电解锰液综合平衡探讨

建立了电解锰液综合平衡方程，研究分析了电解锰液综合平衡中各因素关系及对水解、电极电位的影响，并结合实践总结出电解控制参数。

新型压滤洗涤设备在电解金属锰制液过程的工程应用

新型压滤洗涤设备具备固液分离、原位分级加压循环洗涤、浸渣加气吹饼脱水及智能控制洗涤水消耗量等功能,可用于电解金属锰制液工序回收锰渣中可溶性锰和硫酸铵。采用新型压滤洗涤设备对电解金属锰渣进行了洗涤回收的工程应用研究,结果表明:洗涤1次总耗时72 min,洗涤前锰渣中可溶锰为2.29%,水洗锰渣中可溶锰为1.42%,通过1次洗涤,锰渣中可溶锰下降0.87%,可溶性锰洗涤回收率为37.85%,锰渣中硫酸铵洗涤回收率为55.96%;逆流洗涤2次总耗时为97 min,洗涤前锰渣中可溶性锰为1.97%,洗涤后锰渣中可溶性锰为0.85%,通过2次逆流洗涤,锰渣中可溶性锰下降1.12%,可溶性锰洗涤回收率为57.89%,锰渣中硫酸铵洗涤回收率为78.64%,洗涤回收效果显著。利用新型压滤设备洗涤回收锰渣中锰和硫酸铵,按锰渣质量30%的水量洗涤,每生产1 t电解金属锰,从锰渣中回收溶液的价值约443.49元,具有一定的经济效益。

铁粉还原脱除电解锰阳极液中的硒

采用铁粉还原脱除电解锰阳极液中的硒,考察了各主要因素对硒脱除率的影响,研究了硒脱除过程的动力学。结果表明,锰阳极液中硒的脱除速率随反应时间、铁粉用量、反应温度的增加而增加,随硫酸用量的增加而减少。XRD与SEM分析表明,反应温度对硒渣结构影响最大,30℃反应后渣中存在Se、Fe、Fe Se2、Fe2(Se O4)3 4种物相,硒的结晶形态以纺锤形为主;90℃反应后渣中存在Se、Fe Se2两种形式,硒的结晶形态以球形为主。铁粉还原脱除锰阳极液中硒的动力学过程符合一级反应速率规律,属固体产物层扩散控制,表观活化能为15.94k J·mol-1。

铁碳微电解法从电解锰阳极液中提取硒试验研究

研究了采用铁碳微电解法从电解锰阳极液中提取硒,考察了搅拌速度、反应时间、反应温度、铁碳总质量浓度和铁碳质量比对硒提取率和铁溶出率的影响,分析对比了反应前后铁屑表面特征。结果表明:硒提取率随搅拌速度、反应时间、铁碳总质量浓度增大而提高,而受反应温度的影响较小;在铁碳质量比为2∶1时,硒提取效果较好;铁溶出率随反应时间延长和反应温度升高而提高,受搅拌速度和铁碳质量比的影响不明显;在搅拌速度200r/min、反应时间3h、反应温度30℃、铁碳总质量浓度3.0g/L、铁碳质量比2∶1条件下,硒提取率达96.52%。

用亚硫酸铵从电解锰阳极液中还原回收硒

研究了以亚硫酸铵为还原剂从电解锰阳极液中还原回收硒,考察了硫酸浓度、反应温度、反应时间和亚硫酸铵用量对硒还原率的影响。结果表明:在硫酸浓度0.33 mol/L、反应温度90℃、反应时间120 min、亚硫酸铵用量0.8 g/L条件下,模拟与实际电解锰阳极液中的硒还原率分别达95%和93%,还原效果较好。

