稀有金属(英文版) 2020,39(08),959-966

Process mineralogy of Dalucao rare earth ore and design of beneficiation process based on AMICS

Yu Jiao Ke-Hui Qiu Pei-Cong Zhang Jun-Feng Li Wen-Tao Zhang Xian-Fei Chen

School of Materials and Chemistry and Chemical Engineering, Chengdu University of Technology

School of Science,Xichang University

Institute of Materials Science and Technology,Chengdu University of Technology

作者简介：*Ke-Hui Qiu,e-mail:qkh2188@163.com;

收稿日期：5 December 2019

基金：financially supported by the Science and Technology Support Project in Sichuan(No. 2017GZ0400);

Process mineralogy of Dalucao rare earth ore and design of beneficiation process based on AMICS

Yu Jiao Ke-Hui Qiu Pei-Cong Zhang Jun-Feng Li Wen-Tao Zhang Xian-Fei Chen

School of Materials and Chemistry and Chemical Engineering, Chengdu University of Technology

School of Science,Xichang University

Institute of Materials Science and Technology,Chengdu University of Technology

Abstract：

The test results of the automated mineral identification and characterization system(AMICS),including the mineral composition,particle size distribution,dissemination state and degree of liberation of the target minerals,could be used to improve the beneficiation process.Taking the Dalucao rare earth ore located in Dechang,Sichuan Province,China(with an average content of 2.40 wt%) as the research object in this paper,the chemical composition,phase composition and dissemination state of the minerals were tested by AMICS,and the minerals of different fineness were ground.The concentrate yield,grade and recovery rate of the minerals of different fineness were compared through flotation tests.When the grinding lasted for 5 min and 82.60% of mineral grains passed through the-74-μm sieve,the yield,grade and recovery rate could reach 20.19%,8.75% and 73.64%,respectively(as the best grinding fineness),under the same flotation conditions.

Keyword：

Automated mineral identification and characterization system(AMICS); Bastnasite; Dalucao; Flotation;

Received： 5 December 2019

1 Introduction

China is rich in rare earth mineral resources with superior metallogenic conditions and unique advantages.The Mianning-Dechang (MD) Himalayan REE belt in western Sichuan is approximately 270 km long and 15 km wide,hosting one giant (Maoniuping),one large (Dalucao),two small-medium-sized deposits (Muluozhai and Lizhuang)and numerous other mineralized occurrences and points [ 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12] .

Dechang Dalucao REE deposit is classified into a rare earth (bastnasite) deposit,and the minerals have been seriously weathered.The rare earth minerals exist mainly in the form of bastnasite and parisite.The rare earth minerals have a small monocrystal grain size and are interlocked with other minerals such as barite,fluorite,celestite and calcite,eventually leading to a serious encapsulation phenomenon [ 13, 14, 15] .During flotation,the grinding fineness seriously affected the grade and recovery rate of the rare earth ore concentrates.Accurate research on process mineralogy had important guiding significance to later beneficiation.Currently,the research on process mineralogy of Dalucao bastnasite was carried out mainly through chemical analysis and spectral analysis [ 16, 17, 18] .Owing to the particularity of the samples,many samples needed to be prepared,with a long analysis cycle and big errors.It was extremely important that an advanced mineral analysis method was adopted to provide a reliable basis for beneficiation [ 19, 20, 21, 22] .

Compared with other analysis means,automated mineral identification and characterization system (AMICS) is the latest generation (the third generation) of automated mineral identification and characterization system,followed by QEMSCAN and MLA [ 23, 24, 25, 26] .The chemical composition of each mineral grain (micro-area) is analyzed through energy spectrum analysis,and the backscattering image data of the samples were acquired by electron microscope.Besides,the analysis software can support grainy treatment of complex,multi-component and paragenetic ore samples and subpide these ore samples into different mineral compositions.Mineral data and parameters are obtained through a series of data processing,and mineral composition and other process mineralogy results are presented in a graphical form,as the most cutting-edge analysis and test method in the mineral and geological industry across the world.Compared with MLA,AMICS has lower requirements for sample size.Besides,it can be used to measure the samples with size of 1μm-50 mm,and it is provided with a more complete mineral database,up to more than 2000 kinds.The system can automatically identify and match the samples to be tested.AMICS supports the updated algorithm,and the energy spectrum can test more mineral boundaries and surfaces,which can not only more accurately determine the zone boundary and identify the zones with similar gray levels,but also increase the calculation speed.To sum up,AMICS can provide more accurate and complete mineral information.Based on the uniqueness of the research on the process mineralogy of Dalucao bastnasite,AMICS was used to study the process mineralogy and ascertain the chemical composition,phase composition,dissemination characteristics and degree of liberation,thus laying a solid foundation for flotation and ore grinding [ 27, 28, 29, 30, 31, 32, 33, 34, 35] .

