V2O5-CeO2/TiO2催化剂上低温氨选择性催化还原NO的性能

考察了V2O5-CeO2/TiO2催化剂中V、Ce活性组分的担载量和焙烧温度对催化剂低温催化还原NO活性的影响及其在单独SO2、H2O和两者共存气氛下的抗毒化性能。结果表明,焙烧温度400℃下制备的5V30Ce/TiO2催化剂具有良好的低温催化还原NO活性,空速为10000h-1,165℃时NO转化率达99.2%;500℃以下低焙烧温度时,添加的Ce不与V相互作用,在催化剂表面主要以CeO2形式存在,有利于增大催化剂比表面积,增强V2O5在催化剂上的分散度,提高催化活性。而在500℃以上较高焙烧温度下,Ce与V会形成CeVO4,对活性提高不利。催化剂具有良好的低温抗水中毒性能,但受SO2毒化作用明显,其在SO2、H2O共存气氛下中毒程度较单独SO2下浅。     

V_2O_5/C催化乙二醛氧化为乙醛酸的研究

选用V2O5作为催化剂,活性炭为载体,偏钒酸铵的草酸溶液为浸渍前驱体,采用等体积浸渍法制备了V2O5/C催化剂,将其应用于乙二醛的液相氧化.并对反应液用液相色谱进行了定性,在确定了催化体系中氧化产物的基础上,考察了V2O5含量和焙烧温度对催化剂催化性能的影响,利用XRD和TEM等手段对催化剂进行了表征.结果显示,V2O5含量较低时(w(V2O5)<3%),催化剂的活性组分分散度较高,乙二醛转化率和乙醛酸的选择性都随着V2O5的含量提高而逐渐增加;当负载量为3%时,催化效果最佳,乙二醛转化率和乙醛酸的选择性分别达到16.16%和76.75%;当V2O5的质量分数大于3%时,V2O5颗粒在活性炭表面发生明显聚集,V2O5开始出现多层吸附,导致乙二醛转化率和乙醛酸得率略有下降.而焙烧温度是制备负载型催化剂的一个重要影响因素.焙烧温度的作用不仅在于使活性组分的前驱体充分分解,同时也影响着活性组分的分散状态.我们考察了经不同温度焙烧后的催化剂的活性,从表征结果来看,在473K以下焙烧时,可能活性组分的前驱体未能充分分解,活性中心数目较少,反应效果较差;当V2O5负载量为3%、焙烧温度为573K时,催化剂具有较高的催化活...     

催化剂Zn-Sr-SiO2的制备及其 对甲醇脱氢制备无水甲醛的催化性能

采用溶胶凝胶法制备了催化剂Zn-Sr-SiO₂，其结构经SEM、 XRD、 N₂吸附/脱附、NH₃-TPD和CO₂-TPD表征。利用固定床反应器评价了Zn Sr SiO2对甲醇脱氢制备无水甲醛反应的催化性能。研究了焙烧温度，Zn负载量，Zn/Sr摩尔比，载气流量，质量空速等因素对催化性能的影响，以及催化剂的寿命、失活与再生。结果表明：制备催化剂的最佳条件为焙烧温度700 ℃， Zn负载量为15%， Zn/Sr为5/1。反应温度为600 ℃，甲醇的质量空速为4.47 h^-1时，甲醇的转化率为25.35%，甲醛的选择性为91.98%。催化剂寿命为33 h。再生后，催化剂的中强碱性位得到了再生。     