响应面法优化从电解锰阳极液中回收硒工艺

采用响应面设计优化铁炭微电解法回收电解锰阳极液中硒的工艺条件,研究搅拌速率、铁炭比和反应时间对硒回收率的影响。结果表明,各因素对硒回收率的影响大小顺序为:搅拌速率>铁炭比>反应时间,三者之间两两的交互作用均较弱。最优工艺条件为:搅拌速率199r/min、铁炭比1.94g/g、反应时间192min。在此条件下,硒的回收率可达到96.34%,与模型预测值96.52%无显著差异。

用电解锰阳极液制备电池级硫酸锰

研究了采用一种新型萃取剂A从电解锰阳极液中通过溶剂萃取获得制备电池级硫酸锰的高纯溶液,考察了振荡时间、水相pH、萃取剂浓度、有机相皂化率、相比Vo/Va、硫酸铵浓度对萃取的影响,以及相比Vo/Va和酸度对反萃取的影响。结果表明:在Vo/Va=1.5/1、萃取剂体积分数30%、有机相皂化率30%、水相pH=4.6、25℃条件下萃取15 min,锰萃取率为77.9%,镁萃取率为13.7%;用1 mol/L硫酸溶液,在相比Vo/Va=6/1条件下反萃取负载有机相,得到平均锰质量浓度53 g/L、酸度较低的反萃取液;用此反萃取液制得的硫酸锰产品中锰质量分数大于32%,镁质量分数低于1.5×10^(-5),符合化工行业《电池用硫酸锰》一等品要求。

用P507-Cyanex272协萃体系从电解锰合格液中萃取分离锰镁钙

研究了采用P507-Cyanex272协萃体系从电解锰合格液中萃取分离锰镁钙,考察了水相pH、有机相皂化率、萃取相比、萃取剂体积分数、萃取温度、混合时间及Cyanex272添加量对锰、镁、钙离子萃取率的影响,并对负载有机相进行洗涤、反萃取分离去除钙镁杂质。结果表明:在水相pH=4.5、有机相皂化率50%、萃取相比V o/V a=2.5/1、萃取剂体积分数30%、萃取温度35℃、混合时间5 min、Cyanex272占比60%条件下,锰、镁、钙萃取率分别为64.28%、15.77%和16.24%;负载有机相分别用0.03 mol/L稀硫酸溶液和30 g/L硫酸锰溶液进行两段洗涤,再以1 mol/L硫酸反萃取,反萃取液中锰、镁离子质量浓度分别为52.57 g/L和0.27 g/L,反萃取液再经高纯碳酸锰中和—协同萃取—反萃取,可满足电池级硫酸锰生产要求。

氧化锰矿浆脱除电解锰渣煅烧烟气二氧化硫工艺研究

传统的石灰石-石膏法烟气脱硫不仅运行并成本高还会产生大量的二次污染物,而氧化锰矿湿法脱硫不仅能够脱除烟气中SO2,而且同时实现矿粉中锰的浸出生成硫酸锰。结合电解锰企业生产特点,提出以氧化锰矿和电解阳极液配浆直接脱除电解锰渣煅烧烟气二氧化硫的新工艺,研究了不同工艺参数对脱硫浸锰的影响。模拟电解阳极液与氧化锰矿浆的脱硫浸锰工艺实验表明,随着脱硫时间的增加,烟气中SO2越高,脱硫率越低,锰浸出率增加,故应采用多级逆流方式实现高效脱硫和深度浸锰的目标。脱硫率随着氧化锰粒径的减小而增高,用于脱硫的锰矿粒径应小于120 目。烟气脱硫操作温度控制在50~80 ℃,液固比宜选取9∶1~6∶1。处理装置的进气流量对脱硫浸锰的效率具有较佳值,本实验装置选择2.0 m^3/min。采用模拟电解阳极液对7%的模拟煅烧烟气进行的5级氧化锰浆脱硫实验表明,在液固比为9∶1,锰矿粒径为200 目,温度50 ℃前4级脱硫时间20 min,第5级100 min下,SO2出口浓度为111.4 mg/m^3,锰矿浸出率为93.12%,浆液中Mn^2+浓度为46.26 mg/L,连二硫酸锰浓度为4.0 g/L。本文以氧化锰矿为脱硫原料,电解阳极液配浆来直接脱硫的新工艺,集脱硫浸锰为一体,与传统的硫资源利用方式相比,投资和运行成本显著降低,具有较好的应用前景。

