Fe-MnOx-CeO2/ZrO2低温催化还原NO性能研究

以纳米ZrO2为载体,用浸渍法制备出Fe-MnOx-CeO2/ZrO2催化剂,考察了活性组分配比和助剂负载量对催化剂低温NH3选择性催化还原NO活性的影响,并对催化剂进行了XRD、SEM、EDS和BET表征;探讨了温度、H2O和SO2对Fe-MnOx-CeO2/ZrO2催化剂低温下NH3选择性催化还原NO的影响,结果表明,无SO2和H2O条件下,8%Fe-10%MnOx-CeO2/ZrO2催化剂具有良好的催化活性和稳定性.120℃时,催化剂的脱硝效率为85.23%,当温度升至180℃时,脱硝效率可达到92.0%.SO2和H2O共存条件下,催化剂易失活,采用傅立叶变换红外光谱对各反应阶段的催化剂进行了表征,对其失活机制进行深入研究,结果表明,催化剂失活的主要原因是催化剂表面硫酸铵盐的沉积和催化剂本身活性成分的硫酸盐化.     

贵金属/BaO催化剂上NOx的储存-还原

运用模拟配气方法考察了贵金属(Noble Metals,NM)/BaO催化剂的氮氧化物(NO_x)储存-还原性能. 采用热重-差热分析(TG-DTA)法对催化剂的NO_x吸附-脱附性能进行了研究. 结果表明:NO₂比NO更易于在催化剂上储存,O₂的存在极大地促进了NO_x储存反应的进行. 温度对催化剂上的NO_x储存行为有较大影响,在φ(O₂)为16%,φ(NO)为5×10-4的氧化气氛下,NO_x在NM/BaO上储存的适宜温度为300 ℃. 300 ℃下催化剂的NO_x吸附量可达15 mg/g,当温度升到600 ℃时,催化剂上的NO_x能够完全脱附. 使用H₂在催化剂上进行NO_x还原过程中,当φ(H₂)为1%或3%时,还原反应速率随温度的升高而变化;φ(H₂)为5%时,还原反应速率几乎不受温度影响.      

Combination of biodiesel-ethanol-diesel fuel blend and SCR catalyst assembly to reduce emissions from a heavy-duty diesel engine

In this study, the efforts to reduce NOx and particulate matter （PM） emissions from a diesel engine using both ethanol-selective catalytic reduction （SCR） of NOx over an Ag/Al2O3 catalyst and a biodiesel-ethanol-diesel fuel blend （BE-diesel） on an engine bench test are discussed. Compared with diesel fuel, use of BE-diesel increased PM emissions by 14% due to the increase in the soluble organic fraction （SOF） of PM, but it greatly reduced the Bosch smoke number by 60%-80% according to the results from 13-mode test of European Stationary Cycle （ESC） test. The SCR catalyst was effective in NOx reduction by ethanol, and the NOx conversion was approximately 73%. Total hydrocarbons （THC） and CO emissions increased significantly during the SCR of NOx process. Two diesel oxidation catalyst （DOC） assemblies were used after Ag/Al2O3 converter to remove CO and HC. Different oxidation catalyst showed opposite effect on PM emission. The PM composition analysis revealed that the net effect of oxidation catalyst on total PM was an integrative effect on SOF reduction and sulfate formation of PM. The engine bench test results indicated that the combination of BE-diesel and a SCR catalyst assembly could provide benefits for NOx and PM emissions control even without using diesel particle filters （DPFs）.     

锰前驱体对MnO_x/TiO_2催化剂低温选择性催化还原NO_x影响

以醋酸锰和硝酸锰为前趋体通过浸渍法制备了MA和MN两种系列的MnOx/TiO2催化剂,结合BET、XRD、TPR及FT-IR等手段对催化剂进行了表征,并进行了比较,同时对两种系列的催化剂进行了选择催化还原脱硝的活性测试。结果表明,MA和MN均具有良好的低温催化活性,脱销效率随温度的变化趋势基本相同,在80℃时已经达到80%的脱硝效率;随着温度的升高,在200℃时效率上升至接近100%。通过对催化剂性能测试比较表明,锰的含量对于催化剂的活性有一定的影响。总体上看,MN具有更好的活性,脱销效率较高,并且其活动的窗口也是相对更宽,可能是因为以硝酸锰为前躯体制的的催化剂中MnO2的含量相对较多,即两类前驱体在制备过程中与载体之间的相互作用不同,导致最终催化剂表面活性组分MnOX结构和价态的不同,从而影响催化剂的低温活性。     

臭氧液相氧化同时脱硫脱硝实验研究

在自制的鼓泡反应器上对臭氧(O_3)液相氧化分别脱硫脱硝技术进行了实验研究.结果表明,液相中O_3对NO能够有效氧化,SO_2的存在对NO的脱除具有一定的负面影响,而pH值对NO的脱除率影响较小.[O_3]/[NO]=1.1时,NO脱除率可达到89.6%.pH在3～11范围内,NO脱除率达80%以上.温度在20～65℃范围内,NO脱除率不发生明显变化.结合尾部洗涤装置后,可有效脱除SO_2和NOx,脱硫效率几乎达到100%,在[O_3]/[NO]=1.1时,可获得84.2%的脱硝效率.     

