涉锑废物流及锑回收途径现状概述
收稿日期: 2023-12-27
网络出版日期: 2024-02-18
基金资助
苏州市科技计划项目(SS202107);江苏省研究生科研与实践创新计划项目(SJCX21_1403)
Summary of antimony residues and status in antimony recovery technology
Received date: 2023-12-27
Online published: 2024-02-18
锑作为一种战略性资源,广泛应用于铅酸蓄电池、塑料阻燃剂、催化剂等工业产品和半导体、红外探测器等领域。中国是世界上最大的锑供应国和消费国,然而随着锑需求的日益增大,锑将逐渐成为最稀缺的金属之一,锑的回收受到广泛关注。从锑的生命周期入手,覆盖从锑矿冶金生产、涉锑产品加工生产利用及含锑废弃物处置等环节,对不同工业环境中锑的去向进行梳理,二次锑生产大部分来自冶金工业残留物及报废的含锑铅酸电池,对冶金工业锑残留物和报废产品中锑的回收技术进行总结和难点分析,含锑产品中锑含量较低、材料混合复杂成为制约含锑报废品回收的主要原因,总结锑生产应用过程中涉及的土壤、空气和水环境污染情况及污染治理回收现状,环境污染治理中锑主要被视为污染源而非资源二次利用的来源,或需开发更多富集、回收的技术来推进研究。
刘矜彤 , 张洁 , 周俊良 , 吴兵党 , 黄天寅 , 杨晶晶 . 涉锑废物流及锑回收途径现状概述[J]. 无机盐工业, 2024 , 56(9) : 1 -11 . DOI: 10.19964/j.issn.1006-4990.2023-0621
Antimony,a strategic resource,is extensively utilized in a multitude of industrial products including lead-acid batteries,plastic flame retardants,catalysts,semiconductors,and infrared detectors.China stands as the largest producer and consumer of antimony worldwide.However,with the escalating demand for antimony,this metal is anticipated to gradually transition into one of the most scarce metals.Consequently,there has been a surge in attention towards the recycling of antimony.The destination of antimony in different industrial environments was delved into the life cycle of antimony,encompassing the metallurgical production of antimony ore,the processing,production,and utilization of antimony-related products,as well as the disposal of antimony-containing wastes.Notably,secondary antimony production predominantly emanated from metallurgical industry residues and discarded antimony-containing lead-acid batteries.The difficulties in the recovery technology of antimony residues and scrap products in the metallurgical industry were summarized and analyzed.The low antimony content and complex material mixing in antimony containing products were the main reasons that restrict the recovery of antimony containing waste products.The soil,air,and water environmental pollution involved in the production and application of antimony,as well as the current status of pollution control and recovery were summarized.In environmental pollution control,antimony was mainly regarded as a source of pollution rather than a source of secondary resource utilization.Consequently,there was a pressing need for more sophisticated enrichment and recovery technologies to stimulate further research.