2 Experimental

2.1 Materials and instruments

Nitric acid,hydrochloric acid,perchloric acid,oxalic acid,ammonium chloride and ammonium hydroxide were analytical pure and were purchased from Chengdu CHRON Chemicals Co.,Ltd.Salicylhydroxamic acid (99.5%),sodium silicate (modulus 2.8) and turpentine (2#oil) were purchased from Shanghai Yuanye Bio-Technology Co.,Ltd.;Dechang Dalucao rare earth ores were harvested,crushed into-15 mm and packaged by Sichuan Hedi Mining Co.,Ltd.

The automated mineral identification and characterization systems (AMICS) were as follows:ZEISS (sigma 500)mineral liberation analyzer (German) for determining the chemical composition,phase composition,particle size distribution,dissemination state and degree of liberation);Epsilon 3 X-ray fluorescence spectrometer (XRF) produced by PANalytical B.V.is used for elemental composition and content analysis;planetary ball mill using a ball mill(XQM2L) from Tianjin Hongyang Machinery Equipment Co.,Ltd.,for reducing the mineral fineness;single-trough flotation machine with a 1-L single-trough flotation machine (XFD-111) from Shaoxing Shangyu Jinfeng Machinery Equipment Co.,Ltd.for flotation test.

2.2 Experimental process

AMICS test was as follows.The sample needed to be premade into a cylinder with a diameter of 30 mm.The samples were observed on a polished round surface with a diameter of 30 mm.Hence,the tested ore samples were crushed and then the particle samples were cold-mounted in a cylinder with a diameter of 30 mm using epoxy resin.

The grinding process is shown in flowchart (Fig.1).After mixing,300 g of ground minerals was poured into a1-L flotation tank,water was filled to the scale mark,and flotation was carried out at room temperature with a ventilation rate of 0.35 m³·h^-1 and a stirring rate of 3000r·min^-1.As the foam was blown out,water was continuously filled so as to ensure that the foam can be blown out.The total rare earth was determined by oxalate gravimetric method and was titrated with reference to GBT14635-2008.

3 Results and discussion

Through the electron microscope test and energy spectrum test of AMICS,as well as analysis of the quantitative analysis system,the chemical composition,phase composition,occurrence state of rare earth in the minerals,particle size distribution and degree of liberation can be obtained.

3.1 Process mineralogy analysis of ore samples

3.1.1 Main chemical composition and phase composition of ore samples

After the rare earth elements were listed,the chemical elements were sorted according to the content from high to low,as shown in Table 1.As seen,the rare earth elements in the ore mainly included Ce,La and a small amount of Y,and other elements were mainly Si,Ca,F,Sr,Al,K,S,Fe and Ba.Rare earths may exist in the form of oxides,fluorides,sulfides,sulfates,silicates or carbonates.