纳米Fe3O4/CeO2-H2O2非均相类Fenton体系对3,4-二氯三氟甲苯的降解

以浸渍法制备的新型纳米Fe3O4/Ce O2为催化剂,3,4-二氯三氟甲苯(3,4-DCBTE)为目标污染物,在Fe3O4/Ce O2-H2O2非均相类Fenton体系中对目标污染物的降解进行研究,考察催化剂的催化效果和温度、p H、H2O2投加量等因素对催化剂催化效果的影响.结果表明,以纳米Fe3O4/Ce O2作为催化剂的非均相类Fenton体系对3,4-二氯三氟甲苯的处理效果极佳;随着温度的升高,纳米Fe3O4/Ce O2的催化效果不断提高;在偏酸性环境中,p H越低催化效果越好,p H=2时反应去除效率可达96.67%;随着H2O2投加量的增加,3,4-二氯三氟甲苯的降解效率先提高后降低,投加量为15 mg·L-1时去除效果最好可达99.47%;随着催化剂投加量的增加,同样出现了处理效果先升高后降低的现象,投加量为0.5 g·L-1时催化效果最好可达99.64%.在以纳米Fe3O4/Ce O2为催化剂的非均相类Fenton体系中,3,4-二氯三氟甲苯的降解符合一级反应动力学,反应所需活化能较低只需30.26 k J·mol-1.     

V2O5/TiO2与MoO3/TiO2催化剂表面结构形貌及其对催化氧化碳烟活性的影响

为研究纳米级V₂O₅与MoO₃催化剂表面结构对其催化氧化碳烟活性的影响,以TiO₂为载体,采用等体积浸渍法制备了不同负载率(5%、10%、20%、40%)的V₂O₅/TiO₂与MoO₃/TiO₂催化剂,通过扫描电镜(SEM)、X射线衍射仪(XRD)对比研究了2种催化剂在TiO₂载体上的分散状态及物相结构.以Printex-U碳黑为试验用碳烟,采用热重分析仪对V₂O₅与MoO₃催化剂催化碳烟氧化的活性进行了比较.结果表明:V₂O₅与MoO₃在TiO₂载体上均存在一个单层分散饱和阈值,分别为V20(负载率为20%,下同)、Mo10,在该阈值前后活性组分在载体上分别以单层分散状态和明显的晶态存在.对于V₂O₅催化剂,其最佳催化活性出现在负载率接近单层分散饱和阈值时,与无催化状态相比,T_i(起燃温度)、T_p(最大失重率温度)以及T_f(燃尽温度)分别下降了69.1、46.0、23.0 ℃,有明显的阈值效应.而对于MoO₃催化剂,因其自身低熔点性而表现出良好的表面迁移能力,再加上α-MoO₃晶体特有的层状结构,使其可释放出更多的晶格氧,随着负载率的增加,该催化剂催化氧化碳烟活性持续增加,并且未观察到明显的阈值效应.研究显示,在相同负载率下,MoO₃催化剂催化氧化碳烟活性均高于V₂O₅催化剂.      

