Leaching isomorphism rare earths from phosphorite ore by sulfuric acid and phosphoric acid 被引量：2

Leaching isomorphism rare earths from phosphorite ore by sulfuric acid and phosphoric acid

导出

摘要 Most of the phosphorite deposits in the world contain isomorphism rare earths （RE） which are considerably difficult to be leached into solution in the wet phos- phoric acid process. In this work, a systematic study of leaching RE using sulfuric acid, phosphoric acid, mixed acid and two-step leaching of phosphoric acid and sulfuric acid was performed. The aims are to illuminate the main factors that inhibit RE leaching and to provide insights into the further enrichment of RE in the wet phosphoric acid solution. The results indicate that H2SO4 is not an effective acid for leaching isomorphism RE from phosphorite ore. The low RE leaching efficiency attributes to the RE cocrystallized and encapsulated by phosphogypsum （PG） as well as the precipitation of RE by RE sulfates or phosphates. High concentration of H3PO4 can enhance the dissolution and diffusion of RE ions. Hence, the optimized leaching mode of improving RE leaching efficiency is to adequately dissolve phosphorite ores in high concentration of H3PO4 solution and then add H2SO4 to crystallize PG. The effect of corystallization or encapsulation of PG on RE can be decreased due to the crystallizing mode of PG in the bulk solution instead of on the interface of solid reactants. RE leaching efficiency can be high up to 65% by the optimized leaching mode. Most of the phosphorite deposits in the world contain isomorphism rare earths （RE） which are considerably difficult to be leached into solution in the wet phos- phoric acid process. In this work, a systematic study of leaching RE using sulfuric acid, phosphoric acid, mixed acid and two-step leaching of phosphoric acid and sulfuric acid was performed. The aims are to illuminate the main factors that inhibit RE leaching and to provide insights into the further enrichment of RE in the wet phosphoric acid solution. The results indicate that H2SO4 is not an effective acid for leaching isomorphism RE from phosphorite ore. The low RE leaching efficiency attributes to the RE cocrystallized and encapsulated by phosphogypsum （PG） as well as the precipitation of RE by RE sulfates or phosphates. High concentration of H3PO4 can enhance the dissolution and diffusion of RE ions. Hence, the optimized leaching mode of improving RE leaching efficiency is to adequately dissolve phosphorite ores in high concentration of H3PO4 solution and then add H2SO4 to crystallize PG. The effect of corystallization or encapsulation of PG on RE can be decreased due to the crystallizing mode of PG in the bulk solution instead of on the interface of solid reactants. RE leaching efficiency can be high up to 65% by the optimized leaching mode.

作者 Hui-Xin Jin Fu-Zhong Wu Xiao-Hao Mao Mei-Long Wang Hong-Yan Xie

机构地区 College of Materials and Metallurgy Guizhou Province Key Laboratory of Metallurgical Engineering and Process Energy Saving

出处《Rare Metals》 SCIE EI CAS CSCD 2017年第10期840-850,共11页 稀有金属（英文版）

基金 financially supported by the National Natural Science Foundation of China (Nos. 51364005, 51564003 and 51574094)

关键词 PHOSPHORITE ISOMORPHISM Rare earths LEACHING Sulfuric acid Phosphoric acid Phosphorite Isomorphism Rare earths Leaching Sulfuric acid Phosphoric acid

分类号 TF845 [冶金工程—有色金属冶金]

引文网络
相关文献

参考文献7

1Yan-Fei Xiao,Zong-Yu Feng,Gu-Hua Hu,Li Huang,Xiao-Wei Huang,Ying-Ying Chen,Ming-Lai Li.Leaching and mass transfer characteristics of elements from ion-adsorption type rare earth ore[J].Rare Metals,2015,34(5):357-365. 被引量：28
2Lin Yang,Jianxin Cao,Caiyu Li.Enhancing the hydration reactivity of hemi-hydrate phosphogypsum through a morphology-controlled preparation technology[J].Chinese Journal of Chemical Engineering,2016,24(9):1298-1305. 被引量：6
3陈吉艳,杨瑞东,魏怀瑞,高军波.Rare earth element geochemistry of Cambrian phosphorites from the Yangtze Region[J].Journal of Rare Earths,2013,31(1):101-112. 被引量：14
4Xiao-Wei Huang,Zhi-Qi Long,Liang-Shi Wang,Zong-Yu Feng.Technology development for rare earth cleaner hydrometallurgy in China[J].Rare Metals,2015,34(4):215-222. 被引量：81
5池汝安,田君.风化壳淋积型稀土矿评述[J].中国稀土学报,2007,25(6):641-650. 被引量：233
6金会心,李军旗,吴复忠.含稀土磷矿酸解动力学及稀土浸出机理[J].北京科技大学学报,2011,33(9):1071-1078. 被引量：22
7张杰,孙传敏,杨国峰,谢飞.Separation and Enrichment of Rare Earth Elements in Phosphorite in Xinhua,Zhijin,Guizhou[J].Journal of Rare Earths,2006,24(z2):413-414. 被引量：6

