Nitrogen removal efficiency of iron-carbon micro-electrolysis system treating high nitrate nitrogen organic pharmaceutical wastewater

The nitrate nitrogen removal efficiency of iron-carbon micro-electrolysis system was discussed in treating pharmaceutical wastewater with high nitrogen and refractory organic concentration. The results show that the granularity of fillings,pH,volume ratios of iron-carbon and gas-water,and HRT. have significant effects on the nitrogen removal efficiency of iron-carbon micro-electrolysis system. The iron-carbon micro-electrolysis system has a good removal efficiency of pharmaceutical wastewater with high nitrogen and refractory organic concentration when the influent TN,NH4+-N,NO3--N and BOD5/CODCr are 823 mg/L,30 mg/L,793 mg/L and 0.1,respectively,at the granularity of iron and carbon 0.425 mm,pH 3,iron-carbon ratio 3,gas-water ratio 5,HRT 1.5 h,and the removal rates of TN,NH4+-N and NO3--N achieve 51.5%,70% and 50.94%,respectively.

An internal circulation iron-carbon micro-electrolysis reactor for aniline wastewater treatment:Parameter optimization,degradation pathways and mechanism

Aniline is a vital industrial raw material.However,highly-toxic aniline wastewater usually deteriorated effluent quality,posed a threat to human health and ecosystem safety.Therefore,this study reported a novel internal circulation iron-carbon micro-electrolysis(ICE)reactor to treat aniline wastewater.The effects of reaction time,pH,aeration rate and iron-carbon(Fe/C)ratio on the removal rate of aniline and the chemical oxygen demand were investigated using single-factor experiments.This process exhibited high aniline degradation performance of approximately 99.86% under optimal operating conditions(reaction time=20 min,pH=3,aeration rate=0.5 m3·h^(-1),and Fe/C=1:2).Based on the experimental results,the response surface method was applied to optimize the aniline removal rate.The Box–Behnken method was used to obtain the interaction effects of three main factors.The result showed that the reaction time had a dominant effect on the removal rate of aniline.The highest aniline removal rate was obtained at pH of 2,aeration rate of 0.5 m^(3)·h^(-1)and reaction time of 30 min.Under optional experimental conditions,the aniline content of effluent was reduced to 3 mg·L^(-1)and the removal rate was as high as 98.24%,within the 95% confidence interval(97.84%-99.32%)of the predicted values.The solution was treated and the reaction intermediates were identified by high-performance liquid chromatography,ultraviolet-visible spectroscopy,Fourier-transform infrared spectroscopy,gas chromatography-mass spectrometry,and ion chromatography.The main intermediates were phenol,benzoquinone,and carboxylic acid.These were used to propose the potential mechanism of aniline degradation in the ICE reactor.The results obtained in this study provide optimized conditions for the treatment of industrial wastewater containing aniline and can strengthen the understanding of the degradation mechanism of iron-carbon micro-electrolysis.

Three-dimensional electro-Fenton system with iron-carbon packing as a particle electrode for nitrobenzene wastewater treatment

Traditional Fenton oxidation is an effective method for reducing pollutants that are difficult to degrade.Owing to the large amounts of Fe(II),acids,and alkalis added in the reaction,large amounts of Fenton sludge are produced,increasing treatment costs and restricting the method’s application.In this study,we developed a three-dimensional electro-Fenton system by adding iron-carbon filler and investigated the effects of different electrolytic cell structure arrangements,particle electrode dosages,sponge iron(SI)to granular activated carbon(GAC)dosage ratios,current densities,H_(2)O_(2)dosages,and cathodic aeration on nitrobenzene(NB)wastewater treatment.The optimal system conditions were a particle electrode dosage of 100 g/L,SI:GAC mass ratio of 3:1,current density of 30 mA/cm^(2),H_(2)O_(2)dosage of 50 mmol/L,cathodic aeration of 0.8 L/min,and hydraulic retention time of 120 min.The average NB removal rate and chemical oxygen demand reached 67.38%±1.05%and 70.60%±1.15%,respectively,for which the increase in Fenton sludge was 891.8 mg/L.Different from the traditional Fenton process,additional Fe(II)was not required in the process used herein,reducing iron sludge accumulation and lowering the operating costs of using Fenton sludge as a hazardous waste treatment.In addition,the process applied in this study was able to reduce the chemical amounts used and increase the treatment efficiency.The reductions in sludge treatment costs and secondary pollutants make the proposed process an efficient and sustainable alternative for treating NB wastewater.

