Manganese and ammonia nitrogen recovery from electrolytic manganese residue by electric field enhanced leaching

Tian Yang; Shu Jiancheng; Chen Mengjun; Wang Jianyi; Wang Yao; Luo Zhenggang; Wang Rui; Yang Feihua; Xiu Furong; Sun Zhi

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Manganese and ammonia nitrogen recovery from electrolytic manganese residue by electric field enhanced leaching

机译：电场增强浸出法从电解锰残渣中回收锰和氨氮

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Electrolytic manganese residue (EMR) is a solid waste generated in filters after sulfuric acid leaching of manganese carbonate ore, which contains manganese, ammonia nitrogen and heavy metals that cause damage to environment. In fact, leaching and recovery of manganese and ammonia nitrogen from EMR is the key to the harmless treatment and resource utilization of EMR. In this study, electric field was applied to leach manganese and ammonia nitrogen from EMR. In addition, carbonate precipitation and struvite precipitation methods were used to recover manganese and ammonia nitrogen from leaching solution. The results showed that the leaching efficiencies of manganese and ammonia nitrogen were 88.07% and 91.50%, respectively, when the current density was 35 mA/cm(2), the mass of H2SO4 and H2O2 were 9.15 wt % and 3.33 wt%, solid-liquid ratio was 1:5 at temperature of 40 degrees C leached for 120 min. All heavy metals content in leached EMR except Ni and Cd were below national standard (GB 15618-2018) by electric field enhanced leaching. Meanwhile, manganese and ammonia nitrogen in leaching solution were fractional recovered by MnCO3 and struvite, and the recovery efficiency of manganese and ammonia nitrogen was 98.6% and 98.0%, respectively. This study provides a direction for the effective harmless treatment and resource utilization of EMR. (C) 2019 Elsevier Ltd. All rights reserved.

机译：电解锰残留物（EMR）是在硫酸浸出碳酸锰矿石后，过滤器中产生的固体废物，其中含有锰，氨氮和重金属，会对环境造成破坏。实际上，从EMR中浸出和回收锰和氨氮是EMR无害化处理和资源利用的关键。在这项研究中，电场被应用于从EMR中浸出锰和氨氮。此外，碳酸盐沉淀法和鸟粪石沉淀法被用于从浸出液中回收锰和氨氮。结果表明，当电流密度为35 mA / cm（2）时，H2SO4和H2O2的质量分别为9.15 wt％和3.33 wt％（固体），锰和氨氮的浸出效率分别为88.07％和91.50％。 -在40℃的温度下120分钟浸出液比为1：5。通过电场增强浸出，除Ni和Cd外，浸出EMR中的所有重金属含量均低于国家标准（GB 15618-2018）。同时，通过MnCO3和鸟粪石对浸出液中的锰和氨氮进行分馏，锰和氨氮的回收率分别为98.6％和98.0％。该研究为EMR的有效无害化处理和资源利用提供了指导。（C）2019 Elsevier Ltd.保留所有权利。

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来源
《Journal of Cleaner Production》 |2019年第1期|117708.1-117708.8|共8页
作者
Tian Yang; Shu Jiancheng; Chen Mengjun; Wang Jianyi; Wang Yao; Luo Zhenggang; Wang Rui; Yang Feihua; Xiu Furong; Sun Zhi;
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作者单位

Southwest Univ Sci & Technol Key Lab Solid Waste Treatment & Resource Recycle Minist Educ Mianyang 621010 Sichuan Peoples R China;

Guizhou Inst Bldg Mat Sci Res & Design Ltd Co Guiyang 550007 Guizhou Peoples R China;

Guizhou Bldg Mat Qual Supervis Testing Ctr Guiyang 550000 Guizhou Peoples R China;

State Key Lab Solid Waste Reuse Bldg Mat Beijing 100041 Peoples R China;

Xian Univ Sci & Technol Coll Geol & Environm Xian 710054 Shaanxi Peoples R China;

Chinese Acad Sci Inst Proc Engn Beijing 100190 Peoples R China;

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正文语种 eng
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关键词
Electrolytic manganese residue; Manganese; Ammonia nitrogen; Electric field; MnCO3 and struvite;

机译：电解锰残留物;锰;氨氮电场;MnCO3和鸟粪石;

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1. Manganese and ammonia nitrogen recovery from electrolytic manganese residue by electric field enhanced leaching [J] . Tian Yang, Shu Jiancheng, Chen Mengjun, Journal of Cleaner Production . 2019,第NOVa1期

机译：电场增强浸出法从电解锰残渣中回收锰和氨氮
2. Enhanced electrokinetic remediation of manganese and ammonia nitrogen from electrolytic manganese residue using pulsed electric field in different enhancement agents [J] . Shu Jiancheng, Sun Xiaolong, Liu Renlong, Ecotoxicology and Environmental Safety . 2019,第APRa期

机译：在不同增强剂中使用脉冲电场增强了对电解锰残渣中锰和氨氮的电动修复
3. Enhanced electrokinetic remediation of manganese and ammonia nitrogen from electrolytic manganese residue using pulsed electric field in different enhancement agents [J] . Shu Jiancheng, Sun Xiaolong, Liu Renlong, Ecotoxicology and Environmental Safety . 2019,第Apra期

机译：使用不同增强剂中的脉冲电场从电解锰残留中增强锰和氨氮的电动修复
4. Recovery of Manganese by Roasting-Ammonia Leaching from Low-Grade Manganese Carbonate Ores [C] . Zhongbing Tu, Xiaoping Liang, Xiangguan Yang, Symposium on Rare Metal Extraction and Processing . 2019

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5. Magnetism and electric field effects of epitaxial manganese arsenide and manganese(1-x) nickel(x) arsenic films on gallium arsenide(001) [D] . Shin, Taeho 1996

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6. Recovery and Separation of Vanadiumand Chromium by Two-Step Alkaline Leaching Enhanced with an ElectricField and H2O2 [O] . Hao Peng, Liu Yang, Ya Chen, 2020

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7. Roasting Pretreatment Combined with Ultrasonic Enhanced Leaching Lead from Electrolytic Manganese Anode Mud [O] . Huimin Xie, Shiwei Li, Libo Zhang, 2019

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8. Recovery of Manganese from Steel Plant Slag by Carbamate Leaching [R] . McIntosh, S. N., Baglin, E. G. 1992

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Manganese and ammonia nitrogen recovery from electrolytic manganese residue by electric field enhanced leaching

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