Reconstruction and recovery of anatase TiO_(2) from spent selective catalytic reduction catalyst by Na OH hydrothermal method

The improper disposal of spent selective catalytic reduction (SCR) catalysts causes environmental pollution and metal resource waste.A novel process to recover anatase titanium dioxide (TiO_(2)) from spent SCR catalysts was proposed.The process included alkali (NaOH) hydrothermal treatment,sulfuric acid washing,and calcination.Anatase TiO_(2) in spent SCR catalyst was reconstructed by forming Na_(2)Ti_(2)O_(4)(OH)_(2) nanosheet during NaOH hydrothermal treatment and H_(2)Ti_(2)O_(4)(OH)_(2) during sulfuric acid washing.Anatase TiO_(2) was recovered by decomposing H_(2)Ti_(2)O_(4)(OH)_(2) during calcination.The surface pore properties of the recovered anatase TiO_(2) were adequately improved,and its specific surface area (SSA) and pore volume (PV) were 85 m^(2)·g^(-1)and 0.40 cm^(3)·g^(-1),respectively.The elements affecting catalytic abilities(arsenic and sodium) were also removed.The SCR catalyst was resynthesized using the recovered TiO_(2) as raw material,and its catalytic performance in NO selective reduction was comparable with that of commercial SCR catalyst.This study realized the sustainable recycling of anatase TiO_(2) from spent SCR catalyst.

低渗透砂岩油藏不同流体驱油效率实验

准噶尔盆地东缘低渗透砂岩油藏注水开发中—后期,开发效果变差,含水率变高,需要新的有效开发手段,选取不同流体开展驱油效率实验。利用天然岩心组合成长岩心并模拟地层条件,进行全程水驱及水驱至油藏目前采出程度后转注N_(2)、CH_(4)和CO_(2)的驱油实验,并对不同流体注入前后,进行岩心核磁共振扫描及原油赋存孔隙直径反演。研究结果表明,CO_(2)驱可提高原油采出程度21.58%,驱油效率及原油动用程度从大到小依次为CO_(2)、CH_(4)、H_(2)O和N_(2)。N_(2)主要动用较大孔隙中的原油,动用孔隙直径下限为170.9 nm;CH_(4)主要动用中—大孔隙中的原油,动用孔隙直径下限为48.7 nm;CO_(2)可以动用各个尺寸孔隙中的原油,动用孔隙直径下限最低,为27.8 nm。油田现场建立CO_(2)驱先导试验区,注CO_(2)后产液量上升,含水率下降,产油量增加,研究成果在现场应用效果良好。

利用CO_2改善韦5稠油油藏开采效果

针对江苏油田韦5中低渗复杂小断块薄层稠油油藏进行CO2开采方式研究,为同类型稠油油藏利用CO2开采提供有益的借鉴。用数值模拟方法研究了CO2吞吐的敏感因素,结果认为,周期注气量、注气速度和生产过程的井底流压是影响吞吐效果的重要因素,浸泡时间对效果影响不大。以增产油量和换油率作为评价依据的计算结果表明,在大注气量、高注气速度和合理控制的生产井底流压下存在最优吞吐轮次,可以得到较好的CO2吞吐效果。

纳米材料在提高原油采收率中的研究进展

近年来,油田采油过程对驱油材料的性能提出了更高的要求,使用纳米材料是从微观角度提升驱油剂性能的重要方法。研究表明,对纳米材料进行改性处理,如表面接枝改性、构造核-壳分子结构等,以及将纳米材料与其他驱油材料(如聚合物、表面活性剂等)复配,可从降低油水界面张力、乳化原油降低原油粘度、改善岩石表面润湿性、稳定泡沫等方面推动原油流动,可见纳米材料在提高原油采收率方面具有重要意义。综述了近几年国内外纳米SiO_(2)、纳米TiO_(2)、纳米纤维素、聚合物纳米微球、纳米石墨烯等纳米材料在驱油材料中应用的研究进展,解析了其研发中的瓶颈问题及今后的研发方向,评述了各种纳米材料提高原油采收率、抗温、抗盐等性能,以期为相关研究提供借鉴。