| 1 | DENG Songyun, REN Bozhi, HOU Baolin,et al.Antimony-complexed heavy metal wastewater in antimony mining areas:Source,risk and treatment[J].Environmental Technology and Innovation,2023,32:103355. |
| 2 | PERIFERAKIS A, CARUNTU A, PERIFERAKIS A T,et al.Availability,toxicology and medical significance of antimony[J].International Journal of Environmental Research and Public Health,2022,19(8):4669. |
| 3 | FU Zhiping, ZHANG Guoping, LI Haixia,et al.Influence of reducing conditions on the release of antimony and arsenic from a tailings sediment[J].Journal of Soils and Sediments,2016,16(10):2471-2481. |
| 4 | KLOCHKO K.Antimony[R].Reston:U.S.Geological Survey,2022. |
| 5 | ZHAO Guimei, LI Wenxiu, GENG Yong,et al.Dynamic material flow analysis of antimony resources in China[J].Resources Policy,2023,86:104154. |
| 6 | VAN DEN BRINK S, KLEIJN R, SPRECHER B,et al.Resilience in the antimony supply chain[J].Resources,Conservation and Recycling,2022,186:106586. |
| 7 | DAIGKE B, DECARLO S.Antimony:A critical material you′ve probably never heard of[R].New York:U.S.International Trade Commission,2021. |
| 8 | 中华人民共和国国家发展和改革委员会.全国矿产资源规划(2016—2020年)[EB/OL].(2017-5-11)[2023-12-28].https://www.ndrc.gov.cn/fggz/fzzlgh/gjjzxgh/201705/t20170511_1196755.html. |
| 9 | WANG Ke, WANG Qinmeng, CHEN Yuanlin,et al.Antimony and arsenic substance flow analysis in antimony pyrometallurgical process[J].Transactions of Nonferrous Metals Society of China,2023,33(7):2216-2230. |
| 10 | ARACENA A, VéLIZ M, JEREZ O,et al.An overview of the behavior of concentrates with arsenic,antimony,and bismuth under roasting conditions[J].Minerals,2023,13(7):942. |
| 11 | LI Lei, XU Miao, XIAO Yang.Preparation of elemental As from As-Sb fly ash using continuous reductive method with additive of lead oxide[J].Journal of Central South University,2022,29(9):3003-3015. |
| 12 | 卢红杏.提高锑还原熔炼及精炼过程直收率的措施[J].四川有色金属,2012(1):56-58,66. |
| LU Hongxing.Measures of improving direct recovery of antimony smelting and refining process[J].Sichuan Nonferrous Metals,2012(1):56-58,66. | |
| 13 | YE Longgang, TANG Chaobo, LIU Heng,et al.Efficient bath-smelting reduction of antimony oxide in FeO-SiO2-CaO-Na2O quaternary slag with low melting point[J].JOM,2019,71(11):3903-3908. |
| 14 | CHE Jianyong, ZHANG Wenjuan, CHEN Yongqiang,et al.Progressive low-temperature volatilization control:Efficient separation of arsenic and antimony from smelter dust[J].The Science of the Total Environment,2024,912:169366. |
| 15 | ZHANG Yonglu, WANG Chengyan, MA Baozhong,et al.Extracting antimony from high arsenic and gold-containing stibnite ore using slurry electrolysis[J].Hydrometallurgy,2019,186:284-291. |
| 16 | DONG Zhaowang, ZHOU Zhentao, XIONG Heng,et al.Direct extracting lead sulfide and antimony trisulfide via a vacuum distillation method[J].Separation and Purification Technology,2021,279:119776. |
| 17 | TAN Cheng, LI Hongjuan, LI Jinyan,et al.Recovery of Sb and Fe from Sb-bearing slags through a reduction roasting process with low density polyethylene[J].ISIJ International,2019,59(11):2113-2119. |
| 18 | LI Yun, CHEN Yongming, XUE Haotian,et al.One-step extraction of antimony in low temperature from stibnite concentrate using iron oxide as sulfur-fixing agent[J].Metals,2016,6(7):153. |
| 19 | 唐谟堂,赵天从.三氯化锑水解体系的热力学研究[J].中南矿冶学院学报,1987,18(5):522-528,592-593. |
