高铁赤泥钙化还原过程液相生成抑制机理

高铁赤泥中赋存大量铁资源难以回收利用,钙化还原—磨选方法可实现赤泥中铁、铝组分的高效分离。针对高铁赤泥钙化还原过程中易形成液相,导致物料熔化和设备黏结的问题,本文提出分段式钙化还原—磨选技术路线,研究不同温度制度下,高铁赤泥钙化还原产物的形态、金属化率、微观结构、金属铁晶粒的生长规律和相关磨选指标。结果表明:采用分段钙化还原焙烧,可在低温阶段完成铁氧化物还原至金属铁和钙铝化合物形成的反应过程,在高温阶段完成金属铁颗粒的聚集长大过程,将低熔点物形成和高温焙烧分离进行,抑制液相生成。采用第一段1 125℃焙烧30 min、第二段1 200℃焙烧40 min的分段焙烧制度,还原过程无明显液相生成,金属铁颗粒的平均粒度达到21.52μm。还原产物经磨选后,所获得的还原铁粉TFe质量分数和Fe回收率分别达到92.84%和78.68%。本文研究成果可为高铁赤泥的资源化利用提供理论依据。

提钒尾渣煤基回转窑法钙化还原脱钠研究

针对提钒尾渣中钠含量高,导致难以返回烧结-高炉流程进行回收利用的问题,提出基于煤基回转窑还原的提钒尾渣钙化还原脱钠技术路线,并在Φ1 m×10 m回转窑中试线进行半工业试验,主要研究了高温段还原温度、白灰配比、入窑吨球焦粉配比、高温还原时间对提钒尾渣脱钠的影响规律,同时对脱钠后球团性能和回转窑结窑情况进行分析。结果表明,在高温段温度为1100~1160℃,高温段时间为1.8~2 h,入窑吨球焦粉配比为800~1000 kg,白灰配比为32.5%~41%的条件下,提钒尾渣脱钠率可达到80%以上,吨球焦粉实际消耗量为359 kg。窑内结块物主要由提钒尾渣球团粉末和焦粉灰分粉末组成,结块物呈疏松多孔状,由细颗粒相互粘结构成,窑转动过程会自动掉落,无明显结窑现象。

含锌电炉粉尘钙化碳热还原焙烧实验

这是一篇冶金工程领域的论文。为强化含锌电炉粉尘中锌和铁资源的有效分离与回收,并降低碳还原剂消耗,提出以电炉粉尘制备高碱度炉料进行钙化碳热还原焙烧的思路和方法。采用热力学计算和实验研究相结合,分析电炉粉尘钙化碳热还原焙烧过程中主要物相转变规律,探究其钙化碳热还原反应行为和路径。结果表明,当碳氧摩尔比nc/no<0.6和温度低于1000℃时,ZnFe_(2)O_(4)还原生成Fe_(0.85-x)Zn_(x)O,抑制锌的还原和挥发。而添加CaO均能将ZnFe_(2)O_(4)和Fe_(0.85-x)Zn_(x)O钙化生成Ca_(2)Fe_(2)O_(5),Ca_(2)Fe_(2)O_(5)会被进一步还原。当温度低于1100℃及nc/no<1.0时,含锌电炉粉尘钙化碳热还原焙烧反应路径为:ZnFe_(2)O_(4)+CaO→Ca_(2)Fe_(2)O_(5)+ZnO→Ca_(2)Fe_(2)O_(5)+Zn(g)和Fe_(0.85-x)Zn_(x)O+CaO→Ca_(2)Fe_(2)O_(5)+ZnO+FeO→Ca_(2)Fe_(2)O_(5)+Fe+Zn(g)。这两种反应均能促进锌的释放。在nc/no为0.4~1.2,焙烧温度为1000~1100℃,CaO能促进锌的挥发,钙化碳热还原焙烧nc/no=1.0时的脱锌率与碳热还原焙烧nc/no=1.2时接近,均在90%左右。因此,钙化碳热还原焙烧可降低碳还原剂消耗,节约能耗。