商13-22单元CO_2驱室内实验研究

通过对胜利油田商 1 3 2 2单元进行的CO2 驱室内实验研究 ,确定了商 1 3 2 2单元的最小混相压力、原油与CO2体系的基本物性、CO2 对原油的膨胀降粘效果以及现场进行驱替时的合理注入方式。提出了胜利油田CO2 驱室内研究的一般思路 ,对胜利油田利用CO2 驱提高低渗透油田采收率具有一定的指导意义。

Synthesizing CNT-TiO_(2) nanocomposite and experimental pore-scale displacement of crude oil during nanofluid flooding

Metallic nanoparticles and carbon nanomaterials have been extensively studied in enhanced oil recovery.Carbon nanotube(CNT)/TiO_(2) nanocomposite is synthesized and investigated in terms of contact angle,interfacial tension(IFT),emulsion stability,etc.Its performance in oil displacement in porous media is evaluated through glass micromodel experiment.The synthesized CNT/TiO_(2) is composed of TiO_(2)-based nanocomposites and CNTs as reinforcement phase.TiO_(2) is the dominant crystalline phase,and TiO_(2) nanoparticles cover on the CNTs.CNT/TiO_(2) nanocomposite is able to alter the wetting conditions of the rock from strong oil-wet to hydrophilic conditions and effectively reduce the interfacial tension.CNT/TiO_(2) nanocomposite plays an effective role in stabilizing the Pickering emulsions,and even forms stable emulsions at high temperature as 90℃.For NaCl concentration of up to 2%,a stable emulsion can be formed even after 7 days.It is observed from glass micromodel experiments that the CNT/TiO_(2) nanofluid provides a higher recovery factor denoting its promising performance in enhanced oil recovery.

钛精矿重选分离含硅物相影响因素研究

针对四川某钛精矿中存在的硅含量过高的问题,提出了摇床重选法分离二氧化硅的方法。通过球磨工艺获得不同粒径颗粒,然后采用摇床进行重选,研究粒径大小、粒径组分占比、冲程等因素对钛精矿含硅相的分离效果。结果表明,随着磨矿时间的增加,-200目(<75μm)钛精矿占比逐渐增加。当研磨时间为8 min时,-200目钛精矿的占比为83.0%(质量分数)。随着冲程的增大,SiO_(2)的品位和TiO_(2)的回收率均呈逐渐增大的趋势。当冲程为15 mm时,SiO_(2)的品位由2.46%(质量分数)降低至1.07%。重选分离后原矿分为三部分,TiO_(2)品位:钛精矿>中矿>尾矿,SiO_(2)品位:钛精矿<中矿<尾矿。当-200目铁精矿占比85.5%(质量分数)时,重选后SiO_(2)的含量最低可降至0.93%(质量分数)。

废SCR催化剂中TiO_(2)载体的深度净化研究

湿法化学法是从废脱硝催化剂中回收高纯度TiO_(2)载体的有效方法。为进一步提高回收TiO_(2)纯度,同时探究湿法化学过程对TiO_(2)表面物化性质的影响,采用草酸浸出+混碱热压浸出的方法从废脱硝催化剂中回收TiO_(2),其纯度可达97.37%。采用XRD、TEM、BET、TGA等表征手段对废催化剂、回收TiO_(2)载体以及高纯商业TiO_(2)载体的表面性质进行了研究。结果表明,回收TiO_(2)载体物相结构、表面形貌、比表面积和孔结构、颗粒粒径和表面羟基均得到有效恢复,满足商业TiO_(2)载体的要求。但氧化还原性和表面酸性与高纯商业TiO_(2)载体存在一定差异。该研究为从废脱硝催化剂中回收TiO_(2)的进一步利用和改性提供了基础和参考。

