水产养殖系统中机械增氧与液态氧增氧的效果比较

【研究目的】为分析水产养殖系统中机械增氧与液态氧增氧的增氧效果;【方法】设置增氧潜力、溶解氧(DO)扩散速度、水质因子、对虾生长等多个处理组,对比两增氧系统在各方面的差异。【结果】液态氧的增氧潜力是机械增氧的3倍左右,且DO扩散速度快;液态氧增氧系统和机械增氧系统的DO含量、水温、盐度和pH变化趋势相似,且均相对稳定。与机械增氧系统相比,液态氧增氧系统的氨态氮(TAN)、亚硝态氮(NO2-N)和可溶性磷(PO4-P)含量变化剧烈;液态氧增氧系统中开启增氧机会在一定程度上降低DO含量。液态氧增氧的运行成本与机械增氧相当;但液态氧增氧的效果稳定,且无噪音、无污染、不受外界气压等环境因素的影响。【结论】液态氧增氧在增氧潜力及增氧速度等多个方面均优于机械增氧。

NO_2在石灰石浆液中的吸收特性研究

利用双搅拌釜反应器研究NO2在石灰石浆液中的吸收过程。对石灰石浆液浓度、反应温度、石灰石粒径分布、搅拌速率、NO2入口浓度及烟气中的含氧量等对NO2吸收速率的影响研究表明,在NO2的吸收过程中,石灰石的溶解影响显著;NO2的吸收速率随着搅拌速率、NO2入口浓度和烟气中含氧量的升高而升高,较低的反应温度有利于NO2的吸收。

锂氧电池正极催化剂的制备及性能

为了降低电池极化现象,提升锂氧电池的电化学性能,采用液相扩散法制备锶掺杂的ZIF-8催化剂材料。以硝酸锶和乙酸锌为金属离子本体原料,以2-甲基咪唑为有机配体,以聚乙烯吡咯烷酮为结构导向剂,液相扩散获得锶掺杂的ZIF-8催化剂材料,并通过SEM和TEM测试考察材料的形貌,TGA测试验证材料的结构稳定性,同时借助电化学设备测试材料的电化学性能。实验结果表明:当硝酸锶和乙酸锌的摩尔比为2∶1时,得到的Sr-ZIF-8材料呈六边形片状的形貌;TGA测试表明该材料有较好的结构稳定特性;将材料制成电极应用到锂氧电池中,在100 mA/g的电流密度下,进行恒流充放电测试时,电池首圈可获得4048.5 mA·h/g的放电比容量,放电平台电压值为2.67 V,放电过程的过电势仅为0.29 V;在进行限容300 mA·h/g的条件下,同样的电流密度下可循环27圈,表现出了较好的循环稳定性能。

金属有机物化学气相法制备YBCO超导薄膜研究

运用金属有机物化学气相沉积法(MOCVD),在LaAlO3(LAO)单晶上沉积YBa2Cu3O7-x(YBCO)超导薄膜。通过使用优化的进液装置,使金属有机源连续、稳定地输送至蒸发皿进行闪蒸。通过优化总气压、氧分压等生长条件,获得高质量的YBCO薄膜。在固定的温度条件下,调节反应总气压和氧分压,在总压为380Pa,氧分压为180Pa获得YBCO薄膜临界电流密度Jc=0.6MA/cm2。随着氧分压增大,YBCO薄膜产生a轴取向,(005)峰向左偏移,且薄膜中的Cu/Ba由1.0变化至1.63。在Cu/Ba=1.48时,YBCO薄膜结构与性能较优。