Fig.1 Flowchart of grinding process

  下载原图

Table 1 Main chemical composition of ore from XRF test (wt%)

Chemical composition only representing statistical results of mineral particles in scanning area;total content of 99.90 wt%

  下载原图

Table 2 Main mineral composition in raw bastnasite from MLA test

Phases with a mineral content below 1 wt%being included into column“Other”,including magnetite (0.54 wt%),limonite (0.52wt%),wollastonite (0.47 wt%),galena (0.15 wt%),manganese (0.14wt%),apatite (0.13 wt%),rutile (0.10 wt%) and unknown ores (2.22wt%)

After the rare earth occurrence phases were listed,the phases were sorted by content from low to high,as shown in Table 2.As seen,Ce and La mainly occurred in bastnasite-(La) and bastnasite.Si mainly occurred in feldspar minerals (30.09 wt%),quartz (12.49 wt%) and biotite (3.10wt%),and Ca mainly occurred in anorthite (1.35 wt%),calcite (14.82 wt%) and fluorite (10.04 wt%).F mainly occurred in bastnasite-(La)(4.99 wt%),bastnasite (1.01wt%) and fluorite (10.04 wt%),and Sr mainly occurred in celestite (10.35 wt%).Al mainly occurred in feldspar(30.09 wt%),biotite (3.10 wt%) and kaolinite (2.03 wt%).K mainly occurred in potassium feldspar (17.31 wt%),and S mainly occurred in celestite (10.35 wt%),barite (4.06wt%) and pyrite (2.41 wt%).Fe mainly occurred in biotite(3.10 wt%) and pyrite (2.41 wt%).Ba mainly occurred in celestite (10.35 wt%) and barite (4.06 wt%).The content of chemical elements in Table 1 was fully consistent with the phase content of the elements.

According to the main phases in the minerals from Table 2,the rare earth minerals of the Dechang Dalucao Rare Earth Mine are bastnasite-(La) and bastnasite,of which the bastnasite has a large density and can be separated from feldspar minerals (2.55-2.75 g·cm^-3),calcite(2.6-2.8 g·cm^-3),quartz (2.65 g·cm^-3),fluorescence(3.175-3.56 g·cm^-3),biotite (3.02-3.12 g·cm^-3) and kaolinite (2.60-2.63 g·cm^-3) through gravity separation.However,barite (4.2-4.5 g·cm^-3) and celestite(3.9-4.0 g·cm^-3) with a large density cannot be separated through gravity separation.As barite and celestite are nonmagnetic and bastnasite is weakly magnetic,they can be separated by strong magnetic separation.

Besides,hydroxamic acid collector which has a good collection effect for bastnasite can be used to separate bastnasite from gangue mineral by flotation.

3.1.2 Composition of bastnasite-(La) and bastnasite in ore samples

Typical particles of bastnasite-(La) and bastnasite were selected,respectively.Figure 2 shows energy spectrum analysis.The analysis results are shown in Tables 3 and 4.For bastnasite-(La)(molecular formula (Ce,La)[CO₃]F),theoretical chemical composition consists of REO (rare earth oxides)(74.77%-74.88%) and F (8.72%).For bastnasite (Ce(CO₃)F),theoretical chemical composition consists of REO (74.88%) and F (6.39%).As seen from Table 3,among five typical particles tested,the REO content of the bastnasite ranged between 84.25 wt%and86.87 wt%,with an average of 85.78 wt%,while the F content ranged between 5.34 wt%and 6.02 wt%,with an average of 5.65 wt%.The REO content was higher than the theoretical calculation value,but the F content was lower than the theoretical calculation value,possibly because some rare earth oxides were disseminated in the bastnasite phase.OH and F were in perfect isomorphism,and some F was replaced by OH in the bastnasite,which were similar to the results in Table 4.

3.1.3 Dissemination characteristics of bastnasite-(La)and bastnasite in ores

3.1.3. 1 Schematic diagram.for determination of ore samples by AMICS

Through phase analysis of the minerals,the main composition of the minerals was ascertained.According to different brightness of different minerals in the electron backscattering diagram,different minerals were identified as different colors after granulated graphic processing of the samples using the mineral characterization system;thus,the process diagram was obtained,as shown in Fig.3.