二级参考文献63

1陈吉艳,杨瑞东.Analysis on REE geochemical characteristics of three types of REE-rich soil in Guizhou Province,China[J].Journal of Rare Earths,2010,28(S1):517-522. 被引量：13
2宋云华,沈丽璞.酸性火山岩类风化壳中稀土元素的地球化学实验研究[J].地球化学,1986,15(3):225-234. 被引量：38
3YANGRuidong,QIANYi,ZHANGJie,ZHANGWeihua,JIANGLijun,GAOHui.Sponge spicules in phosphorites of the Early Cambrian Gezhongwu Formation,Zhijin,Guizhou[J].Progress in Natural Science:Materials International,2004,14(10):896-902. 被引量：8
4施春华,胡瑞忠,王国芝.贵州织金磷矿岩稀土元素地球化学特征研究[J].矿物岩石,2004,24(4):71-75. 被引量：45
5陈吉艳,张杰.贵州织金新华含稀土磷矿床矿区土壤稀土元素分布特征[J].矿物岩石地球化学通报,2005,24(1):71-74. 被引量：8
6喻庆华,李先柏.晶型碳酸稀土的形成及其影响因素[J].中国稀土学报,1993,11(2):171-173. 被引量：36
7池汝安,王淀佐.量子化学计算粘土矿物的吸附性能和富集稀土的研究[J].中国稀土学报,1993,11(3):199-203. 被引量：13
8陈志澄,陈达慧,俞受鋆,庄文明,洪华华,符群策.试论有机质在华南花岗岩风化壳REE溶出、迁移和富集中的作用[J].地球化学,1994,23(2):168-178. 被引量：22
9林传仙,郑作平.风化壳淋积型稀土矿床成矿机理的实验研究[J].地球化学,1994,23(2):189-198. 被引量：36
10黄小卫,龙志奇,李红卫,应娓娟,张国成,薛向欣.Development of Rare Earth Hydrometallurgy Technology in China[J].Journal of Rare Earths,2005,23(1):1-4. 被引量：39

共引文献360

1尹伟强,赵锦辉,赵龙胜,刘德鹏,齐少雷,冯宗玉.稀土萃余水相中乳化油滴稳定性及Al^(3+)水解破乳机制[J].稀有金属,2022,46(10):1322-1330.
2郝健松,强毅.离子型稀土矿区氨氮污染机理及修复研究进展[J].中国水运（下半月）,2021,21(6):73-75. 被引量：1
3Jiang Liu,Zhihe Dou,Ting’an Zhang.Kinetic study on bastnaesite concentrate mechanochemical decomposition in NaOH solution[J].Journal of Rare Earths,2020,38(4):418-426. 被引量：2
4Zonghe Yu,Meng Wang,Liangshi Wang,Longsheng Zhao,Zongyu Feng,Xu Sun,Xiaowei Huang.Preparation of crystalline mixed rare earth carbonates by Mg(HCO3)2 precipitation method[J].Journal of Rare Earths,2020,38(3):292-298. 被引量：9
5张子军,杨绍文,段文婷,严城民,张黎,王长兵,赵锦程,倪光清.滇西南岔河稀土矿稀土氧化物富集系数及其研究意义[J].稀土,2022,43(1):98-105. 被引量：1
6郭钟群,赵奎,周尖荣,金解放,周可凡.离子吸附型稀土矿分形特性及土-水特征曲线预测研究[J].稀土,2022,43(1):56-65. 被引量：1
7刘楚凡,周芳,吴晓燕,冯健,池汝安.风化壳淋积型稀土矿浸出渗流和传质过程研究现状及展望[J].稀土,2021,42(1):111-121. 被引量：8
8王启沛,张萌,冯兵,朱秋平,姚娜,杨兵,李发东,张依章,吴俊伟,吴少林.南方离子吸附型稀土尾矿不同土层氮污染现状的垂向特征[J].稀土,2021,42(1):30-44. 被引量：8
9赵永红,张涛,成先雄.离子吸附型稀土矿区土壤与水环境氨氮污染及防治技术研究进展[J].稀土,2020,41(1):124-132. 被引量：26
10周凌波,王晓军,黄成光,汪豪,卓毓龙,陈刚.浸矿过程中离子吸附型稀土矿力学特性实验研究[J].稀土,2020,41(1):26-36. 被引量：2

