分层取样方式对碳酸氢铵沉淀法生产碳酸稀土过程混合RECl<sub>3</sub>溶液理化指标检测结果的影响研究

doi:10.13228/j.boyuan.issn1000-7571.011701

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摘要稀土的提取与分离需要经过硫酸焙烧、水浸、萃取、反萃和碳沉等一系列过程,其中混合RECl₃溶液是稀土产业线中的重要中间产品,该混合稀土溶液的REO浓度、配分、密度等理化指标是评价混合RECl₃溶液产品质量的主要参数。针对一定存储条件下的混合RECl₃溶液,按照国家标准分析方法,结合X射线荧光光谱法(XRF)、电感耦合等离子体原子发射光谱法(ICP-AES)和重量法等手段,对该溶液中的REO浓度、配分、密度等项目进行检测,研究分层取样方式对3项理化指标的影响及变化规律。通过不同存放时间的变化因素绘制混合RECl₃溶液中REO浓度、密度的变化曲线,得出混合RECl₃溶液的存放时间越长,不同层面取样时这两个指标检测结果差异越大的结论;浅析了混合RECl₃溶液取样深度变化对检测结果的影响因素,对混合RECl₃溶液从表层到底层按照均匀间隔取样进行检测,得出REO浓度和密度的检测结果呈递增趋势,配分的检测结果呈轻稀土含量减少、重稀土含量增加的趋势等结论;研究了混合RECl₃溶液中REO浓度范围差异与存放一定时间内REO浓度的变化趋势,得出REO质量浓度小于50 g/L或大于250 g/L时,其检测结果变化缓慢,REO质量浓度在100～200 g/L时,其检测结果变化快速的结论。深入剖析了分层取样方式影响检测结果的基础理论,此研究可用于指导用于稀土应用产品的混合RECl₃溶液的质量控制,对规范混合RECl₃溶液的取样操作具有重要的指导意义。

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关键词 ：取样方式, 混合RECl₃溶液, REO, 密度, 稀土配分, 存放时间

Abstract：The extraction and separation of rare earths require a series of processes such as sulfuric acid roasting, water leaching, extraction, back extraction, and ammonium bicarbonate precipitation. Among them, the mixed RECl₃ solution is an important intermediate product in the rare earth industry line. The physical and chemical indexes of mixed rare earth solution, including rare earth oxide (REO) concentration, the ratio of single rare earth to the total rare earth, and density, are the key parameters to evaluate the quality of mixed RECl₃ solution products. According to the national standard analysis methods and other approaches including X-ray fluorescence spectrometry (XRF), inductively coupled plasma atomic emission spectrometry (ICP-AES) and gravimetry, the effect of the stratified sampling mode on the determination results of REO concentration, the ratio of single rare earth to the total rare earth, and the solution density in mixed RECl₃ solution stored under certain environmental condition was investigated. The changing curve of REO concentration and density was plotted by varying the storage time. It was found that the difference of determination results of samples with different stratified sampling mode increased with increasing the storage time of mixed RECl₃ solution. The influence factors of sampling depth of mixed RECl₃ solution on the determination results was briefly discussed. The mixed RECl₃ solution was sampled at uniform intervals from surface to bottom for determination. The results of REO concentration and density showed an increasing trend. While the ratio of light rare earth to the total rare earth showed a decreasing trend, and the ratio of heavy rare earth to the total rare earth showed an increasing trend. The variation trend of REO mass concentration with REO concentration range difference in mixed RECl₃ solution within certain storage time were investigated. It was shown that the determination results of REO concentration changed slowly when its mass concentration was less than 50 g/L or higher than 250 g/L. When REO mass concentration was in range of 100-200 g/L, the determination results of REO concentration changed fast. The basic theory for the influence of stratified sampling mode on determination results was deeply analyzed. This study could be used to guide the quality control of mixed RECl₃ solution in rare earth production industry. It had important guiding significance for normalizing the sampling operation of mixed RECl₃ solution.

Key words： sampling mode mixed RECl₃ solution REO density the ratio of single rare earth to the total rare earth storage time

收稿日期: 2021-12-03

ZTFLH:	X751
	TQ133.3

通讯作者: 王东杰(1982—),女,正高级工程师,博士,研究方向为环境工程、冶金分析;E-mail: dongjie_201@163.com

作者简介: 申孟林(1982—),男,高级工程师,硕士,研究方向为湿法冶金;E-mail: shen.menglin@163.com

引用本文:

申孟林, 赵文怡, 李华昌, 王彦, 王东杰. 分层取样方式对碳酸氢铵沉淀法生产碳酸稀土过程混合RECl₃溶液理化指标检测结果的影响研究[J]. 冶金分析, 2022, 42(6): 57-63. SHEN Menglin, ZHAO Wenyi, LI Huachang, WANG Yan, WANG Dongjie. Investigation on effect of the stratified sampling mode on determination results of physical and chemical index of mixed RECl₃ solution produced during rare earth carbonate production by ammonium bicarbonate precipitation method. , 2022, 42(6): 57-63.

