低硅铝比ZSM-5分子筛上C4烃的催化裂解反应

以低硅铝比(n(SiO2)/n(Al2O2)=20-45)的ZSM-5分子筛为催化剂,研究了混合C4烃的催化裂解反应,并对不同硅铝比的ZSM-5分子筛进行了酸性表征.混合C4烃的催化裂解反应结果表明,低硅铝比的ZSM-5分子筛具有较高的低温催化活性,高硅铝比ZSM-5分子筛催化剂上乙烯和丙烯的收率高于低硅铝比ZSM-5分子筛催化剂,低硅铝比ZSM-5分子筛上苯和甲苯的收率高于高硅铝比ZSM-5分子筛催化剂.在反应温度为625℃时,硅铝比为20的ZSM-5分子筛催化剂上乙烯、丙烯、苯和甲苯的总收率可达79.42%.酸性表征结果表明,硅铝比低的ZSM-5分子筛具有更多的Bronsted(B)酸酸量、Lewis(L)酸酸量及总酸酸量,这是低硅铝比ZSM-5分子筛具有低温高活性及高的苯和甲苯收率的原因.     

ZSM-5／MOR复合分子筛催化剂对混合C4烃转化反应的催化性能

以ZSM-5/丝光沸石(MOR)复合分子筛为催化剂,对混合C4烃的催化转化反应进行了评价,并采用程序升温脱附和原位红外光谱技术对ZSM-5/MOR的酸性进行了表征. 结果表明,与ZSM-5相比, MOR具有很低的催化活性,但ZSM-5/MOR复合分子筛具有较高的催化活性,随着ZSM-5/MOR复合分子筛中ZSM-5含量的增加, C4烃转化率稍有升高;在C4烃转化率大致相同的情况下,乙烯和丙烯的总选择性比较接近,但苯和甲苯的总收率却快速升高. 随着ZSM-5/MOR复合分子筛中ZSM-5含量的增加,弱酸和中强酸的酸量逐渐减少,强酸的酸量有所增加. 由于ZSM-5/MOR复合分子筛中MOR对ZSM-5起到分散作用而产生更多的L酸中心,且此L酸中心处于分子筛的外表面而具有较高的能量,导致苯和甲苯的总收率升高.     

ZSM-5分子筛晶粒尺寸对C4烯烃催化裂解制丙烯的影响

 采用水热法合成了晶粒尺寸分别为20～30,1～2和0.2～0.3 μm的三种ZSM-5分子筛样品,并用SEM,XRD,氮低温物理吸附,NH3-TPD和TGA等技术对ZSM-5分子筛进行了表征,以考察其晶粒尺寸对C4烯烃裂解生产丙烯过程中催化剂活性和稳定性的影响. 结果表明,在常压,WHSV=10 h-1和550 ℃的条件下,以ZSM-5分子筛为催化剂,通过C4烯烃的催化裂解可以获得高收率的丙烯,反应初期丙烯的单程收率可达38%; 尽管三种晶粒尺寸的分子筛具有相近的比表面积和总酸量,但小晶粒的ZSM-5分子筛(粒径0.2～0.3 μm)具有微孔短、外比表面积大和孔口多等特点,因而表现出较强的容积炭能力和较好的稳定性; 小晶粒的ZSM-5分子筛催化剂经过10次再生重复使用,其催化生成丙烯的收率没有明显降低.     

ZSM-5/ZSM-57复合分子筛催化剂上混合C4烃的催化转化反应

以ZSM-5/ZSM-57复合分子筛为催化剂, 考察了其对混合C4烃催化转化的反应性能. 采用氨程序升温脱附(NH3-TPD)和吡啶吸附傅立叶变换红外(FT-IR)光谱技术表征复合分子筛的酸性质. 结果表明, 当复合分子筛中ZSM-5的含量较低时, 比ZSM-5具有更高的催化活性及乙烯和丙烯选择性, 这是因为此时复合分子筛酸强度较高、酸量较多, 且小孔ZSM-57有利于乙烯和丙烯的择形反应. 而当复合分子筛中ZSM-5的含量较高时, 具有较高的苯和甲苯选择性, 其原因可能是其孔结构及共晶生长时的结构匹配性对芳构化反应有利.     

