甲醇制烃反应机理研究进展

综述了甲醇制烃(MTH)反应机理的研究概况.分别介绍了MTH反应过程中的二甲醚生成、烃池机理、深度反应、催化剂失活原因和副产物甲烷的生成途径,重点综述了烃池机理的研究进展和存在的争议.指出了明确分子筛结构和酸性对烃池物种类型、低碳烯烃生成路径的影响以及初始C—C键形成机制是未来MTH机理研究的方向,据此指导并开发出抗积炭失活能力强、目标产物选择性高的催化剂仍是改进MTH工艺的关键.     

甲醇及合成气制二甲醚中不同粒径的 HY 分子筛及复合 Cu-Mn-Zn/HY 催化剂

 通过改变导向剂的老化时间, 制备了一系列不同粒径的 HY 分子筛作为脱水催化剂, 考察了甲醇脱水反应性能; 将其与铜基甲醇合成活性组分 Cu-Zn-Mn 组成双功能催化剂, 考察了催化剂对合成气直接制二甲醚反应的催化性能. 结果表明, 粒径为 820 nm 的 HY 分子筛在甲醇脱水中表现出较高的催化活性; 以其作为脱水组分的双功能 Cu-Zn-Mn/HY 催化剂也表现出较高的催化活性和良好的稳定性.     

甲醇／C4烃在Ga／HZSM—5催化剂上偶合反应过程的研究

甲醇／低碳烃偶合转化是基于热中和原理而提出的新反应过程，以碳四烯混合物作原料，考察了其与甲醇在Ｇａ／ＨＺＳＭ－５催化剂上偶合转化制备芳烃联产低碳烯烃的反应条件，并探讨了反应过程的作用机理。     

酸性分子筛上甲醇催化转化反应机理研究进展

概括了甲醇转化反应机理实验和理论研究方法,介绍了甲醇脱水预平衡阶段的主要机理模型和实验理论依据,重点综述了C-C键形成过程中涉及到的直接机理和"烃池"机理的实验与理论研究进展和存在的问题,探讨了分子筛孔道结构对"烃池"物种结构和反应历程的影响.     

碳四烃在改性HZSM-5分子筛上芳构化研究

研究了炼厂混合C_4烃在Zn、Ga、Cr、La改性的HZSM-5分子筛催化剂上的芳构化反应,采用TPD和IR测定了催化剂的表面酸性质。结果表明,用Zn(3%)和Zn(2%)Ga(1%)改性的HZSM-5分子筛具有较好的芳构化性能;各改性HZSM-5分子筛催化剂芳构化性能变化与表面酸性有关,总酸量下降,芳构化活性下降,强B酸中心减少,深度裂解反应减少;Zn的单组分和双组分改性的HZSM-5分子筛催化剂芳构化活性的增高与表面强L酸浓度增加和吡啶吸附IR谱中的1615cm~(-1)吸收峰出现有关。     

HY分子筛催化1,3-苯并二噁茂烷类化合物合成的研究

研究了HY分子筛催化邻苯二酚与环己酮、丁酮、丙酮、丙醛、丁醛、异丁醛、戊醛、异戊醛、正己醛、正辛醛、苯甲醛、二苯甲酮等十余种醛(酮)的缩合反应。考察了反应时间、酚与醛(酮)的配比、HY分子筛用量等因素对酚与醛(酮)反应的影响。实验发现,当邻苯二酚与醛(酮)摩尔比为1∶1.0、催化剂用量为每mol邻苯二酚2.5g、反应4h,选择性一般在97%以上,醛(酮)的转化率一般在57%以上,表明HY分子筛对邻苯二酚与醛(酮)的反应有较好的催化性能。     

甲醇与异丁烯在改性β分子筛上的吸附行为研究

采用过渡应答技术对甲醇和异丁烯在改性β分子筛上的吸附行为进行了研究,研究结果表明：异丁烯和甲醇有改性β分子筛上符合先快吸附后慢吸附的Elovich吸附规律。甲醇的吸附量大,但速率慢,异丁烯吸附量小,速率快;由于甲醇的饱和吸附量大于异下烯的饱和吸附量,对合成MTBE反应的选择性具有重要意义。对它们的吸附行为进行动力学研究,得到不同温度下吸附活化能随吸附量变化的关系。不同温度下相对饱和吸附量预测表明：当温度从288K升高到383K时,qMeOH/qIB从6．1降低到4．6,甲醇的相对饱和吸附量随温度升高而减小,但仍保持较高值,证明了甲醇在分子筛上是强吸附的观点,为解释选择性和高和动力学方程的建立提供依据,对反应机理的研究有指导作用。     