同被引文献14

1王犇,孟韵,段春生.废钴钼系催化剂中金属的全回收新工艺研究[J].现代化工,2005,25(z1):204-206. 被引量：8
2曹洁明,侯海涛,马贤佳,姬广斌,郑明波,陆红霞.溶剂热合成具有纳米孔结构的γ-Al_2O_3[J].无机化学学报,2005,21(9):1379-1382. 被引量：4
3ZHOU Hualei,LI Dongyan,TIAN Yajun,CHEN Yunfa.Extraction of scandium from red mud by modified activated carbon and kinetics study[J].Rare Metals,2008,27(3):223-227. 被引量：20
4Meng Xiuhong,Duan Linhai,Xie Xiaohua,Wang Qiang,Wang Haiyan.Synthesis of Macro-Mesostructured γ-Al_2O_3 with Large Pore Volume and High Surface Area by a Facile Secondary Reforming Method[J].China Petroleum Processing & Petrochemical Technology,2014,16(2):20-28. 被引量：2
5Xiao-Wei Huang,Zhi-Qi Long,Liang-Shi Wang,Zong-Yu Feng.Technology development for rare earth cleaner hydrometallurgy in China[J].Rare Metals,2015,34(4):215-222. 被引量：81
6刘成龙,夏举佩,张永波.酸浸提取煤矸石中氧化铝工艺优化及其动力学[J].过程工程学报,2015,15(4):579-583. 被引量：16
7Lei Tian,Yan Liu,Ting-An Zhang,Guo-Zhi Lv,Shuang Zhou,Guo-Quan Zhang.Kinetics of indium dissolution from marmatite with high indium content in pressure acid leaching[J].Rare Metals,2017,36(1):69-76. 被引量：11
8谌纯,张一敏,包申旭,黄晶,杨晓.叔胺N235从石煤酸浸液中分离富集钒[J].稀有金属,2017,41(4):422-428. 被引量：13
9冯宗玉,黄小卫,王猛,张国成.典型稀土资源提取分离过程的绿色化学进展及趋势[J].稀有金属,2017,41(5):604-612. 被引量：55
10Na Zhang,Hong-Xu Li,Hui-Jing Cheng,Xiao-Ming Liu.Electron probe microanalysis for revealing occurrence mode of scandium in Bayer red mud[J].Rare Metals,2017,36(4):295-303. 被引量：7

引证文献2

1Qi Liu,Wen-Qiang Wang,Yue Yang,Xue-Gang Liu,Sheng-Ming Xu.Recovery and regeneration of Al_2O_3 with a high specific surface area from spent hydrodesulfurization catalyst CoMo/Al_2O_3[J].Rare Metals,2019,38(1):1-13. 被引量：5
2Chuanying Liu,Li Chen,Ji Chen,Dan Zou,Yuefeng Deng,Deqian Li.Application of P507 and isooctanol extraction system in recovery of scandium from simulated red mud leach solution[J].Journal of Rare Earths,2019,37(9):1002-1008. 被引量：22