高硅MCM-22分子筛的合成及其C4烯烃裂解性能

由于丙烯衍生物需求量迅速增长,致使全球丙烯需求增长速率超过乙烯,近年来,人们一直在寻求新的丙烯增产的方法,采用分子筛作为催化剂,通过裂解C4及C4以上富烯烃原料来获取高收率的丙烯已引起国内外学者的高度关注,Rubinm等于1990年首先合成出MCM-22分子筛,由于其特有的酸性和独特的孔结构而被广泛用于各类化学反应中,迄今尚未见文献报道MCM-22分子筛在C4烯烃裂解反应中的催化性能研究,由于高硅铝比分子筛具有相对较高的热稳定性和水热稳定性,     

高硅分子筛ZSM-23催化裂解C4烷烃制乙烯丙烯的研究

采用廉价的硅溶胶作为硅源,吡咯烷为模板剂,静态水热晶化法合成出不同硅铝比的ZSM-23分子筛.采用XRD,SEM,吡啶吸附红外光谱等技术,对合成的ZSM-23分子筛的结构、形貌、表面酸性质进行了表征.并进行了所制样品对C4烷烃催化裂解制乙烯丙烯反应催化性能的研究.本文详细考察了硅铝比、反应温度、反应空速以及催化剂稳定性等各种因素对催化性能的影响.结果表明,ZSM-23分子筛的乙烯丙烯收率达到56.0%,丁烷转化率达到88.9%.     

Pt/HZSM-5基催化剂双功能协同性对正丁烷催化裂解反应机制的影响

轻质烷烃结构稳定,化工利用率低.催化裂解轻质烷烃是其高值利用的重要途径,相关研究同时对C-C键和C-H键活化和演变调控具有重要意义.本文在基于原子层沉积法构建高稳定Pt/HZSM-5基双功能模型催化剂的基础上,研究了不同酸性HZSM-5分子筛引入脱氢组分Pt对反应路径及目的产物低碳烯烃的影响规律.研究发现,双功能催化剂中, Pt的脱氢性能与分子筛的酸性裂解性能存在协同作用,不同硅铝比的分子筛上引入Pt,高硅铝比分子筛上Pt的引入对脱氢促进效应更明显.同时,将脱氢组分Pt引入到不同裂解能力的酸性分子筛载体上,会改变其低碳烯烃的生成路径,高硅铝比的分子筛上引入Pt后丁烯的生成路径增强,而低硅铝比的分子筛上则会增强乙烯与丙烯的生成路径,当分子筛硅铝比继续降低时,乙烯的生成路径进一步增强.本研究对多相复杂反应中反应路径调控及高效双功能催化剂设计具有指导意义.     

水蒸气处理对ZSM-5酸性及其催化丁烯裂解性能的影响

 考察了水蒸气处理温度和时间对ZSM-5分子筛酸性及其催化丁烯裂解性能的影响. 结果表明,通过水蒸气处理可降低ZSM-5分子筛的酸量和酸强度,明显提高产物中丙烯与乙烯的选择性和收率,抑制副产物芳烃和低碳烷烃的生成. 用柠檬酸脱除水蒸气处理过程中产生的非骨架铝,可提高ZSM-5分子筛孔道的容碳能力,从而提高催化剂的稳定性. 考察了反应条件对催化剂性能的影响,结果表明较佳的反应条件为WHSV=3.5～8.8 h-1,p=0.06～0.1 MPa,θ=600～620 ℃.     

不同硅铝比ZSM-5分子筛作为助催化剂在渣油裂化中的应用

采用不同方法表征了硅铝比(SiO2/Al2O3)为33、266和487的质子型ZSM-5分子筛,并研究了ZSM-5分子筛作为助催化剂在渣油裂解中的应用。与USY分子筛基催化剂混合后,在固定流化床上,评价了ZSM-5分子筛助催化剂的催化裂化性能。研究发现,提高ZSM-5分子筛硅铝比,可以有效抑制混合催化剂对汽油烯烃的裂解,从而避免了汽油烷烃的大量损失。加入ZSM-5助催化剂后,伴随着液化气(LPG)产率的增加,异丁烷和异戊烷产率增加,这可能是由USY基催化剂和ZSM-5助催化剂的综合效应引起的。汽油烷烃和芳烃含量的变化,引起了汽油辛烷值的增加。高硅铝比ZSM-5分子筛(硅铝比为266和487)不仅可以显著改善汽油的辛烷值,而且有效避免了汽油的大量损失。催化汽油辛烷值的改善主要是由于高硅铝比ZSM-5分子筛具有适宜的芳构化和异构化活性,这些变化主要源于高硅铝比ZSM-5分子筛小的孔道直径和适宜的酸性。     