改性HY型分子筛对废塑料油轻质化的影响

以HY分子筛和硝酸盐[M(NO3)2,M=Ni,Zr,Ca和Ce]为原料,通过浸渍法制得改性HY型分子筛(M/HY)催化剂,其结构和性能经XRD,比表面积,IR和SEM表征。考察了M/HY催化重质油轻质化的效果,结果表明,稀土金属的添加使重质油转化率得到了提高,平均转化率均在40%以上。从总选择性以及类汽油选择性来看,其中Ni/HY活性较好,类汽油选择性平均值为53.98%,最高达72.56%,选择性均优于HY分子筛(21.32%)。     

Study on catalytic synthesis of 1,3-benzodioxoles by HY zeolite

The acetalization and ketalization of various aldehydes and ketones with catechol by using HY zeolite as catalyst were studied. Effect of the reaction time, mole ratio of reactants, and amount of catalyst on the yield of benzodioxoles were investigated. Results show that HY is an efficient catalyst for the acetalization and ketalization with high conversion and selectivity in mild conditions. The best reaction conditions: molar ratio of catechol to aldehydes or ketones is 1:1.4, catalyst amount is 3.5 g/l mol catechol, reaction time is 5 h. Under these conditions, the conversion and selectivity were over 50% and 97%, respectively. Translated from Huaxue Tongbao 2006, 69(6) (in Chinese)     

Ru/HY催化剂催化对苯二酚加氢研究

对苯二酚液相加氢制备1,4-环己二醇的途径环境友好,关键是研究高催化活性的催化剂来提高产物产率.我们以Ru/HY为催化剂用于对苯二酚加氢.用XRD,TEM对催化剂进行了表征,通过吡啶吸附红外对HY酸性的变化进行了讨论.对其反应条件进行了优化.结果表明3.0%Ru/HY的催化剂表现出高的活性,对苯二酚的转化率和1,4-环己二醇的选择性分别为96.5%和68.3%.我们还基于对Ru/HY催化剂结构的研究探讨并提出相应的反应机理.     

Kinetics of methanol steam reforming over COPZr-2 catalyst

The COPZr-2 catalyst, which was prepared in our prophase research, showed good catalytic performance in methanol steam reforming reaction. In this article, the best one was chosen as an example to study the reaction kinetics of methanol steam reforming over this type of catalyst. First, the effects of methanol conversion to outlet CO2 and methanol conversion to outlet CO on methanol pseudo contact time W/FMeOH were investigated. Then by applying the reaction route that methanol direct reforming （DR） and methanol decomposition （DE） were carried out in parallel, the reaction kinetic model with power function type was established. And the parameters for the model were estimated using a non-linear regression program which computed weighted least squares of the defined objects function. Finally, the kinetic model passed the correlation test and the F-test.     

ZnHZSM-5上甲醇芳构化反应的研究

通过浸渍法改性制得ZnHZSM-5催化剂,并采用XRD、BET、NH₃-TPD和Py-IR方法对催化剂进行表征。在连续流动固定床反应装置上考察了Zn负载量和反应条件对甲醇芳构化反应(MTA)的影响。结果表明,0.5%Zn负载量可使芳烃收率提高5%。当Zn负载量超过2%时,不仅不能提高芳烃收率,反而促使甲醇裂解成CO和CO₂,Zn负载量为1.0%～2.0%时芳构化活性较高。最佳反应条件为液体体积空速0.36h^-1~0.6h^-1,温度350℃。并对Zn改性下的甲醇芳构化反应过程进行了探讨。     