二级引证文献27

1尹伟强,赵锦辉,赵龙胜,刘德鹏,齐少雷,冯宗玉.稀土萃余水相中乳化油滴稳定性及Al^(3+)水解破乳机制[J].稀有金属,2022,46(10):1322-1330.
2王毅,陈凯.深圳市河道治理中的绿化[J].珠江现代建设,2000(3):37-38. 被引量：1
3隋宝宽,朱慧红,吕振辉,彭冲.渣油废催化剂回收制备拟薄水铝石[J].石油化工高等学校学报,2019,32(6):8-13. 被引量：2
4Wei Hua,Huan-Huan Sun,Fei Xu,Jian-Gan Wang.A review and perspective on molybdenum-based electrocatalysts for hydrogen evolution reaction[J].Rare Metals,2020,39(4):335-351. 被引量：24
5孙帅,孙宏骞,宋静,曲景奎,齐涛.钪资源现状及溶剂萃取在钪提取过程中的应用研究进展[J].过程工程学报,2020,20(8):877-886. 被引量：7
6Xiaobo Zhu,Wang Li,Baolin Xing,Yude Zhang.Extraction of scandium from red mud by acid leaching with CaF2 and solvent extraction with P507[J].Journal of Rare Earths,2020,38(9):1003-1008. 被引量：11
7Xitao Wu,Zhijian Wang,Chuping Xia,Xuefeng Shi,Tianzong Luo,Xinjun Bao,Rongli Liu,Shengzhong Xie.Kinetics study on leaching of rare earth and aluminum from polishing powder waste using hydrochloric acid[J].Journal of Rare Earths,2020,38(9):1009-1018. 被引量：3
8Xuekai Zhang,Kanggen Zhou,Yehuizi Wu,Qingyuan Lei,Changhong Peng,Wei Chen.Separation and recovery of iron and scandium from acid leaching solution of red mud using D201 resin[J].Journal of Rare Earths,2020,38(12):1322-1329. 被引量：6
9Mingxia Huang,Yongmei Fu,Youcai Lu,Wuping Liao,Zhongjun Li.A novel extractant bis(2-ethylhexyl)((2-ethylhexylamino)methyl) phosphine oxide for cerium(Ⅳ) extraction and separation from sulfate medium[J].Journal of Rare Earths,2020,38(12):1330-1336. 被引量：3
10于凯,艾峥嵘,谢宏伟,刘吉利,宁志强.用P507从高浓度氯化钴溶液中萃取分离钴镍试验研究[J].湿法冶金,2020,39(6):502-506. 被引量：5

1Qing Zhao,Cheng-jun Liu,Bao-kuan Li,Mao-fa Jiang.Decomposition mechanism of chromite in sulfuric acid–dichromic acid solution[J].International Journal of Minerals,Metallurgy and Materials,2017,24(12):1361-1369. 被引量：2
2Dong Zhang,Zhiqi Zhao.Rock chemical weathering by sulfuric acid: pathway, method and prospect[J].Acta Geochimica,2017,36(3):474-478.
3李宁,熊睿,李发学,俞建勇,胡盼盼,刘兆峰.The Structure Development of Cellulose Dissolved in the Phosphoric Acid/Polyphosphoric Acid Solvent[J].Journal of Donghua University(English Edition),2011,28(5):485-487.
4Aaron Akah.Application of rare earths in fluid catalytic cracking： A review[J].Journal of Rare Earths,2017,35(10):941-956. 被引量：17
5孔德盟,黄跃武.Performance Optimization of a Phosphoric Acid Fuel Cell/Absorption Refrigerator Hybrid System[J].Journal of Donghua University(English Edition),2017,34(5):683-688.
6Ping Xue,Guang-qiang Li,Yong-xiang Yang,Qin-wei Qin,Ming-xing Wei.Recovery of valuable metals from waste diamond cutters through ammonia–ammonium sulfate leaching[J].International Journal of Minerals,Metallurgy and Materials,2017,24(12):1352-1360. 被引量：1
7Haoxin Liu,Baiwen Zhao,Yusheng Chen,Chengdun Ren,Yaoqiang Chen.Rare earths (Ce, Y, Pr) modified Pd/La2O3-ZrO2-Al2O3 catalysts usedin lean-burn natural gas fueled vehicles[J].Journal of Rare Earths,2017,35(11):1077-1082. 被引量：6
8Jinyu wang,Xiaowei Huang,Dali Cui,Liangshi Wang,Zongyu Feng,Bin Hu,Zhiqi Long,Na Zhao.Recovery of rare earths and aluminum from FCC waste slag by acid leaching and selective precipitation[J].Journal of Rare Earths,2017,35(11):1141-1148. 被引量：4
9Honghua Zhang,Ruixia Liu,Ruirui Zhang,Feng Huo,Zhiqiang Yang,Bin He,Suojiang Zhang,Yanji Wang.Stability,acidity and interaction properties of [Bmim][SbF_6] coupled with concentrated sulfuric acid[J].Science China Chemistry,2017,60(9):1243-1249. 被引量：2
10Wei-ping Liu,Xia-fei Yin.Recovery of copper from copper slag using a microbial fuel cell and characterization of its electrogenesis[J].International Journal of Minerals,Metallurgy and Materials,2017,24(6):621-626. 被引量：6

Rare Metals

2017年第10期

浏览历史

内容加载中请稍等...