Nano-scaled iron-carbon precipitates in HSLC and HSLA steels

This paper studies the composition, quantity and particle size distribution of nano-scaled precipitates with size less than 20 nm in high strength low carbon (HSLC) steel and their effects on mechanical properties of HSLC steel by means of mass balance calculation of nano-scaled precipitates measured by chemical phase analysis plus SAXS method, high-resolution TEM analysis and thermodynamics calculation, as well as temper rapid cooling treatment of ZJ330. It is found that there existed a large quantity of nano-scaled iron-carbon precipitates with size less than 18 nm in low carbon steel produced by CSP and they are mainly Fe-O-C and Fe-Ti-O-C precipitates formed below temperature A1. These precipitates have ob- vious precipitation strengthening effect on HSLC steel and this may be regarded as one of the main reasons why HSLC steel has higher strength. There also existed a lot of iron-carbon precipitates with size less than 36 nm in HSLA steels.

Iron-carbon composite microspheres prepared through a facile aerosol-based process for the simultaneous adsorption and reduction of chlorinated hydrocarbons

Iron-carbon （Fe-C） composite microspheres prepared through a facile aerosol-based process are effective remediation agents for the simultaneous adsorp- tion and reduction of chlorinated hydrocarbons. Complete dechlorination was achieved for the class of chlorinated ethenes that include tetrachloroethylene （PCE）, trichlor- oethylene （TCE）, cis- and trans-l,2-dicloroethylene （c- DCE, t-DCE）, 1,1-dichloroethylene （1,1-DCE） and, vinyl chloride （VC）. The Fe-C particles potentially provides multi-functionality with requisite characteristics of adsorp- tion, reaction, and transport for the effective in situ remediation of chlorinated hydrocarbons. The carbon support immobilizes the ferromagnetic iron nanoparticles onto its surface, thereby inhibiting aggregation. The adsorptive nature of the carbon support prevents the release of toxic intermediates such as the dichloroethylenes and vinyl chloride. The adsorption of chlorinated ethenes on the Fe-C composites is higher （〉 80%） than that of humic acid （〈 35%） and comparable to adsorption on commercial activated carbons （ 〉 90%）. The aerosol-based process is an efficient method to prepare adsorptive- reactive composite particles in the optimal size range for transport through the porous media and as effective targeted delivery agents for the in situ remediation of soil and groundwater contaminants.

碳改性纳米零价铁对水中六价铬的强化吸附还原研究

纳米零价铁材料因其还原性强的特点而多用于水中Cr(Ⅵ)污染治理。以葡萄糖和氯化铁为原料,通过碳化煅烧还原,制备碳改性纳米零价铁复合材料(nZVI@GC)。材料形貌及结构性质的分析显示,nZVI@GC上纳米零价铁为体心立方的α-Fe^(0),且颗粒分散均匀,平均粒径为32 nm。批处理试验显示,24 h内nZVI@GC对水体中Cr(Ⅵ)的吸附还原质量比为178.6 mg/g,是纳米零价铁(nZVI)的5.7倍,且吸附还原反应符合准二级动力学模型(R^(2)=0.9993)。其中,在pH值为2~3,Cr(Ⅵ)的初始质量浓度为50 mg/L,纳米零价铁的投加质量浓度为0.5 g/L的条件下,nZVI@GC可在30 min内完全吸附还原水中的Cr(Ⅵ)。在干燥空气中无保护存放nZVI@GC时,复合材料上的碳可以有效抑制氧气对纳米零价铁的侵蚀。与新制备材料相比,30 d后nZVI@GC对水中Cr(Ⅵ)的吸附还原率仅下降3.4%。nZVI@GC为材料高效、经济地吸附还原水中Cr(Ⅵ)提供了一种选择。