Deep removal of copper from nickel electrolyte using manganese sulfide

Copper is difficult to separate from nickel electrolyte due to low concentration of copper (0.53 g/L) with high concentration of nickel (75 g/L). Manganese sulfide (MnS) was used to deeply remove copper from the electrolyte. Experimental results show that the concentration of copper (ρ(Cu)) decreases from 530 to 3 mg/L and the mass ratio of copper to nickel (RCu/Ni) in the residue reaches above 15 when the MnS dosage is 1.4 times the theoretical valueDt,MnS (Dt,MnS=0.74 g) and the pH value of electrolyte is 4?5 with reaction time more than 60 min at temperatures above 60 °C. The concentration of newly generated Mn2+(ρ(Mn)) in the solution is also reduced to 3 mg/L by the oxidation reaction. The values ofρ(Cu),ρ(Mn)andRCu/Ni meet the requirements of copper removal from the electrolyte. It is shown that MnS can be considered a highly effective decoppering reagent.

Cooperative removal of Mn^(2+),NH_(4)^(+)-N,PO_(4)^(3-)-P and F−from electrolytic manganese residue leachate and phosphogypsum leachate

Electrolytic manganese residue leachate(EMRL)contains plenty of Mn^(2+) and NH_(4)^(+)-N,and phosphogypsum leachate(PGL)contains large amounts of PO_(4)^(3-)-P and F^(-).Traditional methods of EMRL and PGL discharge could seriously damage the ecological environment.In this study,an innovative method for cooperative removal Mn^(2+),NH_(4)^(+)-N,PO_(4)^(3-)-P,F^(-)from PG and POFT was studied.The result showed that Mn^(2+),PO_(4)^(3-)-P and F^(-)were mainly removed in forms of Mg_(3)Si_(4)O_(10)(OH)_(2),Mn_(3)O_(4),Mn_(3)(PO_(4))_(2),Mg_(3)(PO_(4))_(2),CaSO_(4)·2H_(2)O,MnF_(2),MnOOH and Ca_(2)P_(2)O_(7)·2H_(2)O,when LG-MgO was used to adjust the pH value of the system to 9.5,and the volume ratio of EMRL and PGL was 1:4,as well as reaction for 1 h at 25℃.NH_(4)^(+)-N was mainly removed by struvite precipitate,when the molar ratio of N:Mg:P was 1:3:2.4.The concentrations of Mn^(2+),NH_(4)^(+)-N and F^(-)were lower than the integrated wastewater discharge standard.The concentration of PO_(4)^(3-)-P decreased from 254.20 mg/L to 3.21 mg/L.This study provided a new method for EMRL and PGL cooperative harmless treatment.

Application of a novel redox-active electrolyte in MnO_2-based supercapacitors

This paper reports a novel strategy for preparing redox-active electrolyte through introducing a redox-mediator(p-phenylenediamine,PPD) into KOH electrolyte for the application of ball-milled MnO 2-based supercapacitors.The morphology and compositions of ball-milled MnO 2 were characterized using scanning electron microscopy(SEM) and X-ray diffraction(XRD).The electrochemical properties of the supercapacitor were evaluated by cyclic voltammetry(CV),galvanostatic charge-discharge(GCD),and electrochemical impedance spectroscopy(EIS) techniques.The introduction of p-phenylenediamine significantly improves the performance of the supercapacitor.The electrode specific capacitance of the supercapacitor is 325.24 F g-1,increased by 6.25 folds compared with that of the unmodified system(44.87 F g-1) at the same current density,and the energy density has nearly a 10-fold increase,reaching 10.12 Wh Kg-1.In addition,the supercapacitor exhibits good cycle-life stability.