Na2SO4中毒SCR催化剂对SO3生成特性的影响

为研究Na₂SO₄中毒SCR催化剂（V₂O₅-WO₃/TiO₂催化剂）对SO₃生成特性的影响,采用湿式浸渍法制备w（Na）为3%的Na₂SO₄中毒SCR催化剂,并通过N₂物理吸附/脱附、XRD（X射线衍射）技术、SEM（扫描电镜）、XPS（X射线光电子能谱）分析技术对催化剂的物理化学特性进行表征.结果表明:①随着反应温度的升高,所有催化剂上的SO₃生成率逐渐增加.当温度升至490℃时,SCR催化剂上的SO₃生成率为0.85%,而3% Na₂SO₄中毒SCR催化剂上的SO₃生成率高达1.36%.SO₄2-的存在导致V-O-S增多,从而促进SO₃的生成.②随入口ρ（SO₂）的增加,SO₃生成率呈下降的趋势.当入口ρ（SO₂）为1 000 mg/m3时,3% Na₂SO₄中毒SCR催化剂上的SO₃生成率为1.02%,而SCR催化剂上仅为0.60%.ρ（SO₂）对SO₃生成率的影响主要依赖于温度和催化剂活性位点数等.③N₂物理吸附/脱附、XRD和SEM表征结果表明,与SCR催化剂相比,Na₂SO₄中毒SCR催化剂表面有Na₂SO₄的积聚,出现了裂纹和大孔隙,催化剂的比表面积和孔容下降,这些变化均不利于催化剂的催化性能;XPS结果表明,Na₂SO₄的加入提高了表面化学吸附氧含量,降低了活性组分中w（V4+）/w（V5+）的值.研究显示,相比于SCR催化剂,Na₂SO₄中毒SCR催化剂上的SO₃生成率大幅增加.      

Elimination of formaldehyde over Cu-Al2O3 catalyst at room temperature

Catalytic elimination of formaldehyde (HCHO) was investigated over Cu-Al2O3 catalyst at room temperature. The results indicated that no oxidation of HCHO into CO2 occurs at room temperature, but the adsorption of HCHO occurs on the catalyst surface.With the increase of gas hourly space velocity(GHSV) and inlet HCHO concentration, the time to reach saturation was shortened proportionally. The results of the in situ DRIFTS, Density functional theory calculations and temperature programmed desorption(TPD) showed that HCHO was completely oxidized into HCOOH over Cu-Al2O3 at room temperature. With increasing the temperature in a flow of helium, HCOOH was completely decomposed into CO2 over the catalyst surface, and the deactivated Cu-Al2O3 is regenerated at the same time. In addition, although Cu had no obvious influence on the adsorption of HCHO on Al2O3, Cu dramatically lowered the decomposition temperature of HCOOH into CO2. It was shown that Cu-Al2O3 catalyst had a good ability for the removal of HCHO, and appeared to be promising for its application in destroying HCHO at room temperature.     

SCR气氛下Ce-W/TiO2催化剂的脱硝协同脱汞特性

在固定床反应器上研究了反应温度和烟气组分对Ce-W/TiO₂（物质的量比Ce：W=2：1）催化剂脱硝协同脱汞活性的影响.结果表明：反应温度对该催化剂的脱硝脱汞效率影响显著,在280~400℃温度区间,脱硝效率随温度升高而升高,而脱汞效率在温度为280℃与360℃的条件下较高,360℃时兼具最好的脱硝与脱汞效率.在SCR气氛中,HCl对Hg⁰的氧化脱除有极大的促进作用,低浓度的HCl也有利于脱硝效率的提高,但HCl浓度过高对NO的脱除有抑制作用;SO₂的存在对脱硝过程可起到促进作用,对Hg⁰的氧化有抑制作用.利用BET,XRD,SEM,TPD,XRF,NH3-TPD等分析手段对反应前后催化剂进行表征,结果表明：Ce-W/TiO₂无微孔结构,活性组分CeO₂和WO₃以高度分散的形式分布于载体表面.280℃条件下部分Hg以HgCl₂的形式吸附于反应后催化剂表面,随着反应温度的升高催化剂表面吸附态的汞急剧降低.SCR气氛中的HCl与SO₂会影响催化剂表面酸性,同时增加Cl和S元素含量,进而影响该催化剂的脱硝与脱汞效率.     

以MnOx/TiO2作为催化剂的低温SCR反应过程中还原剂NH3的作用

研究了在以MnOx/TiO2作为催化剂的低温SCR反应过程中,还原剂NH3所起的作用.当系统中NH3浓度较低时,增加气相中NH3的浓度可以大幅度提高NO的去除率.但当系统中NH3浓度较高时,NO去除率基本不随NH3浓度变化而变化.并且瞬态研究中,NH3对NO去除率的影响较为复杂.为了探明NH3在SCR反应中的作用,用原位傅立叶红外检测了各个反应历程中NH3在催化剂表面形成的基团变化及其活性特征.结果表明,在SCR反应过程中,在催化剂表面形成的配位态的NH3是参与反应的主要物质.并且在催化剂表面,此种NH3会与NO生成的硝酸盐形成竞争吸附,当催化剂活性点首先被硝酸盐占领时,将会影响配位态NH3的生成,从而在一定程度上降低了NO的转化率.     