不同硅铝比ZSM-5分子筛作为助催化剂在渣油裂化中的应用（英文）

采用不同方法表征了硅铝比(Si O2/Al2O3)为33、266和487的质子型ZSM-5分子筛,并研究了ZSM-5分子筛作为助催化剂在渣油裂解中的应用.与USY分子筛基催化剂混合后,在固定流化床上,评价了ZSM-5分子筛助催化剂的催化裂化性能.研究发现,提高ZSM-5分子筛硅铝比,可以有效抑制混合催化剂对汽油烯烃的裂解,从而避免了汽油烷烃的大量损失.加入ZSM-5助催化剂后,伴随着液化气(LPG)产率的增加,异丁烷和异戊烷产率增加,这可能是由USY基催化剂和ZSM-5助催化剂的综合效应引起的.汽油烷烃和芳烃含量的变化,引起了汽油辛烷值的增加.高硅铝比ZSM-5分子筛(硅铝比为266和487)不仅可以显著改善汽油的辛烷值,而且有效避免了汽油的大量损失.催化汽油辛烷值的改善主要是由于高硅铝比ZSM-5分子筛具有适宜的芳构化和异构化活性,这些变化主要源于高硅铝比ZSM-5分子筛小的孔道直径和适宜的酸性.     

氟离子对无胺法合成高硅丝光沸石的结构导向作用

 在含氟无胺体系中合成了高硅丝光沸石，研究了合成条件对丝光沸石产物的影响．结果表明，投料n（SiO2）／n（Al2O3）＝20～200时，控制晶化条件可得到高硅丝光沸石纯相．由含氟无胺体系中丝光沸石的热力学稳定相区可见，氟离子的引入对方沸石的生成的相区无影响，ZSM－5和镁碱沸石生成的相区消失，丝光沸石生成的相区扩大，石英生成的相区缩小，且基本上变为两相共存区．合成产物丝光沸石的硅铝比随着氟硅比的升高同步增大，证明氟离子在无胺合成高硅丝光沸石时具有结构导向作用．     

测定ZSM—5分子筛SiO2/Al2O3比的X射线衍射分析新方法

用X射线衍射最小二乘法测定ZSM-5分子筛的晶胞参数，由SiO2／Al2O3比与晶胞何种之间的经验公式，可得到ZSM-5分子筛的SiO2／Al2O3比。实验结果分析表明，该方法测定的ZSM-5分子筛SiO2／Al2O3比较通常采用的化学分析方法省时、简便、重复性好。     

不同硅铝比β沸石的理化性质及烃类催化裂化活性

采用润湿态固相转化方法按照投料硅铝摩尔比(n(SiO2)/n(Al2O3))分别为30、60、150、300、500和纯硅时合成了β沸石, 化学法和X射线荧光(XRF)测定产物的硅铝比和反应初始凝胶基本一致. 利用X射线衍射(XRD)、红外光谱(FT-IR)、扫描电镜(SEM)、氨程序升温脱附(NH3-TPD)和低温N2吸附对系列样品的物相、水热稳定性、晶体形貌、酸性以及表面积和孔体积做了系统的表征. 并将该系列样品作为活性组分添加剂, 以高岭土为基质分别制备烃类裂化催化剂, 对其催化裂化性能进行了评价. 结果表明, 不同硅铝比β沸石添加到裂化催化剂均可以提高其裂化活性, 改善催化剂的抗积炭性能, 硅铝比为150的β沸石催化剂在保持较高裂化活性的前提下, 汽油收率最高, 抗积炭性能也较好, 是优选的裂化催化材料.     

载体组成对负载型PtSn/ZSM-5催化剂上丙烷脱氢反应性能的影响

用微型催化反应装置结合吡啶吸附的红外光谱、NH3-程序升温脱附、热重、H2化学吸附和程序升温还原等物理化学手段研究了载体组成对负载型PtSn/ZSM-5催化剂上丙烷脱氢反应性能的影响.结果表明,负载型PtSn/ZSM-5催化剂对丙烷脱氢的催化性能与载体组成密切相关.随着ZSM-5载体中SiO2/Al2O3比的增加,催化剂表面的酸中心总量和强酸中心量逐渐减少.当SiO2/Al2O3摩尔比从45增至108时,催化剂对丙烷脱氢反应的催化活性提高,并且催化剂的积炭量下降.当SiO2/Al2O3摩尔比增至304时,Sn组分与载体ZSM-5之间的相互作用减弱,经H2还原后催化剂中Sn0物种所占的比例增加,导致催化剂H2化学吸附量和丙烷脱氢反应活性下降.     