| TANG Motang, ZHAO Tiancong.Study on the thermodynamic in the systems of hydrolysis of antimony trichloride[J].Journal of Central South University(Science and Technology),1987,18(5):522-528,592-593. | |
| 20 | SOLOZHENKIN P M, ALEKSEEV A N.Innovative processing and hydrometallurgical treatment methods for complex antimony ores and concentrates.Part I[J].Journal of Mining Science,2010,46(2):203-209. |
| 21 | YANG Tianzu, JIANG Mingxi, LAI Qionglin,et al.Sodium sulfide leaching of low-grade jamesonite concentrate in production of sodium pyroantimoniate[J].Journal of Central South University of Technology,2005,12(3):290-294. |
| 22 | ZHANG Duchao, XIAO Qingkai, LIU Weifeng,et al.Pressure oxidation of sodium thioantimonite solution to prepare sodium pyroantimonate[J].Hydrometallurgy,2015,151:91-97. |
| 23 | WIKEDZI A, SANDSTR?M ?, AWE S A.Recovery of antimony compounds from alkaline sulphide leachates[J].International Journal of Mineral Processing,2016,152:26-35. |
| 24 | DEMBELE S, AKCIL A, PANDA S.Technological trends,emerging applications and metallurgical strategies in antimony recovery from stibnite[J].Minerals Engineering,2022,175:107304. |
| 25 | SAJJAD W, ZHENG Guodong, DIN G,et al.Metals extraction from sulfide ores with microorganisms:The bioleaching technology and recent developments[J].Transactions of the Indian Institute of Metals,2019,72(3):559-579. |
| 26 | HAFEEZ I, NASIR S, ZAHRA S,et al.Metal extraction process for high grade stibnite of kharan(Balochistan Pakistan)[J].Journal of Minerals and Materials Characterization and Engineering,2017,5(1):39-48. |
| 27 | PANDA S, AKCIL A, MISHRA S,et al.A novel bioreactor system for simultaneous mutli-metal leaching from industrial pyrite ash:Effect of agitation and sulphur dosage[J].Journal of Hazardous Materials,2018,342:454-463. |
| 28 | DUPONT D, ARNOUT S, JONES P T,et al.Antimony recovery from end-of-life products and industrial process residues:A critical review[J].Journal of Sustainable Metallurgy,2016,2(1):79-103. |
| 29 | SHU Yanxiang, CAO Huazhen, WU Liankui,et al.The comprehensive utilization of oxidative hydrochloric acid leaching of anode slime bearing fluorine,arsenic and antimony[J].Hydrometallurgy,2019,183:106-111. |
| 30 | ZHANG Huibin, LIU Xinli, JIANG Yao,et al.Direct separation of arsenic and antimony oxides by high-temperature filtration with porous FeAl intermetallic[J].Journal of Hazardous Materials,2017,338:364-371. |
| 31 | BINZ F, FRIEDRICH B.Recovery of antimony trioxide flame retardants from lead refining residues by slag conditioning and Fuming[J].Chemie Ingenieur Technik,2015,87(11):1569-1579. |
| 32 | LONG Hua, ZHENG Yajie, PENG Yinglin,et al.Recovery of alkali,selenium and arsenic from antimony smelting arsenic-alkali residue[J].Journal of Cleaner Production,2020,251:119673. |
| 33 | LING Hongbin, MALFLIET A, CHENG Zhongfu,et al.Antimony recovery from antimony-rich slag by top blowing nitrogen into the molten slag bath[J].Journal of Cleaner Production,2022,373:133766. |
| 34 | XUE Jianrong, LONG Dongping, ZHONG Hong,et al.Comprehensive recovery of arsenic and antimony from arsenic-rich copper smelter dust[J].Journal of Hazardous Materials,2021,413:125365. |
| 35 | LI Dong, GUO Xueyi, XU Zhipeng,et al.Leaching behavior of metals from copper anode slime using an alkali fusion-leaching process[J].Hydrometallurgy,2015,157:9-12. |
| 36 | MENG Ling, ZHANG Shengen, PAN Dean,et al.Antimony recovery from SbCl5 acid solution by hydrolysis and aging[J].Rare Metals,2015,34(6):436-439. |