Ag/Cu3(BTC)2复合催化剂的制备及其NH3-SCR催化性能

采用紫外还原的方法成功制备出Cu₃（BTC）₂（均苯三甲酸合铜）负载贵金属Ag纳米颗粒的Ag/Cu₃（BTC）₂复合催化剂,并用于氨法脱硝反应.应用X射线衍射（XRD）、透射电子显微镜（TEM）、BET测试等手段对催化剂的物理化学性能进行了表征.结果发现Ag纳米颗粒以球状结构高度均匀分散在Cu₃（BTC）₂骨架结构的表面.负载Ag纳米颗粒和Cu-MOF的协同作用,提高了Ag/Cu₃（BTC）₂催化剂的脱硝效率,负载量为15wt%的催化剂表现出最优脱硝效率,在220～260℃达到100%的NO转化率.同时,利用in-situ FTIR技术对NH₃-SCR的反应机理进行了探究.     

TiO2/PS/Fe3O4 光催化剂的低温制备及其光催化和磁回收性能

以聚苯乙烯(PS)包覆油酸修饰过的纳米Fe3O4为磁核,在低温(90℃)、中性(pH=7左右)条件下,制备了以PS为惰性隔离层的磁载TiO2光催化剂.用X射线衍射仪(XRD)、透射电子显微镜(TEM)、傅里叶红外分光光度计(FT-IR)、振动样品磁强计(VSM)对催化剂的物相组成、形貌、表面性质、磁学性质进行了表征.以苯酚为模拟污染物,考察了其光催化活性,以自制的磁回收装置,考察其回收特性.结果表明,低温制备的TiO2为锐钛矿结构,平均粒径为2～5 nm,催化剂TiO2/PS/Fe3O4[其中物质的量比为n(TiO2)∶n(St)∶n(Fe3O4)=60∶2.5∶1]具有结构完整的壳/壳/核结构,TiO2在PS/Fe3O4表面负载牢固;光催化降解苯酚遵循一级反应动力学方程,TiO2/PS/Fe3O4[n(TiO2)∶n(St)∶n(Fe3O4)=60∶2.5∶1]的反应速率常数K=0.025 8,与纯TiO2的活性接近(K=0.026 2);循环使用5次后,反应速率常数仅降低0.003 4.所制催化剂具有较强的磁感应强度,平均回收率可达到92%以上.该低温水解法制备的磁载TiO2光催化剂具有良好的应用前景.     

Cu/Al2O3低温催化氧化H2S研究

高效低成本的催化剂是低温催化氧化脱除硫化氢（H₂S）的研究重点,采用浸渍法研制了Cu/Al₂O₃催化剂,利用N₂物理吸附、XRD（X射线衍射分析）、XPS（光电子能谱）、FT-IR（傅里叶变换红外光谱）等表征手段了解催化剂的表面结构和物相结构,并开展不同温度、相对湿度、Cu负载量条件下的H₂S动态脱附以考察催化剂脱硫性能.结果表明:①催化剂是一种典型的介孔材料,且CuO和Cu₂O高度分散在催化剂表面.②FT-IR结果表明,催化剂在H₂S催化氧化过程中表面Cu_xO和表面结合水中的羟基均参与反应,且有SO₄2-的生成.③XRD、XPS结果表明,脱硫过程中有S单质和CuS的生成.④适宜的温度（50℃）和相对湿度（50%）会显著增强Cu基催化剂的脱硫性能.⑤负载量为3%的Cu基催化剂具有最佳的脱硫性能,穿透硫容量高达220.92 mg/g.研究显示,利用浸渍法可以合成低温催化氧化H₂S的高硫容Cu基催化剂.      

生物法废气脱硝研究

将城市生活污水处理厂活性污泥中的反硝化细菌培养挂膜到填料塔中,进行从模拟废气中脱除ＮＯｘ的效果性能实验研究,该生物膜填料塔能有效地脱除废气中的ＮＯｘ,ＮＯ２的去除率可达９９％以上,ＮＯ的去除率可达９０％左右。该法最适宜的温度为３０￣４５℃,进口ＮＯ浓度（５０￣５００ｍｇ／ｍ＾３）对其去除率几乎没有影响,随着废气流量的增加,ＮＯ的去除率逐步降低。     

Effect of MoO3 on vanadium based catalysts for the selective catalytic reduction of NOx with NH3 at low temperature