气相质谱法研究CO_2-O_2钢液脱碳反应

采用气相质谱法研究了CO_2-O_2在Fe-C体系中的脱碳反应,将气相质谱仪用于气-液体系反应动力学研究,且研究体系具有重要的科研、经济价值。通过质谱分析脱碳反应,考察了气体取样口位置、CO_2喷吹浓度、喷吹高度、气体流速、原始配碳量及反应温度对脱碳反应的影响。结果表明:气体取样口位置为1cm、气体喷吹高度为3cm、气体流速为150mL/min时为最佳气体喷吹条件。原始配碳量在4.0%～1.0%范围CO、CO_2气体呈现3个阶段式变化,1.0%～0.4%呈现两个阶段式变化;在第一阶段中O_2与碳发生反应生成CO_2、CO的同时,CO_2与碳也发生反应生成CO,确定原始配碳量为3.0%是最佳值。且反应温度越高越有利于脱碳反应的进行,达到1873K以后反应温度对脱碳反应的影响较小,确定1873K为最佳实验温度。质谱法测定的终点碳含量理论值与测量值基本一致,说明气相质谱法研究CO_2-O_2脱碳反应的实验数据是可靠的,可用于研究气-液体系反应动力学。

Selective oxidation of alcohols with H2O2 catalyzed by zinc polyoxometalate immobilized on multi-wall carbon nanotubes modified with ionic liquid

In this work,acid functionalized multi-wall carbon nanotubes（MWCNTs） were modified with imidazolium-based ionic liquids.The selective oxidation of various alcohols with hydrogen peroxide catalyzed by [PZnMo2W9O39]^5-,ZnPOM,supported on ionic liquids-modified with MWCNTs,MWCNTAPIB,is reported.This catalyst[ZnPOM@APIB-MWCNT],was characterized by X-ray diffraction,scanning electron microscopy（SEM） and FT-IR spectroscopic methods.This heterogeneous catalyst exhibited high stability and reusability in the oxidation reaction without loss of its catalytic performance.

基于UV+O_2的铝合金切削废液再生处理研究

针对切削废液的处理成本高、难度大的问题,从切削废液再生、回用的角度出发,研究采用UV+O_2高级氧化法对铝合金切削废液进行处理,并从细菌含量、润滑性、pH、防腐性等方面来对比处理后的切削废液与新鲜切削液。结果表明,UV协同O_2高级氧化法处理铝合金切削废液,能够快速有效的杀死切削废液中的细菌,处理3 h后,杀菌率达到99.27%;同时能够改善切削废液的润滑性能,提高pH,处理3 h后的pH为9.74,略低于新鲜切削液;处理后的切削液中,铝合金的自腐蚀电位明显正移,切削液的防锈性能显著提高。处理后的切削液各项性能基本得到恢复,并且达到回用的效果,是一种绿色环保高效的处理切削废液的方法。

空分装置液氧、液氮产品流量测量解决方案

本文主要在分析空分装置液氧、液氮涡街流量计使用现状的基础上,对管道尺寸确定的情况下不能测量较大流量以及涡街流量计小信号切除量较大的问题进行相关研究改进,还就此类问题提出改造建议并对实施效果进行跟踪,对国内煤化工企业的大型空分装置在产品核算、经济效益分析、可靠运行的方面具有一定帮助。

Hybrid polymer electrolyte for Li–O_2 batteries

Li–O_2 batteries have attracted much attention because of their high specific energy. However, safety problem generated mainly from the flammable organic liquid electrolytes have hindered the commercial use of Li–O_2 batteries. One of the competitive alternatives is polymer electrolytes due to their flexibility and non-flammable property. Moreover, the hybrid polymer electrolyte with enhanced electrochemical properties would be achieved by incorporating inorganic filler, liquid plasticizer and redox mediator into the polymer. While most researches of the hybrid polymer electrolyte focused on Li-ion batteries, few of them took account into its application in Li–O_2 batteries. In this review, we mainly discuss hybrid polymer electrolytes for Li–O_2 batteries with different composition. The critical issues including conductivity and stability of electrolytes are also discussed in detail. Our review provides some insights of hybrid polymer electrolytes for Li–O_2 batteries and offers necessary guidelines for designing the suitable hybrid polymer electrolyte for Li–O_2 batteries as well.