Fig.2 Typical phases and EDS spectra:a,b bastnasite-(La) and c,d bastnasite

  下载原图

Table 3 Chemical composition of bastnasite-(La) from MLA test (wt/%)

  下载原图

Table 4 Chemical composition of bastnasite from MLA test (wt/%)

3.1.3. 2 Dissemination characteristics of bastnasite-(La)and bastnasite

As seen from Fig.4,the bastnasite-(La)and bastnasite were encapsulated by various gangue minerals in the ore samples and formed a symbiotic,interlocked and encapsulated relationship with the gangue minerals.As seen from Table 5,when the ore was ground to-74μm,the degree of liberation of the bastnasite-(La)was as high as 79.45%,while that of bastnasite was as high as 72.62%,and the remaining rare earth ores and gangue minerals were under a symbiotic,interlocked and encapsulated relationship.In this case,the ores were beneficiated by gravity separation.Bastnasite-(La) and bastnasite were under intergrowth with feldspar,calcite,quartz,fluorite and biotite,and 18.79%and 23.61%of rare earth ores would be directly lost,respectively.In this case,the ores were beneficiated by magnetic separation.Bastnasite-(La) and bastnasite were under intergrowth with barite and celestite,and 1.76%and 3.14%of rare earth ores would be directly lost,respectively.During flotation of bastnasite-(La) and bastnasite using hydroxamic acid collector,some gangue minerals can also be collected.Therefore,if the ores were beneficiated by gravity separation,this would lead to a high grade but a very low recovery rate.Gravity separation and flotation may lead to a grade cutoff,but a higher yield could be guaranteed.

Fig.3 Schematic diagram for determination of ore samples by AMICS:a SEM image and b result diagram of mineral analysis

Fig.4 Backscattering diagram of dissemination characteristics of rare earth mineral particles:a bastnasite encapsulated by gangue minerals,b bastnasite and bastnasite-(La) showing mutual replacement and association,c needle-like bastnasite precipitated on gangue mineral surface,and d bastnasite particles under liberation

  下载原图

Table 5 Dissemination characteristics of rare earth ores and main minerals in-74-μm ore samples from MLA test (wt/%)

Fig.5 Particle size distribution of rare earth minerals of a bastnasite-(La) and b bastnasite

  下载原图

Table 6 Grinding test conditions

3.1.3. 3 Particle size distribution of bastnasite-(La) and bastnasite in the ores

As can be seen from Fig.4,the size of over 80%particles of bastnasite-(La) and bastnasite was mainly 10-75μm and 10-20μm,respectively,but the size of over 65%bastnasite-(La) was mainly 30-75μm;the size of over 90%bastnasite-(La) was mainly less than20μm.According to Table 2,the content ofthe bastnasite-(La) in the ore was 4.99 wt%,while that of the bastnasite was 1.01 wt%.The content of the bastnasite-(La) was higher than that of the bastnasite,and the particle size was larger than that of the bastnasite.If the grinding size was too large,the monomers would not be liberated.However,if the grinding size was too small,the target minerals were easily clustered with the gangue minerals.Therefore,in terms of grinding fineness,priority should be given to the monomer particle size of the bastnasite-(La).The grinding fineness should mainly range between 30 and 75μm.

3.2 Ore sample flotation test

The grinding time,costs and total beneficiation cost increased.Besides,the grinding fineness was closely related to the beneficiation indexes.According to the analysis results shown in Fig.5,the grinding process was developed,as shown in Table 6.The ground minerals were floated and verified,as shown in flotation process (Fig.6).The flotation results are shown in Table 7.

Fig.6 Flowchart of flotation process

  下载原图

Table 7 Flotation results at different flotation time

According to the results shown in Table 7,the grinding fineness had a significant effect on the recovery rate of the rare earth ore concentrates.With the increase in the grinding fineness and the degree of liberation of main rare earth minerals (bastnasite-(La) and bastnasite),the grade and recovery rate of rare earth ore concentrates would increase.However,as the grinding fineness further increased,the grade and recovery rate would begin to decline.The best grinding fineness occurred when the grinding lasted for 5 min and about 80%passed through the-74-μm sieve.

4 Conclusion

Through AMICS test and analysis,the rare earth minerals of the Dechang Dalucao ore were mainly bastnasite-(La)(4.99 wt%) and bastnasite (1.01 wt%).The main gangue minerals were feldspar minerals (30.09 wt%),calcite(14.82 wt%),quartz (12.49 wt%),celestite (10.35 wt%),fluorite (10.04 wt%),barite (4.06 wt%),biotite (3.10 wt%),pyrite (2.41 wt%) and kaolinite (2.37 wt%).