同时脱除烟气中硫和硝的V2O5/AC催化剂研究

通过在固定床微反应器上对同时脱硫脱硝催化剂的研究，发现将V2O5担载在活性焦(AC)上制得的V2O5/AC催化剂可在200 ℃同时脱除烟气中的SO2和NO，其活性明显高于纯AC。V2O5/AC催化剂的脱硫脱硝活性与催化剂中钒的质量分数有关，随着V2O5质量分数从0.5%增至9%，硫容从3%增加到12%，脱硝率在V2O5质量分数为0.5%到3%时脱硝率稳定在60%左右，继续增加V2O5质量分数，脱硝率降低。程序升温脱附 (TPD) 和红外光谱 (FTIR) 表征结果显示在脱硫脱硝过程中，催化剂表面有H2SO4, 铵盐和VOSO4生成, VOSO4的质量分数随催化剂中V2O5质量分数的提高而升高。使用后的催化剂可通过5%NH3在300 ℃再生，再生后催化剂的脱硝活性明显增加，NO转化率从新鲜样的67%提高到接近100%，对SO2的吸附也比新鲜样有所增加。     

新工艺制备固体超强酸SO42-/SnO2-Nb2O5及其催化松油醇酯化

采用新工艺制备固体超强酸SO42-/SnO2-Nb2O5,将其应用于松油酯化反应。催化剂最佳制备条件:Nb2O5引入(SnO2质量分数)3%,浸渍硫酸浓度1.5 mol/L,500℃焙烧3.0 h;最佳反应条件:n(松油醇):n(乙酸酐)=1.0:1.2,催化剂用量(松油醇质量分数)5%,50℃反应3.0 h;并采用FT-IR、XRD、TG-DTA对催化剂进行表征。结果表明:催化剂可使得松油醇转化率达94.3%,乙酸松油酯选择性达86.2%,新工艺制备的催化剂较沉淀法和sol-gel法的活性高。     

固相球磨法制备丙烷氧化脱氢V2O5/NiO催化剂

以不同温度焙烧制备的NiO和V2O5为前驱物,采用固相球磨法制备了V2O5/NiO催化剂,考察了前驱物的焙烧温度对该催化剂丙烷氧化脱氢制丙烯反应性能的影响,并采用x射线衍射、N2物理吸附、电感耦合等离子体原子发射光谱、透射电子显微镜、H2程序升温还原和x射线光电子能谱等对催化剂进行了表征.结果表明,固相球磨法制备的V2O5/NiO催化剂表现出较好的丙烷氧化脱氢制丙烯催化性能,当以400℃焙烧的氧化物为前驱体时,V2O5/NiO催化剂表面含有较多的未完全还原氧物种Oδ-,因而表现出了较高的丙烯选择性.在475℃反应时,丙烷转化率可达20.1%,丙烯选择性达到71.2%.     

V_2O_5-CeO_2/SBA-15催化剂的制备及氯苯催化燃烧的性能研究

以介孔分子筛SBA-15为载体,采用等体积浸渍法分别制备了不同V负载量(4%～15%(质量分数))的V2O5/SBA-15及经过铈掺杂后的V2O5-CeO2/SBA-15催化剂,考察了催化剂对氯苯的催化燃烧性能,用XRD,UV-vis,SEM和TEM对催化剂进行了表征。活性评价结果表明,当V质量分数在10%时的V2O5/SBA-15催化剂对氯苯催化燃烧性能最好,在掺杂10%的稀土Ce后,催化燃烧氯苯的活性得到明显提高。表征结果表明,V2O5和CeO2均分散在SBA-15的孔道骨架上,没有破坏SBA-15的中孔结构。     

植物还原法制备负载型金纳米催化剂催化乙醇选择氧化反应

采用侧柏叶提取液还原氯金酸制备负载型金纳米催化剂,通过乙醇选择氧化反应,筛选出催化性能较好的TiO2载体。以TiO2载体为载体,考察了Au负载量、焙烧温度、催化剂用量、碳酸氢钠添加量及催化剂反应条件(时间、温度、压力)等因素对乙醇选择氧化反应的影响。结果表明,1.5%Au/TiO2催化剂(Au负载量为1.5%,质量分率,下同)催化乙醇选择氧化反应性能最佳,产物为乙醛、乙酸乙酯和缩醛,0.5%碳酸氢钠添加剂可抑制缩醛的生成,并可显著提高乙醇转化率和乙酸乙酯选择性。通过优化催化反应条件(1.5%Au/TiO2催化剂焙烧温度为400℃、用量为0.4 g、反应温度为100℃、氧气压力为3 MPa、反应时间为3 h时),乙醇转化率为47.9%,乙酸乙酯选择性为89.1%。     