铁酸锌钙化碳热还原的热力学行为

通过热力学计算和实验相结合,分析了含锌电炉粉尘中铁酸锌钙化碳热还原过程热力学行为,讨论还原温度和碳氧摩尔比对铁酸锌钙化碳热还原行为的影响。结果表明,与传统碳热还原相比,ZnFe_(2)O_(4)钙化碳热还原可在较低温度生成ZnO,并可在1100 K直接由ZnFe_(2)O_(4)得到部分单质Zn。当温度高于1221 K时,ZnFe_(2)O_(4)钙化还原出的单质Zn以及由ZnO还原的Zn均以锌蒸气形式挥发,并随着配碳量及温度的升高还原挥发增强。钙化碳热还原不仅降低ZnFe_(2)O_(4)消失的温度,而且降低其还原产出金属铁和锌的温度和碳耗。CaO可重构物相从而明显降低铁酸锌反应产出ZnO、Zn和Fe的温度点,使得ZnFe_(2)O_(4)提前反应完全。当温度为1270 K,碳氧摩尔比n(C)/n(O)=0.7时,ZnFe_(2)O_(4)中锌铁还原与分离效果较好,此时Zn以蒸气形式挥发,Fe以金属单质形式被还原出来。

Manganese extraction by reduction-acid leaching from low-grade manganese oxide ores using CaS as reductant

The extraction of manganese from low-grade manganese oxide ores using Ca S derived from Ca SO4 as reductant was investigated. The effects of mass ratio of Ca S to ore, reduction temperature, reduction time, liquid to solid ratio（L/S ratio）, stirring speed, leaching temperature, leaching time and H2SO4 concentration on the leaching rates of Mn and Fe during the reduction–acid leaching process were discussed. The leaching rates of 96.47% for Mn and 19.24% for Fe were obtained under the optimized conditions of mass ratio of Ca S to manganese oxide ore 1：6.7, L/S ratio 5：1, stirring speed 300 r/min, reduction temperature of 95 °C for 2.0 h in the reduction process and leaching stirring speed of 200 r/min, H2SO4 concentration of 1.5 mol/L, leaching temperature of 80 °C for 5 min in the leaching process. In addition, this process can be employed in the recovery of manganese from various manganese oxide ores, and Mn leaching rate above 95% is obtained.

Effect of calcium compounds on direct reduction and phosphorus removal of high-phosphorus iron ore

The increasing demand for iron ore in the world causes the continuous exhaustion of magnetite resources.The utilization of high-phosphorus iron ore becomes the focus.With calcium carbonate(CaCO_(3)),calcium chloride(CaCl_(2)),or calcium sulfate(CaSO_(4))as additive,the process of direct reduction and phosphorus removal of high-phosphorus iron ore(phosphorus mainly occurred in the form of Fe_(3)PO_(7) and apatite)was studied by using the technique of direct reductiongrinding-magnetic separation.The mechanism of calcium compounds to reduce phosphorus was investigated from thermodynamics,iron metallization degree,mineral composition and microstructure.Results showed that Fe_(3)PO_(7) was reduced to elemental phosphorus without calcium compounds.The iron-phosphorus alloy was generated by react of metallic iron and phosphorus,resulting in high phosphorus in reduced iron products.CaCO_(3) promoted the reduction of hematite and magnetite,and improved iron metallization degree,but inhibited the growth of metallic iron particles.CaCl_(2) strengthened the growth of iron particles.However,the recovery of iron was reduced due to the formation of volatile FeCl_(2).CaSO_(4) promoted the growth of iron particles,but the recovery of iron was drastically reduced due to the formation of non-magnetic FeS.CaCO_(3),CaCl_(2) or CaSO_(4) could react with Fe_(3)PO_(7) to form calcium phosphate(Ca_(3)(PO_(4))_(2)).With the addition of CaCO_(3),Ca_(3)(PO_(4))_(2) was closely combined with fine iron particles.It is difficult to separate iron and phosphorus by grinding and magnetic separation,resulting in the reduced iron product phosphorus content of 0.18%.In the presence of CaCl_(2) or CaSO_(4),the boundary between the generated Ca_(3)(PO_(4))_(2) and the metallic iron particles was obvious.Phosphorus was removed by grinding and magnetic separation,and the phosphorus content in the reduced iron product was less than 0.10%.

