths could be reached by filtration. The precipitate was dissolved with hydrochloric acid and perchloric acid. The residual iron (III) was reduced with ascorbic acid. Little residual interference element aluminum was mashed with diacetone. The pH of solution was controlled at 5.5. The xylenol orange was used as indictor. The solution was titrated with EDTA standard solution until the color was changed from red purple to bright yellow. Thus the determination method of total rare earths in intermediate alloy of rare earth aluminum by EDTA titration was established. The proposed method was applied for the determination of total rare earths in intermediate alloy samples of rare earth aluminum (including lanthanum-aluminum, samarium-aluminum, erbium-aluminum and yttrium-aluminum). Moreover, different amounts of high-purity lanthanum oxide, samarium oxide, erbium oxide and yttrium oxide, which had been heated in muffle furnace at 950℃, was added into sample for recovery tests, respectively. The relative standard deviation (RSD, n=11) of determination results were less than 0.30%. The recoveries were between 99.6% and 100.4%. The contents of total rare earths in lanthanum-aluminum and samarium-aluminum samples were determined according to the experimental method, and the found results were basically consistent with those obtained by the oxalate gravimetric method in national standard GB/T 31966-2015.
潘利文,罗涛,林覃贵,等.稀土铝合金最新研究进展[J].轻合金加工技术,2016,44(9):12-16.PAN Li-wen,LUO Tao,LIN Qin-gui,et al.Latest research progress of rare earth aluminum alloy[J].Light Alloy Processing Technology,2016 44(9):12-16.
[2]
王荣滨.稀土铝合金的研究与应用[J].有色金属加工,2007,36(2):21-23.WANG Rong-bin.Research and application of RE aluminum alloy[J].Nonferrous Metals Processing,2007,36(2):21-23.
[3]
王会阳,安云岐,李承宇,等.稀土在铝和铝合金中应用的研究及进展[J].稀土,2012,33(1):74-80.WANG Hui-yang,AN Yun-qi,LI Cheng-yu,et al.The research progress of rare earth application in aluminum and aluminum alloys[J].Chinese Rare Earths,2012,33(1):74-80.
[4]
王明丽.EDTA滴定法测定萤石中氟化钙含量的不确定度评定[J].广东化工,2010,37(10):119-120.WANG Ming-li.Evaluation of uncertainty for determination of calcium fluoride content in fluorspar by EDTA titration[J].Guangdong Chemical Industry,2010,37(10):119-120.
[5]
都业俭,张桂梅,薛建萍,等. EDTA法测定RECl3(L)稀土总量影响因素分析[J].包钢科技,2017,43(6):64-68.DU Ye-jian,ZHANG Gui-mei,XUE Jian-ping,et al.Analysis of influencing factors on determination of total rare earth in RECl3(L) by EDTA method[J].Science and Technology of Baotou Steel,2017,43(6): 64-68.
[6]
杨红.EGTA滴定法测定稀土合金中稀土总量[J].冶金分析,2001,21(6):57-59.YANG Hong.Determination of total RE in rare earth alloy by EGTA titrimetry[J].Metallurgical Analysis,2001,21(6):57-59.
[7]
刘昕,魏雪冬,王强.纯铝中铈组稀土总量的测定[J].轻合金加工技术,2002,30(9):34-35.LIU Xin,WEI Xue-dong,WANG Qiang.Measure about cerium RE content in pure aluminium[J].Light Alloy Processing Technology,2002,30(9):34-35.
[8]
孙志峰,张志刚,张翼明,等.镝铁合金中稀土总量的测定-EDTA容量法[J].稀土,2010,31(1):77-79.SUN Zhi-feng,ZHANG Zhi-gang,ZHANG Yi-ming,et al.Determination of total rare earth contents in Dy-Fe alloy with EDTA volume method[J].Chinese Rare Earths,2010,31(1):77-79.
[9]
肖勇.氢氟酸分离-EDTA容量法测定钕铁硼废料中稀土总量[J].江西有色金属,2007,24(1):40-41.XIAO Yong.Hydrofluoric acid separating-EDTA capacity measuring of total rare earth content in neodymium-iron-boron waste material[J].Jiangxi Nonferrous Metals,2007,24(1):40-41.
[10]
杨雪嫚.NaOH浸取EDTA容量法测定发热剂中金属铝[J].特钢技术,2015,82(1):50-52.YANG Xue-man.Determination on aluminum in exothermic agent by EDTA volumetric method with NaOH leaching[J].Special Steel Technology,2015,82(1):50-52.
[11]
刘攀.铝及铝合金中元素分析的标准应用现状与方法研究进展[J].冶金分析,2018,38(4):32-50.LIU Pan.Application status of standards and research progress of methods for elemental analysis in aluminum and aluminum alloy[J].Metallurgical Analysis,2018,38(4):32-50.
[12]
高励珍,张立峰,崔爱端,等.草酸盐重量法测定镝铁合金中稀土总量[J].稀土,2010,31(6):61-66.GAO Li-zhen,ZHANG Li-feng,CUI Ai-duan,et al.Determination of total rare earth content in Dy-Fe alloy with oxalate gravimetric method[J]Chinese Rare Earths,2010,31(6):61-66.
[13]
许涛,王东杰,郝茜.钐钴合金中稀土总量的测定[J].稀土,2014,35(3):72-76.XU Tao,WANG Dong-jie,HAO Qian.Determination of total rare earth contents in SmCo alloy[J].Chinese Rare Earths,2014,35(3):72-76.
[14]
王东杰,易红宏,唐晓龙,等.稀土系储氢合金中稀土总量的测定[J].分析试验室,2016,35(11):1353-1358.WANG Dong-jie,YI Hong-hong,TANG Xiao-long,et al.Determination of total rare earth based in rare earth system hydrogen storage alloys[J].Chinese Journal of Analysis Laboratory,2016,35(11):1353-1358.
[15]
王素梅,张慧珍,郝茜.钆镁合金中稀土总量的测定-草酸盐重量法[J].稀土,2013,34(2): 65-67.WANG Su-mei,ZHANG Hui-zhen,HAO Qian.Determination of rare earth content in gadolinium magnesium alloys-oxalate gravimetric method[J].Chinese Rare Earths,2013,34(2) 65-67.
[16]
孙宇红,李建华,贾建平.稀土镁合金中稀土总量的测定-草酸盐重量法测定稀土总量[J].云南大学学报,2005,27(3):400-402.SONG Yu-hong,LI Jian-hua,JIA Jian-ping.Determination of total rare earth elements in rare earth magnesium alloys-determination of total rare earth elements by oxalate gravimetric method[J].Journal of Yunnan University,2005,27(3):400-402.