| 37 | HAN Junwei, Zhenyu OU, LIU Wei,et al.Recovery of antimony and bismuth from tin anode slime after soda roasting-alkaline leaching[J].Separation and Purification Technology,2020,242:116789. |
| 38 | HERNáNDEZ-PéREZ L, CARRILLO-ABAD J, PéREZ-HERRANZ V,et al.Effluents from the copper electrorefining as a secondary source of antimony:Role of mass transfer on the recovery by electrodeposition[J].Desalination,2023,549:116322. |
| 39 | LIU Tiantian, QIU Keqiang.Removing antimony from waste lead storage batteries alloy by vacuum displacement reaction technology[J].Journal of Hazardous Materials,2018,347:334-340. |
| 40 | KOPARAL A S, ?ZGüR R, ??üTVEREN ü B,et al.Antimony removal from model acid solutions by electrodeposition[J].Separation and Purification Technology,2004,37(2):107-116. |
| 41 | LING Hongbin, BLANPAIN B, GUO Muxing,et al.Characterization of antimony-containing metallurgical residues for antimony recovery[J].Journal of Cleaner Production,2021,327:129491. |
| 42 | LI Kuo, XU Zhenming.Decomposition of high-impact polystyrene resin in e-waste by supercritical water oxidation process with debromination of decabromodiphenyl ethane and recovery of antimony trioxide simultaneously[J].Journal of Hazardous Materials,2021,402:123684. |
| 43 | 鲍玥.印染废水处理系统中锑的迁移转化规律及其处理工艺研究[D].杭州:浙江大学,2017. |
| BAO Yue.Study on Sb migration and transformation in dyeing wastewater treatment system and enhanced treatment technologies[D].Hangzhou:Zhejiang University,2017. | |
| 44 | ALASSALI A, ABIS M, FIORE S,et al.Classification of plastic waste originated from waste electric and electronic equipment based on the concentration of antimony[J].Journal of Hazardous Materials,2019,380:120874. |
| 45 | DOUGHERTY S J, GARSKA K J.Recovery of sodium andantimony values from spent ethylene glycol residues:US,4100253[P].1978-07-11. |
| 46 | ALASSALI A, PICUNO C, SAMARA H,et al.Antimony mining from PET bottles and e-waste plastic fractions[J].Sustainability,2019,11(15):4021. |
| 47 | FERNSCHILD G, RUDOLPH W, MASSONNE J.Process for the recovery of antimony pentachloride from used catalyst solutions:US,4005176[P].1977-06-29. |
| 48 | TANG Haiying, HASSAN M U, NAWAZ M,et al.A review on sources of soil antimony pollution and recent progress on remediation of antimony polluted soils[J].Ecotoxicology and Environmental Safety,2023,266:115583. |
| 49 | JIANG Shasha, DENG Xiaoyu, MA Liyuan,et al.Standardized framework for assessing soil quality at antimony smelting site by considering microbial-induced resilience and heavy metal contamination[J].Journal of Environmental Sciences,2025,148:306-320. |
| 50 | ZOU Hao, REN Bozhi.Analyzing topsoil heavy metal pollution sources and ecological risks around antimony mine waste sites by a joint methodology[J].Ecological Indicators,2023,154:110761. |
| 51 | 张桐,张展华,胡杰华,等.淋洗技术在土壤污染修复中的应用与挑战[J].环境化学,2022,41(11):3599-3612. |
| ZHANG Tong, ZHANG Zhanhua, HU Jiehua,et al.Application and challenge of washing technology in soil pollution remediati-on[J].Environmental Chemistry,2022,41(11):3599-3612. | |
| 52 | 王靖文,曹斐姝,唐万鹏,等.分步连续沉淀法对锑砷污染土壤淋洗废液的回收及净化[J].有色金属(冶炼部分),2023(8):159-166. |
| WANG Jingwen, CAO Feishu, TANG Wanpeng,et al.Recovery and purification of wasted washing solution from antimony and arsenic contaminated soil by stepwise continuous precipitation me-thod[J].Nonferrous Metals(Extractive Metallurgy),2023(8):159-166. | |