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[1] 胡志伟.铁矿石机械化取制样系统设计[J].现代矿业,2017,33(4):206-209,212.
HU Zhiwei.Design of mechanized sampling system for iron ore[J].Modern Mining,2017,33(4):206-209,212.
[2] 韩伟,于志华,祖宁宁.锰硅合金取制样方法研究[J].河南冶金,2008(5):14-15.
HAN Wei,YU Zhihua,ZU Ningning.Study on sampling and preparation of ferromanganese-silicon alloy[J].Henan Metallurgy,2008(5):14-15.
[3] 吴国境,韦星羽,陈永欣,等.全自动取制样系统运行问题及对策研究[J].大众科技,2021,23(6):143-145.
WU Guojing,WEI Xingyu,CHEN Yongxin,et al.Research on operation problems and counter measures of automatic sampling and preparation system[J].Popular Science & Technology,2021,23(6):143-145.
[4]于亚辉,牟保畏,张慧珍,等.散装浮选稀土精矿取样方法探究[J].冶金分析,2022,42(1):36-42.
YU Yahui,MU Baowei,ZHANG Huizhen,et al.Research on sampling methods of bulk flotation rare earth concentrates[J].Metallurgical Analysis,2022,42(1):36-42.
[5] 李艳秋,张西春,李洲,等.矿物取制样系统偏差检验[J].现代矿业,2020,36(9):242-245.
LI Yanqiu,ZHANG Xichun,LI Zhou,et al.Deviation inspection of mineral sampling and preparation system[J].Modern Mining,2020,36(9):242-245.
[6] 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 Yejian,ZHANG Guimei,XUE Jianping.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.
[7] 肖文康.铜精矿取制样品及存储在实践中的应用[J].科学技术创新,2018(31):146-147.
XIAO Wenkang.Application of copper concentrate sampling and storage in practice[J].Scientific and Technological Innovation,2018(31):146-147.
[8] 张彩丽,左兆迎,胡首鹏.基于铁矿石检验的机械取制样风险控制研究[J].检验检疫学刊,2019,29(3):104-106.
ZHANG Caili,ZUO Zhaoying,HU Shoupeng.Research on risk control of mechanical sampling based on iron ore inspection[J].Journal of Inspestion and Quarantine,2019,29(3):104-106.
[9] 居殿春,卿阳,严定鎏,等.氯化物熔盐中钙镁离子固化工艺的热力学分析[J].钢铁钒钛,2011,32(3):25-29.
JU Dianchun,QING Yang,YAN Dingliu,et al.Thermodynamic analysis of Ca²⁺ and Mg²⁺ curing process in molten chlorides[J].Iron Steel Vanadium Titanium,2011,32(3):25-29.
[10] 李毅红.含高岭石煤泥水沉降试验研究[J].选煤技术,2020(5):38-41.
LI Yihong.Experimental study on settlement of kaolinite-containing coal slime water[J].Coal Preparation Technology,2020(5):38-41.
[11] 唐其环,赖丽勤,许文清.采集方法对氯化物沉积速率测试结果的影响[J].装备环境工程,2005(4):42-45.
TANG Qihuan,LAI Liqin,XU Wenqing.The influence of sampling methods on test result of chloride deposition rate in marine environment[J].Equipment Environmental Engineering,2005(4):42-45.
[12] 项跃列.卧螺沉降离心机用于乙基氯化物固液分离生产初探[J].浙江化工,1997(3):43-44.
XIANG Yuelie.Application of horizontal screw sedimentation centrifuge in solid-liquid separation of ethyl chloride[J].Zhejiang Chemical Industry,1997(3):43-44.
[13] Durand A.Aqueous solutions of amphiphilic polysaccharides: concentration and temperature effect on viscosity[J].European Polymer Journal,2007,43(5):1744-1753.
[14] 王道广,王均凤,张香平,等.离子液体在稀土萃取分离中的应用[J].化工学报,2020,71(10):4379-4394.
WANG Daoguang,WANG Junfeng,ZHANG Xiangping,et al.Application of ionic liquid in extraction and separation of rare earth[J].CIESC Journal,2020,71(10):4379-4394.
[15] 张力军.我国稀土冶炼企业发展趋势浅析[J].能源技术与管理,2010(2):105-106,118.
ZHANG Lijun.Analysis on the development trend of rare earth smelting enterprises in China[J].Energy Technology and Management,2010(2):105-106,118.
[16] Jadhav D A,Ray S G,Ghangrekar M M.Third generation in bio-electrochemical system research-a systematic review on mechanisms for recovery of valuable by-products from wastewater[J].Renewable & Sustainable Energy Reviews,2017,76:1022-1031.