B2O3/TiO2-ZrO2催化环己酮肟气相Beckmann重排反应研究 Ⅲ. 反应条件的影响

 对B2O3／TiO2－ZrO2催化环己酮肟气相Beckmann重排制己内酰胺的反应条件进行了优化研究，系统考察了反应温度、原料空速、载气及其流速和稀释剂等对催化剂催化性能的影响．结果表明，当反应温度为300℃、环己酮肟的重时空速WHSV）为0．33h－1、氮气为载气（流速30ml／min）及乙腈为稀释剂时，B2O3／TiO2－ZrO2催化剂的催化性能最佳，连续反应6h，环己酮肟的转化率为100％，己内酰胺的选择性高达98．6％．     

生物质气经由二甲醚两步法制备低碳烯烃

制备出NiSAPO-34及NiSAPO-34／HZSM-5催化剂,考察了其对二甲醚催化转化制备低碳烯烃的性能．利用Cu／Zn／Al／HZSM-55u筛选出的2％NiSAPO—34／HZSM-5催化剂进行生物质气经由二甲醚两步法制备低碳烯烃的实验,结果表明在SAPO-34上添2H2％的Ni不改变其结构,但降低了酸中心数量,并生成了较强的酸中心．添加少量具有稳定酸中心的HZSM-5,该催化剂的活性提高到3h以上,反应进行2h获得了最高的低碳烯烃选择性为90．8％．当把该催化剂应用到两步催化转化过程的第二个反应器中,其高催化活性可达5h以上．当以低氢碳比生物质气（H2／CO／CO2／N2／CH4=41．5／26．9／14．2／14．6／2．89）作为原料时,经两步转化,低碳烯烃的收率达到84．6g／m^3syngas.     

Pd/HZSM-5涂层催化吸热燃料超临界裂解

超临界催化裂解反应是实现吸热燃料功能的关键途径.采用气体辅助涂层和化学镀方法在ψ3管内壁制备了Pd/HZSM-5双功能涂层催化剂.利用SEM、XRD和XPS等对涂层进行了表征,结果显示催化剂涂层表面平整,涂层厚度为12μm～16μm,催化剂粒径为1μm～5μm;Pd颗粒分散均匀,主要以零价态存在.考察了模型吸热燃料正十二烷在反应管内的超临界催化裂解反应,结果表明,Pd/HZSM-5涂层能显著促进裂解反应,在温度640℃、压力4 MPa、停留时间10 s下,吸热燃料裂解率为55.5%,产氢率为3.1%,热沉为3 470 kJ/kg,较HZSM-5涂层分别提高了8.5%,58.7%和10.5%;较热裂解分别提高了17.3%,78.1%和13.5%.     

金属氧化物改性的HZSM-5催化热解木质素定向制备对二甲苯（英文）

对二甲苯是石化行业中一种重要的大宗化学品,而且生物质基对二甲苯的制备在学术和工业领域都具有重要意义.对木质素和甲醇在不同金属氧化物改性的HZSM-5催化剂作用下共催化热解一步法制备可再生的对二甲苯的过程进行了研究.研究结果表明,在HZSM-5催化剂中引入La,Mg,Ce和Zn元素可以调节催化剂的酸强度和强酸性位点,进而促进轻芳烃(如苯和甲苯)烷基化形成对二甲苯以及间/邻二甲苯向对二甲苯的异构化.木质素和甲醇的共催化热解显著地提高了对二甲苯的产率.在20%La_2O_3/HZSM-5催化剂作用下,木质素与33 wt%甲醇共催化热解获得的对二甲苯的最高收率为13.9%,对二甲苯/二甲苯比率为82.7%.并且基于产物的分析以及催化剂的表征,提出了由木质素制备对二甲苯的可能反应途径.     

CO2加氢合成二甲醚的催化剂的制备

先采用均匀沉淀法制备出CuO—ZnO催化剂,然后以CuO—ZnO催化剂作为晶核采用水热合成法制备出CuO—ZnO／HZSM-5（氢型ZSM-5分子筛）复合催化剂．利用X射线衍射和氨程序升温脱附手段对复合催化剂进行表征,并应用于CO2催化加氢合成二甲醚的反应．研究结果表明,在相同的反应条件下,这种CuO—ZnO／HZSM-5复合催化剂与采用物理混合法制备出的复合催化剂相比具有更好的催化效果,不但提高了CO2的转化率、二甲醚的选择性以及二甲醚和甲醇的总选择性,同时还改善了催化剂的稳定性．     