铁碳自养反硝化高效去除厌氧氨氧化出水硝酸盐氮效能分析

通过工艺连续运行研究、铁沉淀形态转化和微生物种群结构分析,考察铁碳自养反硝化工艺对厌氧氨氧化出水硝酸盐氮的去除效能,揭示铁碳载体与生物膜耦合的理论机制.结果表明:铁碳自养反硝化工艺可实现硝酸盐氮的高效去除.在水力停留时间(HRT)为16.6h时,厌氧氨氧化出水的总氮(TN)去除率可达(90.0±4.7)%;在HRT为13.3h时,厌氧氨氧化出水的TN去除率为(82.2±1.4)%.在运行阶段Ⅰ,Fe_(3)O_(4)是生物膜中的主要铁沉淀类型,而在阶段Ⅲ,生物膜中Fe_(3)O_(4)减少,密度更小的FeOOH型铁沉淀有所增加.铁碳自养反硝化工艺运行过程中,在接种污泥中占优势的兼养反硝化菌脱氯单胞菌(Dechloromonas)比例显著降低,而自养反硝化菌和铁转化细菌得到富集,热单胞菌属(Thermomonas)的相对丰度由第43d的0.70%提升至第120d的4.51%.

中国铁矿石选矿技术发展与展望

铁矿石作为钢铁工业最为重要的原材料,是我国重要的战略性矿产资源之一。我国铁矿资源储量丰富,但97%以上属于贫矿,需要经过选矿富集后才能供给高炉炼铁。多年来,在我国选矿工作者的共同努力下,我国铁矿选矿技术得到长足进步和发展。通过回顾我国铁矿选矿技术的发展历程,综述单一弱磁选、单一浮选、重选—磁选—反浮选、磁化焙烧—磁选等主要选矿技术在我国铁矿选矿厂的应用,总结我国典型多金属共生型铁矿石如伴生稀土/萤石型铁矿石、伴生钛铁矿型铁矿石、伴生多金属硫化物型铁矿石和伴生硼铁矿型铁矿石的选矿现状,介绍影响我国铁矿选矿技术进步的关键设备如圆锥破碎机、高压辊磨机、半自磨机、立环脉动高梯度磁选机、高频振动细筛、搅拌磨机等,指出我国铁矿选矿未来要以“高效节能、低碳减排”为原则,以“优质优用、劣质能用”为战略,开发选冶联合工艺,研发大型高效设备,研制低温环保药剂,提高智能控制水平,加强资源综合利用。

简析钢铁材料的磁学性质

钢铁制品在日常生活中随处可见;钢铁材料具有磁性也是广为人知的生活常识。实用的钢铁材料种类繁多,磁性的强弱也有显著差别。本文旨在解析这个生活常识背后所涉及的物理知识。总体来看,钢铁材料主要是含有少量碳元素的铁碳合金,此外还可能包含少量其他合金元素。合金元素的含量及种类对钢铁材料磁性的影响很大。本文主要结合铁碳二元合金相图介绍了不同含碳量钢铁材料的组分,并据此对材料磁性的变化进行了定性分析。概括来说,铁磁性主要来自于材料中可能包含的三种组分:铁素体、渗碳体和马氏体,而奥氏体则仅具有顺磁性。其中马氏体是一种处于亚稳状态的非平衡相,无法标记在平衡相图中。本文也可以作为学习和应用相图的一个教学案例。

