MIBK萃取法从铌液中除锑制取高纯氧化铌的实验研究

利用MIBK在一定酸度条件下对Sb(Ⅲ)和Sb(Ⅴ)具有不同的萃取性能的特性,采用HF-H2SO4-MIBK萃取体系,控制一定酸度并将Sb(Ⅲ)氧化为Sb(Ⅴ),最大限度地满足萃取分离Sb的要求,即可达到制取高纯氧化铌(Sb含量<10×10^(-6))的目的。

铌液中和沉淀时氨流量自动化控制关键技术的研究

五氧化二铌生产制取过程中影响其物性的因素主要有铌液的浓度、沉淀方式及焙烧过程,其中较关键是铌液沉淀过程的控制,而沉淀过程关键因素是实现对氨注入的控制。本文研究了铌液沉淀过程中氨流量自动化控制关键技术,实现了较精确控制氨沉淀过程流量大小及关键PH值节点控制。

含铌铁液氧化脱磷保铌热力学分析

通过计算含铌铁液在1 573 K、铌含量为0.027%、0.013%、0.006%的氧活度,比较含铌铁液脱硅、脱磷及脱锰终点的氧活度的大小,确定含铌铁液脱磷过程中,铌、锰、硅含量的变化。结果表明:保持含铌铁液氧活度是9.471×10-5时,铁液中的锰基本不变化,硅可全部脱除,铌含量显著减少到0.013%。氧化钡脱磷效果优于氧化钙脱磷效果。

脱硫剂对含铌铁液脱硫效果的影响

应用镁、钙基脱硫剂在真空碳管炉内进行含铌铁液脱硫实验,分析对比了不同脱硫剂的脱硫效果,并用Factsage软件进行脱硫热力学计算。结果表明:通过热力学计算镁的脱硫率高于Ca-Si合金、Al-Ca合金和50%CaO-30%Al_2O_3-20%MgO的脱硫率;实验表明了镁中加入CaO能显著提高镁的脱硫效果,Mg+CaO和铝钙脱硫时在铁液中形成形态不同的夹杂物。

从钽铌萃余液中萃取回收钨的试验研究

钽铌精矿经硫酸－氢氟酸分解，萃取法提取钽铌后，残液中含有ＷＯ＿３２０－５０ｇ／Ｌ，研究了Ｎ＿（２３５）－仲辛醇－煤油体系萃取回收钨，采用氨水反萃取。通过一系列条件试验，及扩大试验验证，钽铌萃余液中钨是可以回收的，并可制成合格的仲钨酸铵产品。

镁粉还原-仲辛醇萃取法从钽铌矿分解液中除Sb的实验研究

从Sb的价态着手,研究了仲辛醇对Sb(Ⅲ)和Sb(Ⅴ)萃取性能的差异,证实在相同的萃取条件下,Sb(Ⅴ)更容易被仲辛醇萃取。在此基础上,采用一定量的镁粉还原钽铌矿分解液中Sb,使高价态Sb转化成低价态Sb,以达到Sb与Ta/Nb分离的目的。实验结果表明,为使Nb2O5产品中Sb含量低于20×10-6,还原条件应采用镁粉用量10g/L、反应5h。

甘肃省交勒萨依铌钽矿矿体特征及找矿标志

甘肃省阿克塞哈萨克族自治县交勒萨依铌钽矿侵入岩发育,燕山期花岗伟晶岩脉是主要的含矿岩性。通过对矿体地质特征的研究,初步分析了找矿标志及找矿方向。

降低Nb_2O_5中氟含量的研究

对原有的沉淀、压洗工艺制取Nb(OH)5进行了改进研究,并对煅烧Nb(OH)5设备进行了对比,结果表明:对高浓度铌液(Nb2O5>120g/L),采用加稀释剂预处理方法,可以解决高浓度铌液沉淀得到的Nb(OH)5洗涤除氟难的问题。研究得出的提高洗水温度、增加调浆次数的新压洗工艺,提高了除氟效率、产品Nb2O5的合格率,并节约了用水。对比试验表明,用回转管电炉煅烧比用台车式电炉煅烧的除氟效果好。