Glutathione depleting drugs, antioxidants and intestinal calcium absorption

Glutathione （GSH） is a tripeptide that constitutes one of the main intracellular reducing compounds. The normal content of GSH in the intestine is essential to optimize the intestinal Ca2＋ absorption. The use of GSH depleting drugs such as DL-buthionine-S,R-sulfoximine, menadione or vitamin K3, sodium deoxycholate or diets enriched in fructose, which induce several features of the metabolic syndrome, produce inhibition of the intestinal Ca2＋ ab-sorption. The GSH depleting drugs switch the redox state towards an oxidant condition provoking oxida-tive/nitrosative stress and inflammation, which lead to apoptosis and/or autophagy of the enterocytes. Either the transcellular Ca transport or the paracellular Ca route are altered by GSH depleting drugs. The gene and/or protein expression of transporters involved in the transcellular Ca2＋ pathway are decreased. The favonoids quercetin and naringin highly abrogate the inhibition of intestinal Ca2＋ absorption, not only by restoration of the GSH levels in the intestine but also by their anti-apoptotic properties. Ursodeoxycholic acid, melatonin and glutamine also block the inhibition of Ca2＋ transport caused by GSH depleting drugs. The use of any of these antioxidants to ameliorate the intestinal Ca2＋ absorption under oxidant conditions associated with different pathologies in humans requires more investigation with regards to the safety,pharmacokinetics and pharmacodynamics of them.

La_(1-x)Ca_xMn_(1-y)Al_yO_3 perovskites as efficient catalysts for two-step thermochemical water splitting in conjunction with exceptional hydrogen yields

Solar‐driven thermochemical water splitting represents one efficient route to the generation of H2as a clean and renewable fuel.Due to their outstanding catalytic abilities and promising solar fuel production capacities,perovskite‐type redox catalysts have attracted significant attention in this regard.In the present study,the perovskite series La1‐xCaxMn1‐yAlyO3(x,y=0.2,0.4,0.6,or0.8)was fabricated using a modified Pechini method and comprehensively investigated to determine the applicability of these materials to solar H2production via two‐step thermochemical water splitting.The thermochemical redox behaviors of these perovskites were optimized by doping at either the A(Ca)or B(Al)sites over a broad range of substitution values,from0.2to0.8.Through this doping,a highly efficient perovskite(La0.6Ca0.4Mn0.6Al0.4O3)was developed,which yielded a remarkable H2production rate of429μmol/g during two‐step thermochemical H2O splitting,going between1400and1000°C.Moreover,the performance of the optimized perovskite was found to be eight times higher than that of the benchmark catalyst CeO2under the same experimental conditions.Furthermore,these perovskites also showed impressive catalytic stability during two‐step thermochemical cycling tests.These newly developed La1‐xCaxMn1‐yAlyO3redox catalysts appear to have great potential for future practical applications in thermochemical solar fuel production.

Porous layered La_(0.6)Sr_(0.4)Co_(0.2)Fe_(0.8)O_(3)perovskite with enhanced catalytic activities for oxygen reduction

Low-cost catalysts with high activity are in immediate demand for energy storage and conversion devices.In this study,polyvinyl pyrrolidone was used as a complexing agent to synthesize La_(0.6)Sr_(0.4)Co_(0.2)Fe_(0.8)O_(3)(LSCF)perovskite oxide.The obtained porous layered LSCF has a large specific surface area of 23.74 m^(2)/g,four times higher than that prepared by the traditional sol-gel method(5.08 m^(2)/g).The oxygen reduction reaction activity of the oxide in 0.1 mol/L KOH solution was studied using a rotating ring-disk electrode.In the tests,the initial potential of 0.88 V(vs.reversible hydrogen electrode)and the limiting diffusion current density of 5.02 mA/cm^(2)were obtained at 1600 r/min.Therefore,higher catalytic activity and stability were demonstrated,compared with the preparation of LSCF perovskite oxide by the traditional method.