炼铁工序减污降碳协同增效技术评估方法研究

为推广减污降碳协同控制技术,以炼铁工序为研究对象,从协同度、成本收益和环境影响3个维度评价炼铁工序源头、过程节能技术、末端治理技术和低碳技术的协同控制效益。从污染物和碳排放协同度分析来看,源头、过程节能技术能有效推动炼铁工序污染物和碳排放的协同减排,而末端控制技术对污染物和温室气体的减排不具有协同性。绿氢冶炼技术和熔剂性球团制备技术污碳减排协同度较高,此外高炉喷吹焦炉煤气技术、高炉煤气回收技术和高炉热风炉双预热能协同减少VOCs和碳排放。在当前我国碳交易价格条件下,从成本收益分析来看节能技术和污染物末端治理技术具有可推广性。随着碳交易价格的上涨,绿氢冶炼和碳捕集(CCS)技术减排成本呈下降趋势。绿氢冶炼技术、污染物末端治理技术最能有效地减少环境影响,其他节能技术也能相应减少环境影响,而现有条件下CCS技术的实施会增加对环境的影响。综合污染物和温室气体协同减排的协同度、经济效益和环境效益评估,炼铁工序中源头防治和节能技术可作为我国现阶段减污降碳协同增效技术进行推广,随着未来碳交易价格的增长和能源的转型,绿氢冶炼技术和CCS技术具有较大应用前景。

磷化铁@碳纳米管制备及其锌空电池正极催化性能——本科综合化学实验设计

为响应“新工科”建设的需求,将碳基纳米材料与金属锌空电池相结合的前沿科研成果设计为本科综合化学实验。通过化学氧化聚合及高温热解制备磷化铁@碳纳米管,并考察其作为锌空电池正极催化材料的电化学性能,从而帮助学生了解新能源电池行业最新发展动态,熟悉锌空电池的组装及性能测试,将已学知识“学以致用”,培养分析、解决问题的能力和创新能力,提升综合素养。

活性炭负载纳米零价铁/银复合材料对水中铅的吸附性能研究

通过液相还原法,将纳米零价铁(nZVI)和纳米银(nAg)负载到活性炭(AC)上,制备出一种新型复合材料(nAg/nZVI/AC),用于处理含铅废水。结果表明,在pH=7条件下,nAg/nZVI/AC对Pb(Ⅱ)的去除率达到99.7%,比原AC提高了74.28%。同时,银的加入提高了nZVI的反应活性,使吸附更快达到平衡。吸附过程与Langmuir模型(R2为0.972)和准二级动力学模型(R2为0.9219)更吻合。结合热力学分析结果,Pb(Ⅱ)的去除是一个以化学吸附为主的自发过程。

铁碳材料促进有机固体废弃物厌氧消化作用的研究进展

有机固体废弃物的厌氧消化在实现废物资源化利用中有重要意义。近年来,通过使用不同类型的添加剂提高厌氧消化的效率成为研究热点,其中铁基和碳基材料因为具有良好的导电性被广泛使用。着重归纳了铁基和碳基材料促进有机固体废弃物厌氧消化的研究进展,总结了两种添加剂在厌氧消化中的作用机制。铁基材料主要通过降低氧化还原电位为微生物创造生存条件、加强直接种间电子转移(DIET)、通过刺激关键酶促进水解和酸化过程的作用。碳基材料除可加强DIET外,还通过吸附抑制性化合物和富集功能性微生物及支持微生物定殖来发挥作用。同时,铁碳材料可协同促进厌氧消化。最后,深入分析了这两种材料在有机固体废弃物的厌氧消化过程中存在问题,并展望了其发展前景。

焦炉煤气GLT络合铁脱硫绿色低碳系统性解决方案分析

焦炉煤气PDS脱硫的硫磺收率在50%~60%,副盐累积产生大量脱硫废液,仅仅络合铁催化剂应用在HPF装置上存在诸多问题。从GLT络合铁脱硫的化学原理和工艺原理出发,结合工业改造实际,GLT络合铁技术应用在焦炉煤气净化中形成了系统化成套解决方案,不仅解决了络合铁催化剂应用的适配性问题,而且将硫膏资源化的同时实现零废液外排。通过案例对比分析了不同技术路线的技术经济性,GLT络合铁技术系统性解决焦炉煤气脱硫存在的环保问题,显著节省投资和运行费用,极大降低煤气净化过程的二氧化碳排放。