活性炭负载磷钨杂多酸催化合成异丁醛乙二醇缩醛

研究了负载型催化剂H3 PW12 O40/C催化合成异丁醛乙二醇缩醛的催化行为.结果表明,该催化剂在异丁醛和乙二醇的缩合反应中表现出较高的催化活性.经纯化后,异丁醛乙二醇缩醛的最终收率可达73.4％,在相同条件下催化活性优于纯H3 PW12 O40.     

甲醇与乙醇一步合成异丁醛用CuO-ZnO/Al2O3催化剂

在ＣｕＯ－ＺｎＯ／Ａｌ２Ｏ３催化剂上，甲醇与乙醇在常压和２１０￣３６０℃温度下一步反应合成异丁醛。利用正交设计方法，研究了ＣｕＯ－ＺｎＯ／Ａｌ２Ｏ３体系催化剂组成和制备条件等因素对催化剂催化性能的影响。结果表明，催化剂中ＣｕＯ含量对催化剂的催化活性影响最大，而ＺｎＯ含量则主要影响催化剂对异丁醛的选择性。催化剂制备条件，如沉淀温度、陈化时间等，也不同程度也影响催化剂的催化性能。ＸＲＤ和ＢＥＴ表征结果     

NiO/LaMnO3催化剂用于乙醇水蒸气重整反应

采用柠檬酸络合-浸渍法制备了NiO/LaMnO3钙钛矿型复合氧化物催化剂并将其应用于乙醇水蒸汽重整制氢反应, 考察了NiO含量、焙烧温度对催化剂性能的影响, 采用XRD、TPR和热分析等手段对催化剂进行了表征. 结果表明, 该催化剂具有高活性、高选择性和良好的稳定性. 催化剂中的NiO含量和焙烧温度对催化性能有显著影响. 在原料气体积组成为20%(体积分数, φ) C2H5OH 和水以及80%(φ)N2, 其中水醇摩尔比为3:1, 空速为80000 mL·h-1·g-1 cat, 反应温度为400 ℃时, 15%(质量分数, w)的NiO/LaMnO3上, 乙醇转化率接近100%. 关联催化剂活性和TPR及XRD实验结果, 发现催化剂的高活性源于由催化剂前驱体中进入钙钛矿型复合氧化物晶格中的镍离子被还原所得的金属镍.     

Vapour phase synthesis of isobutyraldehyde from methanol and ethanol over mixed oxide supported vanadium oxide catalysts

The vapour phase synthesis of isobutyraldehyde from methanol and ethanol in one step was investigated over titania-silica, titania-alumina, titania-zirconia, titania-silica-zirconia, and magnesia supported vanadium oxide catalysts at 623 K and under normal atmospheric pressure. Among various catalysts the titania-silica binary oxide supported vanadia provided higher yields than the other single or mixed oxide supported catalysts. The high conversion and product selectivity of V₂O₅/TiO₂-SiO₂ catalyst (20 wt% V₂O₅) was related to the better dispersion of vanadium oxide over titania-silica mixed oxide support in addition to other acid-base and redox characteristics. A reaction path for the formation of isobutyraldehyde from methanol and ethanol mixtures over these catalysts was described.     