Separation of alumina and silica from metakaolinite by reduction roasting-alkaline leaching process: Effect of CaSO_(4) and CaO

Limestone(CaCO3),which could promote sulfur fixation,was added to coal gangue during roasting in a circulating fluidized bed(CFB)boiler.CaO and CaSO_(4) were the main Ca-bearing minerals while metakaolinite was the major Al-bearing mineral in CFB slag.The effect of CaSO_(4) and CaO on the separation of alumina and silica from metakaolinite by reduction roasting−alkaline leaching process was studied.Results showed that metakaolinite was completely converted into hercynite and silica solid solutions(i.e.,quartz and cristobalite solid solutions)by reduction roasting with hematite.More than 95%of silica in the reduced specimen was removed by alkaline leaching.The addition of CaSO_(4) and CaO remarkably decreased the separation efficiency of alumina and silica in metakaolinite,which could be attributed to the formation of Si-bearing minerals:(1)Fayalite and anorthite were formed during the reduction roasting process;(2)Fayalite was stable while anorthite was converted into sodalite and wollastonite during the alkaline leaching process.This study demonstrates that sulfur in coal gangue should be fixed by treating the exhaust gas instead of controlling the combustion process of CFB to achieve the comprehensive recovery of silica and alumina from the CFB slag.

Verification of Levich Law-Determination of Hydrogen Currents during Calcareous Deposition

The complexity of calcareous deposits processes in a marine environment results in simultaneous effects of the following parameters： temperature, polarization potential, interfacial pH, chemical composition, etc.. The comprehension of these processes implies studies in artificial seawater and a follow-up of the parameters by voltarnperometry and chronoamperometry. Calcareous deposits electrochemically are very often used to follow up the evolution of scale deposition in desalination circuits. Again, the scale formation is brought about by electrochemical reduction of dissolved oxygen. The hydroxyl ions formed on the metallic surface engender a rise of interfacial pH which causes calcareous deposition （CaCOs and Mg（OH）2）. This reaction goes with reaction of hydrogen evolution which could disrupt the formed deposit, A study is carried out in a solution of seawater ASTM without calcium and without magnesium （so that the deposit will not be formed） on a titanium rotating disk electrode monitored between 300 and 1000 rpm. Study shows that Levich criterion is checked for the four values of selected potential on the diffusion plateau and a very cathodic polarization potential and a high temperature favors hydrogen current rate.

Single-atom modified graphene cocatalyst for enhanced photocatalytic CO_(2) reduction on halide perovskite

Metal halide perovskite(MHP)has become one of the most promising materials for photocatalytic CO_(2) reduction owing to the wide light absorption range,negative conduction band position and high reduction ability.However,photoreduction of CO_(2) by MHP remains a challenge because of the slow charge separation and transfer.Herein,a cobalt single-atom modified nitrogen-doped graphene(Co-NG)cocatalyst is prepared for enhanced photocatalytic CO_(2) reduction of bismuth-based MHP Cs_(3)Bi_(2)Br_(9).The optimal Cs_(3)Bi_(2)Br_(9)/Co-NG composite exhibits the CO production rate of 123.16μmol g^(-1)h^(-1),which is 17.3 times higher than that of Cs_(3)Bi_(2)Br_(9).Moreover,the Cs_(3)Bi_(2)Br_(9)/Co-NG composite photocatalyst exhibits nearly 100% CO selectivity as well as impressive long-term stability.Charge carrier dynamic characterizations such as Kelvin probe force microscopy(KPFM),single-particle PL microscope and transient absorption(TA)spectroscopy demonstrate the vital role of Co-NG cocatalyst in accelerating the transfer and separation of photogenerated charges and improving photocatalytic performance.The reaction mechanism has been demonstrated by in situ diffuse reflectance infrared Fourier-transform spectroscopy measurement.In addition,in situ X-ray photoelectron spectroscopy test and theoretical calculation reveal the reaction reactive sites and reaction energy barriers,demonstrating that the introduction of Co-NG promotes the formation of ^(*)COOH intermediate,providing sufficient evidence for the highly selective generation of CO.This work provides an effective single-atom-based cocatalyst modification strategy for photocatalytic CO_(2) reduction and is expected to shed light on other photocatalytic applications.