碳纳米管-二氧化钛纳米复合材料的合成及纳米流体驱油实验

为了同时利用(类)金属氧化物和碳纳米材料在提高采收率方面的作用,合成了碳纳米管-二氧化钛(CNT-TiO_(2))纳米复合材料,用接触角、界面张力和乳液稳定性等评价其性能,通过玻璃刻蚀模型驱油实验评估CNT-TiO_(2)纳米流体驱油效果。合成的CNT-TiO_(2)纳米复合材料由二氧化钛基体和碳纳米管增强相组成,二氧化钛为主要的结晶相,二氧化钛纳米颗粒覆盖在碳纳米管上。CNT-TiO_(2)能够将岩石的润湿性从油湿变为水湿,并降低油水界面张力。CNT-TiO_(2)可提高Pickering乳液的稳定性,在90℃条件下形成的乳液仍能保持稳定;NaCl质量分数高达2%时,配制的乳液在静置7 d后仍保持稳定。驱油实验结果显示,CNT-TiO_(2)纳米流体提高采收率效果较好。

废SCR脱硝催化剂混碱热压浸出V、W研究

受复杂烟气条件影响,SCR催化剂经长时间运行后会引发失活现象,不可逆的转变为废弃SCR催化剂。为实现其资源化利用,开展了废SCR催化剂中有价金属钒钨提取及TiO_(2)回收的系列工艺研究。对高压碱浸提取钒钨过程进行工艺优化,考察了稀碱浸出体系下反应温度、反应时间、液固比、碱浓度、Na_(2)CO_(3)添加等因素对废催化剂中钒钨浸出过程的影响,并结合XRD、SEM等表征手段对浸出渣结构进行协同调控,综合钒钨浸出速率与浸出渣的载体性能优化工艺条件,钒、钨浸出率可达98.9%、64.4%,回收载体TiO_(2)含量达95.87%。

TiO_(2)-NTAs/ZnO异质结的制备及紫外探测性能研究

利用电子束蒸发技术、阳极氧化法和磁控溅射技术在ITO玻璃衬底上制备了二氧化钛纳米管阵列/氧化锌(TiO_(2)-NTAs/ZnO)异质结,利用SEM、EDS Mapping、XRD、Raman、分光光度计和电化学工作站等对样品的微观形貌、元素成分、晶体结构、透过率和紫外探测性能进行表征。结果表明,TiO_(2)-NTAs的表面结构清晰、高度有序、孔径均一,为锐钛矿型,沿(101)晶面择优生长;ZnO薄膜呈现颗粒状附着在TiO_(2)-NTAs的表面,为六方纤锌矿型;在TiO_(2)-NTAs/ZnO异质结中,钛、锌和氧3种元素呈均匀分布。相比TiO_(2)-NTAs,TiO_(2)-NTAs/ZnO异质结在紫外-可见光区具有较高的吸收能力;能有效提高光暗电流比、缩短响应恢复时间,有助于紫外探测器的实际应用。

In_(2)O_(3)/TiO_(2)室温氢气传感器及其优异的氢敏性能

为改善纳米TiO_(2)传感器在室温下对H_(2)虽有快速响应但恢复过慢的问题,引入商业纳米In_(2)O_(3)对其进行改性。分别采用压片法和阳极氧化-沉积法制备了In_(2)O_(3)/TiO_(2)纳米复合压片薄膜和In_(2)O_(3)/TiO_(2)纳米管阵列,并将其应用于氢气传感器,研究了其室温氢敏性能。采用扫描电镜、X射线衍射、比表面积测试等方法对样品进行了表征,并研究了不同电极(Ag、Pt、Pd)、不同热处理温度及不同质量分数的In_(2)O_(3)对复合传感器室温氢敏性能的影响。结果表明,与纯TiO_(2)传感器相比,复合传感器扩大了氢气的检测范围,室温下可检测到体积分数1×10^(-6)~1×10^(-3)的氢气,且恢复时间大大缩短。其中,以Pt为电极,经600℃退火的质量分数为20%的In_(2)O_(3)/TiO_(2)复合传感器表现出最优的氢敏性能,在室温下对体积分数1×10^(-6)H_(2)的响应时间为7 s,恢复时间为32 s。