镁改性HZSM-5对Cu-ZnO-Al2O3／HZSM5-催化合成气直接N-甲醚反应的影响

采用浸渍法制备了一系列MgO改性的HZSM-5分子筛，并以MgO/HZSM-5为甲醇脱水催化剂与Cu—ZnO-Al2O3甲醇合成催化剂组成双功能催化剂，在连续流动加压固定床反应器上考察了其对合成气直接制二甲醚反应的催化性能．结果表明，以适量MgO改性的HZSM-5分子筛组成的双功能催化剂上，二甲醚选择性可高达64.8％，CO2和烃类副产物的选择性分别为30．2％和0．4％；由未改性的HZSM-5分子筛组成的双功能催化剂上，二甲醚选择性仅为49．1％，CO2和烃类副产物的选择性则分别高达37．1％和9．3％．当MgO含量过高时，则CO转化率和二甲醚选择性均降低．根据实验结果，提出了甲醇在MgO／HZSM-5上脱水的反应机理．     

双金属镍-锰／γ-Al2O3催化剂对甲烷二氧化碳重整反应的影响

用浸渍法制备γ-Al2O3负载的Ni-Mn双金属催化剂．在500-700。C按照17：17：2的C02／CHa／N2比例,以36mL／min的载气流速进行甲烷二氧化碳重整反应,利用甲烷二氧化碳的转化率、生成的合成气H2／CO比例以及长期稳定性等指标评价了催化剂的催化性能．实验表明,添加Mn提高催化性能并使双金属催化剂的稳定性更高,比单金属催化剂更好地抑制焦炭生成,Mn最合适的添加量为0．5wt％．通过BET、C02-TPD、TGA、XRD、SEM、EDX和FTIR各种技术对催化剂进行了表征．     

木质素降解模型化合物愈创木酚及苯酚原位加氢制备环己醇

以Raney Ni为催化剂,研究了甲醇水相重整制氢与木质素降解模型化合物愈创木酚／苯酚加氢的耦合反应.考察了反应前冷压、反应温度、反应时间、物料配比等条件对木质素降解模型化合物原位加氢反应性能的影响,并对影响机制进行了讨论.结果表明,在反应温度为220 ℃、反应前冷压0 MPa(表压)、物料比水／甲醇／模型化合物为20∶5∶0.8的条件下,反应7 h后愈创木酚转化率与环己醇选择性分别达99.00％和93.74％,反应12 h后苯酚的转化率与环己醇选择性分别达90.50％和99.29％.采用原位加氢反应,木质素降解的酚类模型化合物转化率和选择性明显优于外部供氢反应的转化率和选择性,同时,避免了外部供氢反应存在的氢气制备、储存、传输及加氢条件苛刻等问题,为木质素解聚产物制备化工品提供了新思路与实验基础.     

双功能WC/HZSM-5催化剂上正己烷芳构化反应性能

以HZSM-5(SiO2/Al2O3=38)为载体,偏钨酸铵为钨源制备了双功能催化剂WC/HZSM-5,考察了其催化正己烷芳构化反应性能,并采用X射线衍射、扫描电子显微镜、X射线能量散射谱和程序升温氨脱附等手段对催化剂进行了表征,探讨了制备方法和WC含量对WC/HZSM-5催化剂性能的影响.结果表明,采用原位还原碳化法制备的WC/HZSM-5(RC)催化剂上正己烷芳构化反应性能优于浸渍法制备的WC/HZSM-5(IP).5%WC/HZSM-5(RC)样品在反应初始阶段芳烃选择性为10.28%,而HZSM-5上的仅为2.56%.WC/HZSM-5(RC)催化剂上反应产物中轻质芳烃(苯、甲苯和二甲苯)含量增加,重质芳烃C9+含量降低,其催化性能优于Pt/HZSM-5催化剂.产物分布的变化可能是由于WC与分子筛间的协同作用所致.     