Simultaneous removal of ethanol, acetaldehyde and nitrogen oxides over V-Pd/γ-Al_2O_3-TiO_2 catalyst

V-Pd/γ-Al2O3-TiO2 catalysts with different vanadium contents were prepared by a combined sol-gel and impregnation method. X-ray diffraction (XRD), N2 adsorption-desorption (BET), X-ray photoelectron spectroscopy (XPS) and catalytic removal of ethanol, acetaldehyde and nitrogen oxides at low temperature (<300 ?C) were used to assess the properties of the catalysts. The results showed that the sample with 1wt% vanadium exhibited an excellent catalytic performance for simultaneous removal of ethanol, acetaldehyde and nitrogen oxides. The conversions of ethanol, acetaldehyde and nitrogen oxides at 250 ?C were 100%, 74.4% and 98.7%, respectively. V-Pd/γ-Al2O3-TiO2 catalyst with 1 wt% vanadium showed the largest surface area and higher dispersion of vanadium oxide on the catalyst surface, and possessed a larger mole fraction of V4+ species and unique PdO species on the surface, which can be attributed to the strong synergistic effect among palladium, vanadium and the carriers. The higher activity of V-Pd/γ-Al2O3-TiO2 catalyst is related to the V4+ and Pd2+ species on the surface, which might be favorable for the formation of active sites.     

添加钒对Pd/Al2O3-TiO2 催化剂上醇醛催化氧化性能及表面特性的影响

采用浸渍法分别制备了Pd/Al₂O₃-TiO₂、V/Al₂O₃-TiO₂和不同钒含量的V-Pd/Al₂O₃-TiO₂催化剂,并对乙醇、乙醛的完全催化氧化性能进行了测试。结果表明,添加适量的钒组分(1%~3%)能够有效地提高催化剂的深度氧化活性。采用XRD、NH₃-TPD、N₂吸附等技术分析研究催化剂的表面特性与催化活性之间的关系,发现Pd/Al₂O₃-TiO₂催化剂添加适量钒组分后,调变了催化剂的表面酸性、比表面积和孔容,使得V组分和Pd组分与载体之间产生较强的相互作用,双金属组分的协同效应提高了催化剂对乙醇、乙醛的深度氧化活性。     

Ni-Fe/La2O2CO3催化乙醇水蒸气重整制氢的研究

采用La2(CO3)3空气焙烧法制备了La2O2CO3载体、采用浸渍法制备了Ni,Fe不同比例的Ni-Fe双金属催化剂及Ni/La2O2CO3,Fe/La2 O2 CO3催化剂,考察了各催化剂从300～700℃催化乙醇水蒸气重整反应的性能,并用BET,XRD,TPR等技术对催化剂进行表征。结果表明,相对单一金属催化剂,Ni-Fe双金属催化剂均表现出更高的活性,这可能是因为高分散的Ni,Fe和LaFeyNi1-yO3的共存作用。其中Ni含量为10%,Fe含量为5%时的Ni-Fe/La2O2CO3表现出最高的活性,400℃时乙醇的转化率为100%,H2的选择性最高达到94.1%,而CO的选择性则低至1.2%。     

Selective oxidation of propane to acrylic acid over mixed metal oxide catalysts

The effects of metal atomic ratio, water content, oxygen content, and calcination temperature on the catalytic performances of MoVTeNbO mixed oxide catalyst system for the selective oxidation of propane to acrylic acid have been investigated and discussed. Among the catalysts studied, it was found that the MoVTeNbO catalyst calcined at a temperature of 600 ℃ showed the best performance in terms of propane conversion and selectivity for acrylic acid under an atmosphere of nitrogen. An effective MoVTeNbO oxide catalyst for propane selective oxidation to acrylic acid was obtained with a combination of a preferred metal atomic ratio （Mo1V0.31Te0.23Nb0.12）. The optimum reaction condition for the selective oxidation of propane was the molar ratio of C3H8 ：O2 ： H2O ： N2 = 4.4： 12.8 ： 15.3 ： 36.9. Under such conditions, the conversion of propane and the maximum yield of acrylic acid reached about 50% and 21%, respectively.     