Enhanced photoelectrocatalytic decomplexation of Ni-EDTA and simultaneous recovery of metallic nickel via TiO_(2)/Ni-Sb-SnO_(2) bifunctional photoanode and activated carbon fiber cathode

In order to enhance Ni-EDTA decomplexation and Ni recovery via photoelectrocatalytic (PEC)process,TiO_(2)/Ni-Sb-SnO_(2)bifunctional electrode was fabricated as the photoanode and activated carbon fiber (ACF) was introduced as the cathode.At a cell voltage of 3.5 V and initial solution pH of 6.3,the TiO_(2)/Ni-Sb-SnO_(2)bifunctional photoanode exhibited a synergetic effect on the decomplexation of Ni-EDTA with the pseudo-first-order rate constant of 0.01068 min^(-1)with 180 min by using stainless steel (SS) cathode,which was 1.5 and 2.4times higher than that of TiO_(2)photoanode and Ni-Sb-SnO_(2)anode,respectively.Moreover,both the efficiencies of Ni-EDTA decomplexation and Ni recovery were improved to 98%from 86%and 73%from 41%after replacing SS cathode with ACF cathode,respectively.Influencing factors on Ni-EDTA decomplexation and Ni recovery were investigated and the efficiencies were favored at acidic condition,higher cell voltage and lower initial Ni-EDTA concentration.Ni-EDTA was mainly decomposed via·OH radicals which generated via the interaction of O_(3),H_(2)O_(2),and UV irradiation in the contrasted PEC system.Then,the liberated Ni^(2+)ions which liberated from Ni-EDTA decomplexation were eventually reduced to metallic Ni on the ACF cathode surface.Finally,the stability of the constructed PEC system on Ni-EDTA decomplexation and Ni recovery was exhibited.

TiO_(2)基制硫催化剂活性的影响因素探究

在硫磺回收过程中,低温催化反应指在催化剂作用下H_(2)S和SO_(2)转化成单质硫的过程,制硫催化剂主要是TiO_(2)基制硫催化剂,该类催化剂在长周期运行过程中会逐渐失活,造成制硫转化率降低。为了探究催化剂失活原因,本文通过BET(比表面积测试法)、SEM(扫描电子显微镜)以及使用两个周期的制硫催化剂表征分析结果等方式,对使用前后催化剂的结构进行对比,确定了造成制硫催化剂失活的主要因素,在生产中实现对催化剂的有效保护,保证装置的长周期平稳运行。

废弃SCR脱硝催化剂与废NaCl盐焙烧回收催化剂中的钛、钒、钨

通过废弃选择性催化还原(SCR)脱硝催化剂与废NaCl盐焙烧,可以将催化剂中的钨和钒与钛分离。在最佳浸出条件下(焙烧温度900℃,焙烧时间3 h,废盐与废催化剂的质量比为0.5,浸出温度80℃,反应时间60 min),钨和钒的浸出率分别达到84.63%和66.42%,同时钛的损失率仅为1.3%。废NaCl盐和焙烧温度可以促进锐钛矿型TiO_(2)转化为金红石型TiO_(2),反应后得到了金红石型TiO_(2)。金红石型TiO_(2)中的钛的价态为四价,晶格氧和化学吸附氧分别占57.26%和42.74%。该方法可以同时解决2种废弃物的处置问题。

PVDF/TiO_(2)薄膜的制备及其光热催化性能研究

文章制备聚偏氟乙烯/二氧化钛(PVDF/TiO_(2))薄膜,对薄膜的断面形貌与孔隙结构、光热催化性能及可循环性能进行研究,探索吸附及消除水资源有机物污染的治理方式。结果表明:TiO_(2)纳米粒子质量分数为2.5%,薄膜C在pH值为6.5、温度20~30℃条件下,亚甲基蓝降解率较高,光热催化降解效果最优。在自然水环境、海水环境、工业废水环境下,薄膜C的光热催化降解率均可以达到90%以上。薄膜C经过6次连续循环使用,对亚甲基蓝的降解率仍能保证在90%,其回收效果及可循环利用性能较好。