铁掺杂分散性氮化碳的制备及其对废水中Cr(Ⅵ)的还原

Fe掺杂辐照改性石墨相氮化碳(g-C_(3)N_(4))制备铁掺杂分散性氮化碳,利用SEM、XRD、FTIR对材料进行表征,电子束辐照改变了石墨相氮化碳的能带结构,Fe的掺杂抑制了光生电子空穴对的复合。在光催化条件下利用铁掺杂分散性氮化碳对废水中Cr(Ⅵ)的还原能力进行了试验研究,对电子束辐照剂量、催化剂种类、催化剂投加量、Fe的掺杂量等影响因素进行了相关的分析,结果表明:电子束辐照剂量为30 kGy,Fe的掺杂比例为10%时,Cr(Ⅵ)的降解效率最高,180 min内的降解率为95%,是纯石墨相氮化碳的4倍以上。

铁碳微电解填料对人工湿地反硝化作用的影响

为探究铁碳微电解原理对人工湿地系统中反硝化作用的影响,利用液相还原法制得活性炭表面负载零价铁(Fe~0)材料,以填料不同投加配比,搭建垂直流人工湿地模拟小试装置,分别有1号纯砾石、2号砾石+3%铁碳、3号砾石+8%铁碳,观察每日进出水水质情况。结果表明:投加初期,2号与3号装置对硝态氮的去除效果显著,几乎可实现全部转化;填料表面Fe元素会伴随水流有一定损耗,且投加量越大损耗越高;两装置分别在18d和21d后出水水质达到稳定状态,硝态氮浓度稳定在11mg/L和13mg/L,略低于空白装置。

CIPs@Mn_(0.8)Zn_(0.2)Fe_(2)O_(4)-CNTs复合材料低频吸波性能研究

随着5G无线通信与低频雷达侦察技术的飞速发展,低频电磁波辐射已成为当代的严重问题。目前,中高频段吸波材料的研究已趋于成熟,而设计低频段吸波材料仍面临巨大的挑战,亟待研究者们解决。基于四分之一波长相消机制,本研究设计了0.5~3 GHz低频段复合吸波材料。采用简单的一步水热法,诱导铁氧体在羰基铁粉与碳纳米管表面生长,制备出CIPs@Mn_(0.8)Zn_(0.2)Fe_(2)O_(4)-CNTs三元复合材料,对比研究了碳纳米管含量对材料吸收峰频率的影响。实验结果表明,引入碳纳米管,一方面为材料带来了界面极化、偶极极化等额外的损耗机制,增加了材料的衰减系数;另一方面基于四分之一波长相消机制,高介电与高磁导率的耦合,使材料在低频段获得良好的阻抗匹配。最终,在4 mm厚度下,样品分别在2.11与1.75 GHz处,获得了–40.8与–32.1 dB的反射损耗,–10 dB带宽分别为1.70~2.70 GHz和1.40~2.20 GHz。该复合材料制备工艺简单,低频吸收性能良好,具有很大的应用潜力,为开发更有效的低频吸波材料提供了新的思路和方法。

工艺参数对球墨铸铁和低碳钢激光焊接的影响

为了提高球墨铸铁和低碳钢焊接接头力学性能,解决容易开裂的问题,采用激光焊接的方法对球墨铸铁和低碳钢进行焊接,研究了工艺参数对其焊接接头的组织和性能影响。结果表明,随着激光功率逐渐增加或焊接速率的逐渐变缓,试验件抗拉强度呈现出先增大后减小的变化趋势;当焊接功率为4250 W和焊接速率为2.4 m/min时,试样件焊接接头的强度处于极值400 MPa;在球墨铸铁侧热影响区内形成3种壳体结构(双壳结构、单壳结构和无核结构);焊缝区组织主要由树枝晶组织、少量的马氏体和莱氏体组织构成;焊缝区存在微裂纹,通过添加镍基材料可获得无裂纹焊缝,并提升抗拉强度约40 MPa,达到母材的95%。该研究对后续球墨铸铁与低碳钢高功率激光焊接工艺优化是有帮助的。