Judging from mineral types,the rare earth minerals,barite and celestite can be separated from feldspar minerals,calcite,quartz,fluorite,biotite and kaolinite by gravity separation,and the rare earth minerals were separated from barite and celestite by magnetic separation.The minerals formed a symbiotic,interlocked and encapsulated relationship.However,seen from the degree of liberation,the intergrowth of the rare earth ore and feldspar,as well as calcite,quartz,fluorite and biotite was severe.Gravity separation would lead to a low yield of rare earth,and highgrade minerals cannot be obtained if only magnetic separation was used.Therefore,the Dechang Dalucao ore was beneficiated by both gravity separation and magnetic separation at best.

During flotation of bastnasite-(La) and bastnasite using hydroxamic acid collector,some gangue minerals (especially those inter-grown with rare earth) can also be collected.Therefore,flotation could lead to a higher yield of the rare earth ore concentrates.

The grinding fineness had a significant effect on flotation.When the grinding lasted for 5 min and 82.60%of mineral grains passed through the-74-μm sieve,the main rare earth mineral (bastnasite) in the minerals could be liberated.The yield,grade and recovery rate of the rare earth ore concentrates could reach 20.19 wt%,8.75 wt%and 73.64 wt%,respectively (the optimum grinding fineness),under the same flotation conditions.

Acknowledgements This study was financially supported by the Science and Technology Support Project in Sichuan (No.2017GZ0400))

参考文献

[1] Chakhmouradian AR,Wall F.Rare earth elements:minerals,mines,magnets(and more).Elements.2012;8(5):3 33.

[2] Xin L,Xu G.Father of Chinese rare earths chemistry.Bull Chin Acad Sci.2009;23(2):98.

[3] Shu XC,Liu Y,Li DG.Geochemical characteristics and geological significance of fenites in the Mianning-Dechang REE belt,western Sichuan Province.Acta Petrol Sin.2019;35(5):1372.

[4] Li Z,Liu Y.Ore types and genesis of weathered deposits in mianning-dechang REE ore belt,Western Sichuan Province,Southwestern China.Earth Sci.2018;43(4):1307.

[5] Chakhmouradian AR,Smith MP,Kynicky J.From “strategic”tungsten to “green” neodymium:a century of critical metals at a glance.Ore Geol Rev.2014;64(1):455.

[6] Weng ZH,Jowitt SM,Mudd GM,Haque NA.A detailed assessment of global rare earth element resources:opportunities and challenges.Econ Geol.2015;110(8):1925.

[7] Hou ZQ,Tian SH,Xie YL.The Himalayan Mianning-Dechang REE belt associated with carbonatite-alkaline complexes,eastern Indo-Asian collision zone,SW China.Ore Geol Rev.2009;36(1-3):65.

[8] Massari S,Ruberti M.Rare earth elements as critical raw materials:focus on international markets and future strategies.Resour Policy.2012;38(1):36.

[9] Yl XIE.Ore Genesis and deposit model of carbonatite-host REE deposits:the Mianning-Dechang REE Belt,Western Sichuan province,China.Acta Geol Sin(Engl ed).2014;88(z2):475.

[10] Liu Y,Chen C,Shu XC.The formation model of the carbonatite-syenite complex REE deposits in the east of Tibetan Plateau:a case study of Dalucao REE deposit.Acta Petrol Sin.2017;33(7):1978.

[11] Ling XX,Li QL,Liu Y.In situ SIMS Th-Pb dating of bastnaesite:constraint on the mineralization time of the Himalayan Mianning-Dechang rare earth element deposits.J Anal atom Spectrom.2016;31(8):1680.

[12] Niu HC,Shan QA,Chen XM.Relationship between light rare earth deposits and mantle processes in Panxi rift,China.SCI China Ser D-Earth Sci.2003;46(1):41.

[13] Guo DX,Liu Y.Occurrence and geochemistry of Bastnasite in carbonatite-related REE deposits,Mianning-Dechang REE belt,Sichuan Province,SW China.ORE Geol Rev.2019;107:266.