用于费托合成的骨架Co@HZSM-5核壳催化剂

以骨架Co 为内核, 通过水热合成在其表面包覆HZSM-5 分子筛膜, 制备了具有核壳结构的骨架Co@HZSM-5 催化剂. 采用元素分析、氮物理吸附、粉末X射线衍射、扫描电子显微镜、氨脱附等手段对催化剂的物理化学性质进行了表征. 在气相费托合成反应中, 骨架Co@HZSM-5 核壳催化剂显示了比物理混合的骨架Co-HZSM-5催化剂更好的催化裂解作用, 故C₅-C₁₁汽油段产物选择性高. 通过改变水热时间, 对分子筛膜厚进行了调节, 发现适当的分子筛膜厚在保证催化剂具有较高活性的前提下, 使长链费托合成产物完全裂解, 高选择性地得到汽油段产物. 提高反应温度有利于费托合成反应的进行以及分子筛上裂解效率的提高, 但产物分布向短链烃方向移动. 在水热4天制备的骨架Co@HZSM-5核壳催化剂上及反应温度为250 ℃时, 得到了最佳反应结果, 汽油段产物选择性达79%, 说明费托合成活性中心与催化裂解酸中心之间形成了良好的协同作用.     

Coking kinetics and influence of reaction-regeneration on acidity,activity and deactivation of Zn/HZSM-5 catalyst during methanol aromatization

The coking kinetics and reaction-regeneration on Zn/HZSM-5(Zn/HZ) catalyst in the conversion of methanol to aromatics were investigated.The highest initial benzene, toluene and xylene(BTX) yield of ca. 67.7% was obtained on fresh Zn/HZ catalyst, which showed the worst catalytic stability. The cycle of reaction-regeneration significantly modified the texture and acidity of Zn/HZ catalyst, which in turn affected its catalytic performance and coking behavior in methanol conversion to BTX. The residual carbon located on the surface of Zn/HZ catalyst led to the decrease of acid sites and the change on the acid sites distribution, which played an important roles on its activity and deactivation. It was found that the high B/L ratio and the low total acid sites concentration of the Zn/HZ catalyst favored to the high BTX yield and good catalytic stability in methanol conversion.     

Transformation of Bio-oil into BTX by Bio-oil Catalytic Cracking

Production of benzene, toluene and xylenes (BTX) from bio-oil can provide basic feedstocks for the petrochemical industry. Catalytic conversion of bio-oil into BTX was performed by using different pore characteristics zeolites (HZSM-5, HY-zeolite, and MCM-41). Based on the yield and selectivity of BTX, the production of aromatics decreases in the following order: HZSM-5>MCM-41>HY-zeolite. The highest BTX yield from bio-oil using HZSM-5 reached 33.1% with aromatics selectivity of 86.4%. The reaction conditions and catalystcharacterization were investigated in detail to make clear the optimal operating parameters and the relation between the catalyst structure and the production of BTX.     

在Ni/HZSM-5催化剂上低温水蒸汽重整生物油制氢

We investigated high catalytic activity of Ni/HZSM-5 catalysts synthesized by the impregna-tion method, which was successfully applied for low-temperature steam reforming of bio-oil. The influences of the catalyst composition, reforming temperature and the molar ratio of steam to carbon fed on the stream reforming process of bio-oil over the Ni/HZSM-5 catalysts were investigated in the reforming reactor. The promoting effects of current passing through the catalyst on the bio-oil reforming were also studied using the electrochemical catalytic re-forming approach. By comparing Ni/HZSM-5 with commonly used Ni/Al₂O₃ catalysts, the Ni₂₀/ZSM catalyst with Ni-loading content of about 20% on the HZSM-5 support showed the highest catalytic activity. Even at 450 oC, the hydrogen yield of about 90% with a near complete conversion of bio-oil was obtained using the Ni₂₀/ZSM catalyst. It was found that the performance of the bio-oil reforming was remarkably enhanced by the HZSM-5 supporter and the current through the catalyst. The features of the Ni/HZSM-5 catalysts were also investigated via X-ray diffraction, inductively coupled plasma and atomic emission spectroscopy, hydrogen temperature-programmed reduction, and Brunauer-Emmett-Teller methods.     