| 53 | LI Ling, LIAO Lu, FAN Yuhong,et al.Accumulation and transport of antimony and arsenic in terrestrial and aquatic plants in an antimony ore concentration area(south-west China)[J].Environmental Chemistry,2020,17(4):314. |
| 54 | JADHAO P R, AHMAD E, PANT K K,et al.Advancements in the field of electronic waste recycling:Critical assessment of chemical route for generation of energy and valuable products co-upled with metal recovery[J].Separation and Purification Technology,2022,289:120773. |
| 55 | LI Jiaokun, GU Tianyuan, LI Liangzhi,et al.Complete genome sequencing and comparative genomic analyses of Bacillus sp.S3,a novel hyper Sb(Ⅲ)-oxidizing bacterium[J].BMC Microbiology,2020,20(1):106. |
| 56 | NGUYEN T, LEE Man.A review on the separation of lithium ion from leach liquors of primary and secondary resources by solvent extraction with commercial extractants[J].Processes,2018,6(5):55. |
| 57 | SUN Lina, GUO Bin, Weiguang LYU,et al.Genomic and physiological characterization of an antimony and arsenite-oxidizing bacterium Roseomonas rhizosphaerae[J].Environmental Research,2020,191:110136. |
| 58 | FILELLA M, HENNEBERT P, OKKENHAUG G,et al.Occurrence and fate of antimony in plastics[J].Journal of Hazardous Materials,2020,390:121764. |
| 59 | LONI P C, WANG Weiqi, QIU Xuan,et al.Antimony precipitation and removal by antimony hyper resistant strain Achromobacter sp.25-M[J].Environmental Research,2024,245:118011. |
| 60 | YANG Kunlun, LI Cheng, WANG Xiaorui,et al.Structure and morphology control of amorphous Mn-doped Fe oxide composite using soft-templates for efficient Sb(Ⅴ) removal in textile wastewater:Mechanism of solid-liquid interface regulation and Sb(Ⅴ) adsorption[J].Chemical Engineering Journal,2023,454:140255. |
| 61 | REN Yifan, ZHENG Wentian, LI Shuo,et al.Atomic H*-mediated electrochemical removal of low concentration antimonite and recovery of antimony from water[J].Journal of Hazardous Materials,2023,445:130520. |
| 62 | HERNáNDEZ-PéREZ L, MU?OZ-PéREZ A, ORTEGA E M,et al.Increasing the sustainability of copper electrorefining:Selective electrodeposition of antimony in the presence of bismuth from highly concentrated hydrochloric acid effluents[J].Journal of Environmental Chemical Engineering,2024,12(2):112005. |
| 63 | HU Yunxuan, ZHANG Shuangyu, LUO Chenghui,et al.Enhanced removal of Sb(Ⅴ) from aqueous solutions using layered double hydroxide modified with sodium dodecyl sulfate[J].Journal of Environmental Chemical Engineering,2022,10(3):107776. |
| 64 | ARNOLD M, KANGAS P, M?KINEN A,et al.Mine water as a resource:Selective removal and recovery of trace antimony from mine-impacted water[J].Mine Water and the Environment,2019,38(2):431-446. |
| 65 | LIANG Jiaxing, HU Zenan, ZHANG Xinyue,et al.Recovery of antimony using biological waste and stepwise resourcization as catalysts for both polyesterification and transfer hydrogenati-on[J].Colloids and Surfaces A:Physicochemical and Engineering Aspects,2022,635:128119. |
| 66 | ZHANG Xinyue, GUO Rongxiu, GUO Ying,et al.Sustainable antimony management via porphyrin ligand-based MOFs:From enrichment of antimony from water to the utilization in SbO2-based aqueous batteries[J].Journal of Environmental Chemical Engineering,2023,11(6):111148. |
| 67 | WANG Yao, ZHANG Xinyue, JU Na,et al.High capacity adsorption of antimony in biomass-based composite and its consequential utilization as battery anode[J].Journal of Environmental Sciences(China),2023,126:211-221. |
/
| 〈 |
|
〉 |