活性铁对海洋沉积物中有机碳的保存作用

沉积物碳汇是海洋碳汇的重要组成部分,揭示沉积物的储碳机制对研究气候变化与全球碳循环的相互作用具有重要意义。矿物对有机碳的保护作用是有机碳最重要的稳定机制,其中活性铁(Fe_(R))在沉积物有机碳的累积作用中发挥着捕获有机碳并形成“铁锈碳汇”的重要作用。本文系统梳理了近年来关于海洋沉积物中Fe_(R)的固碳的研究成果,总结了海洋沉积物中Fe_(R)的提取方式、类型、固碳量、固碳机制、结合有机质来源及分子类型,阐述了Fe_(R)固碳的重要意义,旨在加深对矿物与有机碳相互作用的理解。海洋沉积物中Fe_(R)常通过柠檬酸盐-碳酸氢盐-连二亚硫酸盐(CBD)还原提取,主要以针铁矿、水铁矿及赤铁矿等氧化物形式存在。Fe_(R)可以结合沉积物中约80%的有机碳,结合机制包括以配体交换为主的吸附机制和共沉淀/螯合机制。Fe_(R)与有机碳的结合机制可依据铁结合有机碳(Fe_(R)-OC)与Fe_(R)的摩尔比值(Fe_(R)-OC∶Fe_(R))简单判定,当Fe_(R)-OC∶Fe_(R)低于1.00时以吸附方式结合,大于1.00时以共沉淀方式结合,且共沉淀相比吸附机制具有更高的有机碳结合量及稳定性。大部分海洋沉积物中Fe_(R)优先与海源类有机质结合,但在氧化还原频繁的河口及三角洲地区倾向与陆源类有机质结合。分子模拟实验、木质素氧化降解及近边X射线吸收精细结构光谱表明Fe_(R)与芳香碳及羧基碳等有机质具有更高的亲和性。Fe_(R)对有机质的稳定保存及减缓气候变化引起的负反馈具有重要意义,建议未来更多关注沉积物中有机质与铁矿物结合的具体过程及不同沉积环境Fe_(R)固碳的差异机制,更加关注不同结合机制的定量化及重要性对比研究。

闽江河口湿地围垦稻田对土壤铁碳结合特征的影响

土壤铁氧化物结合态有机碳是有机碳长期维持的主要途径,但其机理研究仍较为薄弱。为探究河口湿地围垦稻田对土壤铁碳结合特征的影响,本研究选择福建省闽江河口天然芦苇湿地与围垦稻田为研究对象,对两种类型土壤中的铁结合态有机碳(Fe-OC)及其相关指标进行测定与分析。结果显示:①芦苇湿地围垦稻田改变了土壤氧化还原过程,显著影响土壤中铁相的转化。围垦后土壤二价铁[Fe(Ⅱ)]、三价铁[Fe(Ⅲ)]、活性总铁含量(HCl-Fe_(t))及Fe(Ⅲ)/Fe(Ⅱ)分别显著下降了24.68%、52.56%、51.45%、35.68%(P<0.05)。游离态氧化铁(Fe_(d))与无定形态铁(Fe_(o))含量分别显著下降了21.64%和29.24%(P<0.05),络合态铁(Fe_(p))含量则有所增加。②芦苇湿地围垦稻田显著影响土壤碳固存,Fe-OC与土壤有机碳含量(SOC)在围垦稻田后分别显著下降了39.03%和18.42%(P<0.05);芦苇湿地与稻田土壤Fe-OC均主要以吸附途径结合,稻田土壤Fe-OC对土壤有机碳的贡献率(fFe-OC)显著高于芦苇湿地(P<0.05)。③土壤全氮、含水量、电导率、铁以及土壤有机碳、溶解性有机碳与Fe-OC呈显著正相关(P<0.01)。本研究可为退耕还湿、土壤碳增汇提供科学参考。