[14] Ouyang H,Liu Y.REE mineralization and characteristics of wall rocks in the muluozhai REE deposit,mianning county,Sichuan Province.Acta Geosci Sin.2018;39(3):329.

[15] Li XY.Geological characteristics of Dalucao REE deposit in Dechang County,Sichuan Province.Miner Depos.2005;24(2):151.

[16] Xiong WL,Deng J,Chen BY.Flotation-magnetic separation for the beneficiation of rare earth ores.Miner Eng.2018;119:49.

[17] Fandrich R,Gu Y,Burrows D,Moeller K.Modern SEM-based mineral liberation analysis.Int J Miner Process.2007;84(1-4):310.

[18] Liu Y.Chemical and mineralogical study on bastnaesite:dominated rare earth ores.Chem Eng Trans.2017;59:973.

[19] Tian Y,Liu TA,Zhang GZ,Lv S,Zhou GQ.Kinetics of indium dissolution from marmatite with high indium content in pressure acid leaching.Rare Met.2017;36(1):69.

[20] Deng ZB,Tong X,Valpieso AL,Wang X,Xie X.Collectorless flotation of marmatite with pine oil.Rare Met.2017;36(2):147.

[21] Li YR,Xiong QH.A cross-field exploration of information technology and materials science.InfoMat.2019;1(1):4.

[22] Zhang Y,Lin H,Dong YB,Xu XF,Wang X,Gao YJ.Coupling relationship between multicomponent recovery of rare earth tailings.Rare Met.2017;36(3):220.

[23] Ying G.Automated scanning electron microscope based mineral liberation analysis.J Min Mater Charact Eng.2003;2(1):33.

[24] Fang MS,Wang MY.Application of AMICS in comprehensive recovery of associated gold and silver in a copper ore.Mining Metall.2018;27(3):104.

[25] Xu CL,Zhong CB,Lyu RL.Process mineralogy of Weishan rare earth Ore by MLA.J Rare Earth.2019;3:334.

[26] Wen LG,Zeng PS,Zhan XC,Fan CZ,Sun DY,Wang G,Yuan JH.Application of the automated mineral identification and characterization system(AMICS)in the Identification of rare earth and rare minerals.Rock Miner Anal.2019;37(2):121.

[27] Zhang ZY,He ZY,Yu JX,Xu ZG,Chi RA.Novel solution injection technology for in situ leaching of weathered crust elution-deposited rare earth ores.Hydrometallurgy.2016;164:248.

[28] Zhang N,Li HX,Cheng HJ,Liu XM.Electron probe microanalysis for revealing occurrence mode of scandium in Bayer red mud.Rare Met.2017;36(4):295.

[29] Zhang ZY,Sun NJ,He ZY,Chi RA.Local concentration of middle and heavy rare earth elements on weathered crust elution-deposited rare earth ores.J Rare Earths.2018;36(5):552.

[30] Cox C,Kynicky J.The rapid evolution of speculative investment in the REE market before,during,and after the rare earth crisis of 2010-2012.Extr Ind Soc.2018;5(1):8.

[31] Kynicky J,Smith MP,Cheng X.Diversity of rare earth deposits:the key example of china.Elements.2012;8(5):361.

[32] Xu C,Kynicky J,Chakhmouradian AR,Li XH,Song WL.A case example of the importance of multi-analytical approach in deciphering carbonatite petrogenesis in South Qinling orogen:Miaoya rare-metal deposit,central China.Lithos.2015;227:107.

[33] Wei J,Chu X,Sun XY,Xu K,Deng HX,Chen JG,Wei ZM,Lei M.Machine learning in materials science.InfoMat.2019;1:338.

[34] Chi RA,Wang DZ.Rare Earth Mineral Processing.Beijing:Science Press.2014.1.

[35] Feng M,Cheng X,Kynicky J,Zeng L,Song WL.Rare earth element enrichment in palaeoproterozoic fengzhen carbonatite from the North China block.Int Geol Rev.2016;58(15):1940.