V-Mo-O催化剂的制备及催化甲苯合成苯甲醛的研究

在低温液相条件下,催化氧化甲苯合成苯甲醛是具有竞争力的苯甲醛合成路线。采用溶胶凝胶法制备了V-Mo-O催化剂,评估了在液相低温条件下选择性氧化甲苯的催化性能。研究表明,钒钼配比和焙烧温度对催化剂性能影响显著,适宜的钒钼物质量的配比为6:7,适宜的焙烧温度为500℃。扫描电镜实验表明,该条件下合成的催化剂呈棒状结构,直径约700nm,长度约6µm。X射线衍射观测到催化剂中拥有Mo6V9O40和MoO3物相。X光电子能谱表征,棒状催化剂外表面覆盖一层主含MoO3物种的薄层,这种不同氧化态钼物种的分层组装可能有助于氧物种的传递,提高了其催化性能。当反应温度为80℃,氧化剂为双氧水,溶剂为冰乙酸时,甲苯在该催化剂上的转化率为38.9%,苯甲醛的选择性为69.7%。     

NO-NH_3-O_2 reaction catalyzed by V_2O_5/AC at low temperatures——Effects of SO_2, V_2O_5 loading and reaction temperature

The effects of SO2, V2O5 loading and reaction temperature on the activity of activated carbon supported vanadium oxide catalyst have been studied for the reduction of NO with NH3 at low temperatures (150-250℃). It is found that SO2 significantly promotes the catalyst activity. Both V2O5 loading and reaction temperature are vital to the promoting effect of SO2. The catalysts with V2O5 loadings of 1 -5 weight percent have a positive effect on the promotion of SO2, while the catalysts with V2O5 loadings of above 7 weight percent have not such an effect or show a negative effect. At lower temperatures (<180℃) SO2 poisons the catalyst but at higher temperatures promotes it. The reason of the SO2 promotion was also discussed; it may results from the formation of SO42- on the catalyst surface, which increases the surface acidity and hence the catalytic activity.     

Preparation of Highly Active Pt-K/γ-AI203 Catalyst for 0-Phenylphenol Synthesis from 0-Cyclohexenyl-cyclohexanone Dehydrogenation

0.5%Pt-K/y-Al2O3 catalysts for the synthesis of 0-phenylphenol(OPP) from 0-cyclohexenyl-cyciohexanone (dimer) dehydrogenation were prepared by means of a two subsequent impregnation method.The effects of catalyst preparation parameters,such as K promoters,calcination,and reduction conditions,were investigated.The results showed that the addition of K2SO4 to Pt/y-Al2O3 catalyst notably promoted the selectivity of OPP,and its optimum content was found to be 6% in mass fraction.The higher activity was obtained when Pt/y-Al2O3 catalyst was calcined in nitrogen atmosphere at 400-500℃ and then reduced at the same temperature for 3 h in hydrogen atmosphere.The conversion of the dimer and the selectivity of OPP were always above 99% and 90%,respectively,over 0.5%Pt-6% K2SO4/γ-Al2O3 catalyst during the pilot scale test of 8000 h.     

Gas Phase Selective Catalytic Oxidation of Toluene to Benzaldehyde on V2O5-Ag2O／η-Al2O3 Catalyst

Gas phase selective catalytic oxidation of toluene to benzaldehyde was studied on V2O5-Ag2O/η-Al2O3 catalyst prepared by impregnation. The catalyst was characterized by XRD, XPS, TEM,and FT-IR. The catalytic results showed that toluene conversion and selectivity for benzaldehyde on catalyst sample No.4 (V/(V Ag)=0.68) was higher than other catalysts with different V/Ag ratios. This was attributed to the higher surface area, larger pore volume and pore diameter of the catalyst sample No.4 than the other catalysts. The XRD patterns recorded from the catalyst before and after the oxidation reaction revealed that the new phases were developed, and this suggested that silver had entered the vanadium lattice. XPS results showed that the vanadium on the surface of No.4 and No.5 sample was more than that in the bulk, thus forming a vanadium rich layer on the surface. It was noted that when the catalyst was doped by potassium promoter, the toluene conversion and selectivity for benzalde hydewere higher than those on the undoped catalyst. This was attributed to the disordered structure of V2O5 lattice of the K-doped catalyst and a better interfacial contact between the particles.