The selective catalytic reduction(SCR) activities of the MoO_3 doped V/WTi catalysts prepared by the incipient wetness impregnation method at low temperature were investigated.The results showed that the addition of MoO_3 could enhance the NO_ xconversion at low temperature and the best SCR activity was obtained when the dosage of MoO_3 reached5 wt.%. The NH3-TPD and DRIFTS experiments indicated that the addition of MoO_3 changed the type and number of acid sites on the surface of catalysts and reaction activities of acid sites were altered at the same time. The redox capacity and amount of active oxygen species got improved for V3Mo5/WTi catalyst, which could be confirmed by the H_2-TPR and transient response experiments. Water vapor inhibited the NO_xconversion at low temperature. Deposition of ammonium sulfate or bisulfate might be main reason for the loss of catalytic activity in the presence of SO_2 at low temperature. Choosing the suitable NH_3/NO ratio and elevation of reaction temperature both could weaken the influence of SO_2 on the SCR activity of the V3Mo5/WTi catalyst. Thermal treatment of the deactivated catalyst at350°C could get the low temperature activity recovered. The decrease of GHSV improved the de NO_x efficiency at low temperature and we speculated that the rational technological process and operation parameters could contribute to the application of this kind of catalysts in real industrial environment.     

Effect of Ce doping of TiO2 support on NH3-SCR activity over V2O5-WO3/CeO2-TiO2 catalyst

CeO2–TiO2composite supports with different Ce/Ti molar ratios were prepared by a homogeneous precipitation method, and V2O5–WO3/CeO2–TiO2catalysts for the selective catalytic reduction（SCR） of NOx with NH3 were prepared by an incipient-wetness impregnation method. These catalysts were characterized by means of BET, XRD, UV–Vis,Raman and XPS techniques. The results showed that the catalytic activity of V2O5–WO3/TiO2 was greatly enhanced by Ce doping（molar ratio of Ce/Ti = 1/10） in the TiO2 support.The catalysts that were predominantly anatase TiO2 showed better catalytic performance than the catalysts that were predominantly fluorite CeO2. The Ce additive could enhance the surface adsorbed oxygen and accelerate the SCR reaction. The effects of O2 concentration, ratio of NH3/NO, space velocity and SO2 on the catalytic activity were also investigated. The presence of oxygen played an important role in NO reduction. The optimal ratio of NH3/NO was 1/1 and the catalyst had good resistance to SO2 poisoning.     

钒和钨负载量对V2O5-WO3/TiO2表面形态及催化性能的影响

采用浸渍法制备了一系列不同钒和钨负载量的V₂O₅-WO₃/TiO₂催化剂样品,对样品NH₃选择性催化还原NO性能进行了评价,并用BET、XRD、XPS等手段对催化剂样品的表面形态进行了表征.研究发现,钒的负载量对催化剂的比表面积和催化活性有显著影响,当钒负载量从1％升高到8％时,催化剂比表面积下降了16 m²/g,最高活性温度降低了约100℃.钨起到稳定剂和助剂的双重作用,当钒负载量为1％时,钨负载量从0升高到6％,催化剂比表面积仅下降了3 m²/g,而活性温度窗口向高温和低温各拓宽了约50℃.研究表明钒和钨负载量都能影响催化剂表面的VO_x物种,但对催化剂的表面晶型没有明显影响.     

SO2对CoH-ZSM-5催化CH4还原NO催化性能的影响

研究了富氧条件下SO₂对CoH-ZSM-5上CH₄选择还原NO(CH₄-SCR)的影响,应用SO₂-TPSR,NO+(O₂)-TPD等方法研究了产生中毒的原因并定量研究了被毒化的活性位.反应在773 K进行时,加入体积分数78×10^-6SO₂,NO的转化率由72%逐渐降低并稳定在58%,提高反应温度至823 K,NO稳定转化率上升至62%.同时加入2.5     

NH3-SCR performance and the resistance to SO2 for Nb doped vanadium based catalyst at low temperatures

Niobium oxide as the promoter was doped in the V/WTi catalyst for the selective catalytic reduction(SCR)of NO.The results showed that the addition of Nb_2O_5could improve the SCR activity at low temperatures and the 6 wt.%additive was an appropriate dosage.The enhanced reaction activity of adsorbed ammonia species and the improved dispersion of vanadium oxide might be the reasons for the elevation of SCR activity at low temperatures.The resistances to SO_2of 3V6Nb/WTi catalyst at different temperatures were investigated.FTIR spectrum and TG-FTIR result indicated that the deposition of ammonium sulfate species was the main deactivation reason at low temperatures,which still exhibited the reactivity with NO above 200°C on the catalyst surface.There was a synergistic effect among NH_3,H_2O and SO_2that NH_3and H_2O both accelerated the catalyst deactivation in the presence of SO_2at 175°C.The thermal treatment at 400°C could regenerate the deactivated catalyst and get SCR activity recovered.The particle and monolith catalysts both kept stable NO_xconversion at 225°C with high concentration of H_2O and SO_2during the long time tests.