Reaction mechanism of lanthanum nitrate-doped Mo–La material during solid–liquid spray doping processing

At three critical temperatures which were obtained by thermo-gravimetry-differential thermal analysis–differential scanning calorimetry（TG/DTG/DSC）curves of lanthanum nitrate crystal, the air thermal decomposition experiments and solid–liquid spray doping simulation procedures of lanthanum nitrate crystal were carried out, and their products were analyzed by X-ray diffraction（XRD）. Meanwhile, the spray doping processing of Mo O2–50 wt% La（NO3）3composite powder was undergone with lanthanum nitrate solution as the dopant,and doped Mo O2powder was analyzed by XRD. The results demonstrate that during the traditional solid–liquid spray doping processing, lanthanum nitrate, in the form of either crystal or aqueous solution, would be converted into La（NO3）3á4H2O by the dehydration reaction, rather than be decomposed to La2O3and NO or NO2. Therefore, it is inferred that the oxynitride gas produced from the process is attributed to the decomposition of residual HNO3in lanthanum nitrate crystal. The source of HNO3is supported by the chemical composition of lanthanum nitrate crystal.

离子液体吸收氧气及其应用的研究进展

本文对近年来离子液体(ILs)吸收氧气(O2)及其在分离、活化O2方面的研究进展进行了系统地论述.首先,概述了常规ILs、Co(Ⅱ)螯合型ILs和ILs支撑液膜(SILMs)吸收分离O2的研究工作,并着重讨论了阴离子种类和体积大小、阳离子种类和烷基取代基碳链长度等内在因素以及温度和压力等外在因素对ILs吸收O2性能的影响.其次,比较了ILs吸收O2、二氧化碳(CO2)和氮气(N2)等气体的性能差异,并结合△solH■m和△solG■m等热力学性质对此差异进行了深入分析.最后,重点论述了ILs活化O2的机理及其在金属-O2电池和一锅氧化级联催化反应中的应用,并对ILs吸收、分离和活化O2领域的后续研究提出了展望与建议.

混合液回流比对多点进水新型A/O/A/A/O泥膜耦合工艺脱氮除磷的影响

针对中国南方城镇低碳氮比(低C/N)生活污水的脱氮除磷问题,开发并设计了新型多点进水A1/O2/A3/A4/O5泥膜耦合工艺及中试装置。在进水点1和进水点2的进水流量比为4:6的条件下,通过改变混合液回流比,研究了其对系统中有机物、氮、磷的去除影响及氮素的转化规律。结果表明:当平均进水低C/N比为2.09,混合液回流比为300%时,出水中COD、NH4+-N、TN、TP的平均值分别为23.45、0.80、12.41、0.36 mg·L^(-1),平均去除率分别为86.88%、98.25%、77.68%、90.31%;相对于分段进水A/O/A/A/O泥膜耦合工艺,增加混合液回流比后系统对TN的去除率由68.28%增加到77.68%;对TP的去除率由75.22%增加到90.31%。本系统对于低碳氮比污水处理具有明显的脱氮除磷效果优势,解决了低碳氮比污水生物处理过程中磷出水较难低于0.5 mg·L^(-1)的难题。

α-Fe2O3 immobilized benzimidazolium tribromide as novel magnetically retrievable catalyst for one-pot synthesis of highly functionalized piperidines

Nanostructured ot-Fe2O3 were prepared by precipitation followed by calcination method. Cetyltrimethylammonium bromide （CRAB） was used as surfactant. The nano α-Fe2O3 was then silanized with （3-chloropropyl）-triethoxysilane （CPTES） by room temperature mixing ofα-Fe2O3 and CPTES to produce silane coated ct-Fe2O3 （CIPr-Si@Fe2O3）. As-synthesized CIPr-Si@Fe2O3 was functionalized via covalent grafting of benzimidazole to produce 3-（1-benzimidazole）Pr-Si@Fe2O3. This was further reacted with bromine to afford α-Fe2O3 immobilized benzimidazolium tribromide （α-Fe2O3-BIM tribromide）. This ionic liquid （IL） α-Fe2O3 BIM tribromide was characterized by FT-IR, XRD, TEM, SEM, TGA, VSM, EDX and BET analysis. The as-synthesized IL tribromide was used as catalyst for one-pot synthesis of highly substituted piperidines. The method is greener in terms of solvent selection, recovery of the catalyst and efficiency.