ZnCrO_x/HZSM-5催化合成气直接转化制异构烷烃

分别采用共沉淀法和水热法制备了ZnCrO_x复合金属氧化物和HZSM-5沸石,通过物理混合得到双功能催化剂,实现了合成气一步高选择性制备异构烷烃。采用XRD、TEM、氮吸附和NH3-TPD等技术对催化剂进行了表征,考察了双功能催化剂中HZSM-5沸石组分硅铝比以及ZnCrO_x/HZSM-5质量比(OX/ZEO mass ratio)对合成气催化转化反应性能的影响。结果表明,随着HZSM-5硅铝比的增加,催化剂酸密度下降,CO转化率略有下降,产物中C5+选择性显著提高,异构烷烃比例不断增加。此外,在保证CO转化率的前提下提高双功能催化剂中ZnCrO_x组分的比例,产物中C5+的选择性也显著上升。在400℃、2.0 M Pa、进料空速(GHSV)为3600 mL/(h·gcat)的条件下,合成气(H2/CO(volume ratio)=2)转化率达到35%,C5+选择性超过44%,且C5+中异戊烷比例高达65%。     

Controlled re-oxidation of low-pressure methanol synthesis catalyst,followed by means of DSC

The re-oxidation of low-pressure methanol synthesis catalyst was followed by means of DSC, with the aim of contributing to a better understanding of the processes taking place during catalyst blanketing, stabilization and re-oxidation. The investigations were carried out with previously hydrogen-reduced samples, and their successive re-oxidation was performed with different oxygen contents in the oxygen/nitrogen gas mixtures. A procedure for catalyst stabilization and/or catalyst discharge is proposed.     

Hydrogenolysis of glycerol over HY zeolite supported Ru catalysts

An enhanced active and selective catalyst consisting of ruthenium supported on dealuminated HY zeolite has been prepared by a wet impregnation method. It was found that BET surface area of Ru/HY catalysts significantly increases after HCl treatment. This treatment also increases the concentration of strong acid sites in the catalyst. The hydrogenolysis of glycerol over 5 wt% Ru/HY catalyst was investigated at 190-220 ℃, an initial H2pressure of 3-6 MPa, and in 20 wt% glycerol aqueous solution. The results indicate that HCl treated Ru/HY catalyst shows higher activity compared with the untreated Ru/HY catalyst, and that the glycerol hydrogenolysis efficiency is influenced by the porosity and acidity of the support. A selectivity to 1,2-PDO of 81.3% at a glycerol conversion of 60.1% under 3 MPa H2pressure and 220 ℃ for 10 h was achieved over the modified Ru/HY catalyst with a 1.0 mol/L HCl treatment. It has also been shown that a longer reaction time, a higher temperature and a higher H2pressure have the positive effects on the glycerol hydrogenolysis efficiency of the enhanced Ru/HY.     

Isomerization and Disproportionation of 1,2,4-Trimethylbenzene over HY Zeolite

The conversion of 1,2,4-trimethy]benzene (1,2,4-TMB) over HY zeolite was studied at atmosoheric pressure and 200–300 °C by using a fixed-bed, integral-flow reactor. The types and initial selectivities of various products were obtained from plots of product selectivity according to the time-on-stream theory. The primary reaction included the isomerization and the disproportionation; the former led to the simultaneous formation of 1,2.3- and 1,3,5-TMB whereas the latter produced all isomers of xylene and tetramethylbenzene. The relative initial rate of disproportionation to isomerization decreased from 12.6 at 200 °C to 5.47 at 300 °C. The activation energies for the primary reactions were estimated and compared with those in the reaction of 1,2,3-TMB.     

Reducing methane formation in methanol to olefins reaction on metal impregnated SAPO-34 molecular sieve

SAPO-34 silicoaluminophosphate molecular sieve produces large amounts of methane at elevated temperatures in the methanol to olefins (MTO) process. This significantly reduces the lower olefins selectivity a key factor in determining the commercial viability of this catalyst. Impregnation of the SAPO-34 molecular sieve with metal ions such as K, Cs, Pt, Ag and Ce was found to reduce the amount of methane significantly at higher temperatures thereby increasing the lower olefins selectivity. This observed effect is less apparent at lower temperatures where the amount of methane formed is generally low. This revised version was published online in June 2006 with corrections to the Cover Date.