Nb_2O_5粒度的工艺控制研究

采用分步沉淀法将铌液沉淀生成Nb（OH）_5,经洗涤、烘干、煅烧获得Nb_2O_5产品,研究了Nb_2O_5粒度的工艺控制条件。结果表明,在料液中先通入0.1MPa的氨气,中和料液pH值至4,自然冷却16h后快速通入0.3MPa氨气直至反应完成（沉淀终点料液pH控制为9）,产物经洗净、240℃烘干6h、860℃煅烧后,即可得到平均粒径（D50）为1~5μm的Nb_2O_5产品。当铌液的浓度增大到一定范围时,最终煅烧出的Nb_2O_5平均粒径增大;煅烧炉温升高,煅烧出的Nb_2O_5平均粒径也增大。

含铌钢液使用CaC_2还原脱磷的试验研究

利用CaC2-CaF2对含铌钢液在碳管炉中进行了还原脱磷试验，钢液的碳含量wC=0．5％～1．9％，温度为1550℃。研究了脱磷剂加入方式和加入量、铁水的含碳量、坩埚材质对脱磷率的影响。为了获得好的动力学条件，根据CaC2分解的特点，采用了将脱磷剂装入钢管后，喂入钢液进行还原脱磷反应的方法。试验结果表明：钢液wC=0．5％时，脱磷剂喂入法最终脱磷率为41％；钢液wC=1．9％时，脱磷剂喂入法最终脱磷率为25％，随着钢液含碳量的升高，脱磷率逐渐降低；脱磷剂采用顶加法时脱磷率均在10％以内，脱磷剂采用喂入法时脱磷效果远优于顶加法的脱磷效果；刚玉坩埚易受CaC2侵蚀，不适宜用于CaC2还原脱磷。MgO坩埚是进行还原脱磷反应的理想容器；在脱磷过程中合金元素铌不发生变化。

Effect of extrusion ratios on hardness,microstructure,and crystal texture anisotropy in pure niobium tubes subjected to hydrostatic extrusion

Nb tubes were fabricated through hydrostatic extrusion at extrusion ratios of 3.1 and 6.1 at ambient temperature,and then their microstructure,texture,and Vickers hardness were investigated based on electron back-scattered diffraction(EBSD)data.The fraction of low-angle boundaries(LABs)largely decreased with a sharp decrease in mean grain sizes after hydrostatic extrusion and was not proportional to extrusion ratios,assuming that mixed-asymmetrical junctions forming LABs dissociate at high extrusion ratios from the external stress(>981 MPa)with thermal activation by the generated heat.The correlation between grain size and Vickers hardness followed the Hall−Petch relationship despite the texture gradient of theá111ñcyclic fiber textural microstructure at low extrusion ratios and theá100ñtrue fiber textural microstructure at high extrusion ratios.The increase in hydrostatic pressure on the Nb tubes contributed to texture evolution in terms of extrusion ratios due to the difference between{110}<111>and{112}<111>components based on EBSD data.

“Water in salt/ionic liquid”electrolyte for 2.8 V aqueous lithium-ion capacitor

Development of high-voltage electrolytes with non-flammability is significantly important for future energy storage devices.Aqueous electrolytes are inherently non-flammable,easy to handle,and their electrochemical stability windows(ESWs)can be considerably expanded by increasing electrolyte concentrations.However,further breakthroughs of their ESWs encounter bottlenecks because of the limited salt solubility,leading to that most of the high-energy anode materials can hardly function reversibly in aqueous electrolytes.Here,by introducing a non-flammable ionic liquid as co-solvent in a lithium salt/water system,we develop a"water in salt/ionic liquid"(WiSIL)electrolyte with extremely low water content.In such WiSIL electrolyte,commercial niobium pentoxide(Nb2O5)material can operate at a low potential(-1.6 V versus Ag/AgCl)and contribute its full capacity.Consequently,the resultant Nb2O5-based aqueous lithium-ion capacitor is able to operate at a high voltage of 2.8 V along with long cycling stability over 3000 cycles,and displays comparable energy and power performance(51.9 Wh kg^-1 at 0.37 kW kg^-1 and 16.4 Wh kg^-1 at 4.9 kW kg^-1)to those using non-aqueous electrolytes but with improved safety performance and manufacturing efficiency.