添加Mo对Cu/HZSM-5催化剂性能影响

负载催化剂;二氧化碳加氢;二氧化碳;添加Mo对Cu/HZSM-5催化剂性能影响     

助剂对泡沫金属微反应器内二甲醚水蒸气重整制氢的影响

采用共沉淀耦合机械混合法制备了CuO-ZnO-Al₂O₃/HZSM-5双功能催化剂用于二甲醚水蒸气重整制氢的研究,结合BET、H₂-TPR、XRD、SEM等表征手段,在泡沫金属微反应器内考察助剂Cr、Zr、Ce、Co对双功能催化剂催化性能的影响。研究结果表明,加入Cr助剂后, 可以有效降低催化剂的平均孔径和还原温度,并抑制催化剂制备过程中氢氧化锌晶相的形成,催化剂的低温催化性能明显提高,二甲醚的转化率和氢收率在较低温度下即可分别达到99%和95%,表现出了良好的低温反应活性。考察了反应温度、空速和水醚比等条件对二甲醚水蒸气重整催化剂催化活性的影响,在250℃、空速3 884 mL/(g·h)、水醚比为5的条件下,CuO-ZnO-Al₂O₃-Cr₂O₃/ HZSM-5催化二甲醚水蒸气重整反应进行50 h,二甲醚的转化率维持在97%以上,催化剂的活性没有明显下降。     

Highly shape-selective Zn-P/HZSM-5 zeolite catalyst for methanol conversion to light aromatics

A highly shape-selective and relatively long-lifetime HZSM-5-based catalyst (Zn-2P/HZSM-5) was prepared by chemical modification with both ZnSiF₆·6H₂O and H₃PO₄ solution. The phosphoric acid modification could effectively modulate the Brønsted acid strength of the HZSM-5 catalyst, which promotes the oligomerization, alkylation, cyclization, and hydrogen transfer reactions. The introduction of Zn-Lewis acid sites significantly improved the dehydroaromatization of higher olefins. All of these were very beneficial for the generation of BTX (i.e. benzene, toluene, and xylene) hydrocarbons in aromatization of methanol. The coke amount and the average rate of coke formation decreased over the Zn-2P/HZSM-5 catalysts, which may largely be ascribed to its lower strong acid sites and lower outer surface acidity. The catalytic performance of methanol aromatization showed that the Zn-2P/HZSM-5 catalyst exhibited the highest BTX selectivity of about 46.76% and the longest catalytic lifetime of about 498 h at T = 400 °C, P = 0.1 MPa, and weight hourly space velocity = 0.7 h⁻¹.     

Process optimization of vapor phase pyridine synthesis using response surface methodology

The vapor phase pyridine synthesis from acetaldehyde, formaldehyde and ammonia over HZSM-5 catalyst was studied. The process parameters like temperature, aldehyde ratio, and Si/Al ratio in HZSM-5 was investigated and the process conditions were optimized using surface response methodology (RSM) based on Box-Behnken design. The influence of process parameters investigated using analysis of variance (ANOVA), to identify the significant parameters. The optimum conditions for high yield of pyridine were identified to be a reaction temperature 400°C, aldehyde ratio 1: 1 and Si/Al ratio 106.7. A maximum of 55% yield of pyridine formed under the optimum experimental conditions. The proposed model equation using RSM has shown good agreement with the experimental data, with a correlation coefficient R ² = 0.99.     

HZSM-5分子筛上C_(6～8)混合链烃和邻二甲苯的加氢裂化

在连续流动固定床装置上,探讨了不同酸性HZSM-5上C6~8混合链烃(以下简称混合烃)和邻二甲苯加氢裂化的变化规律,并在稳定条件下考察了反应温度、质量空速以及氢烃体积比等反应参数的影响。混合烃的加氢裂化伴随着芳构化反应,酸性较弱的HZSM-5主要发生加氢裂化反应,裂化产物以正构烷烃为主,甲烷和异构烷烃较少。酸性强的HZSM-5上,起初以芳构化反应为主,稳定之后产物分布与弱酸催化剂接近。混合烃的加氢裂化反应表现出明显的温度效应,而质量空速和氢烃体积比的影响较小。在380℃、3.0 MPa、质量空速1.02 h-1、氢烃体积比1 000的条件下,100 h内混合烃的转化率均在99%以上,稳定的裂化反应选择性在95%以上。邻二甲苯发生加氢裂化及异构、歧化反应,酸性强的HZSM-5裂化产物收率高,裂化产物分布与混合烃的基本相同。稳定的邻二甲苯裂化反应选择性小于10%。     

CH_4在Mo/HZSM-5及其改性催化剂上的无氧芳构化(英文)

运用微型固定床反应器装置,研究了Mo/HZSM-5催化剂的Mo载量、金属助剂改性、载体模数对甲烷无氧芳构化反应性能的影响。结果表明,Ni/Mo摩尔比为0.1的Mo-Ni/HZSM-5(SiO2/Al2O3=25)催化性能最好,其稳定性较好,芳烃收率最高可达15.74%;此时甲烷转化率60.24%,芳烃选择性26.13%。