Production of propylene from an unconventional metathesis of ethylene and 2-pentene over Re2O7/SiO2-Al2O3 catalysts

An unconventional metathesis of ethylene and 2-pentene over Re2O7/SiO2-Al2O3 catalysts has been studied as an alternative route for the production of propylene. Complete conversion of 2-pentene and propylene yield as high as 88 wt% were obtained under mild reaction conditions at 35°C and atmospheric pressure. Unlike the conventional metathesis of ethylene and 2-butenes in which isomerization is a competing side reaction, the isomerization of 1-butene product from the unconventional metathesis of ethylene and 2-pentene to 2-butenes can further react with excess ethylene in the feed, resulting in additional increase in propylene yield. The secondary metathesis reaction was found to be favored under ethylene/2-pentene (E/2P) molar ratio 3 and gas hourly space velocity (GHSV) 1000 h-1 at the reaction temperature of 35°C. No catalyst deactivation was observed during the 455 min time-on-stream under the selected reaction conditions.     

Effects of ammonium exchange and Si/Al ratio on the conversion of methanol to propylene over a novel and large partical size ZSM-5

One type of ZSM-5 zeolite with large partical size was prepared and characterized by XRD, SEM, N2 adsorption-desorption, XRF, Py-IR and NH3-TPD techniques. Effects of ammonium exchange and SiO2/Al2O3 molar ratios on the reaction of methanol to propylene (MTP) over Na-ZSM-5 and H-ZSM-5 zeolites have been studied in a fixed-bed flow reactor under the operating conditions of T = 500 °C, P = 1 atm, and WHSV = 6 h-1. Ammonium exchange led to a rapid decrease in Na content for Na-ZSM-5 zeolite. The reaction results indicated that Na-ZSM-5 and H-ZSM-5 with different SiO2/Al2O3 molar ratios all exhibited high activity for methanol conversion. Ammonium exchange and the decreased SiO2/Al2O3 molar ratio of ZSM-5 zeolite led to an increase both in strong acid sites and weak acid sites. Na-ZSM-5 with high SiO2/Al2O3 molar ratio was favorable for the formation of propylene. The highest propylene selectivity (45.9%) was obtained over Na-ZSM-5 zeolite catalyst with SiO2/Al2O3 molar ratio of 220.     

Dealuminated ZSM-5 Zeolite Catalyst for Ethylene Oligomerization to Liquid Fuels

Ethylene oligomerization using ZSM-5 zeolite was investigated to study the role of Bronsted acid sites in the formation of higher hydrocarbons. The oligomerization of olefins, dependent on the acidity of ZSM-5 zeolite, is an important step in the conversion of natural gas to liquid fuels. The framework Si/Al ratio reflects the number of potential acid sites and the acid strength of the ZSM-5 catalyst. ZSM-5 with the mole ratio SiO2/Al2O3 equal to 30 was dealuminated for different periods of time according to the acidic ion-exchange method to produce ZSM-5 with various Si/Al ratios. The FT-IR analysis revealed that the integrated framework aluminum band, non-framework aluminum band, and silanol groups areas of the ZSM-5 zeolites decreased after being dealuminated. The performance of the dealuminated zeolite was tested for ethylene oligomerization. The results demonstrated that the dealumination of ZSM-5 led to higher ethylene conversion, but the gasoline selectivity was reduced compared to the performance     

电场增强催化甲烷合成碳二烃催化剂影响研究

本研究提出了在常温、常压电场增强等离子体条件下甲烷直接转化合成碳二烃的洁净工艺 ,在不同的放电电压、放电功率、甲烷进料流量和不同的催化剂作用下 ,甲烷能够以不同的转化率和选择性转变为碳二烃。对影响甲烷转化率和碳二烃选择性的因素 :放电电压、放电功率、甲烷进料流量和催化剂进行了研究 ,对催化剂性能进行了比较 ,并探讨了反应机理。结果表明 ,适宜的工艺条件 :放电电压 2 0kV～ 4 0kV ;输入功率 :2 0W～ 4 0W ;合适的甲烷进料流量 :30mL/min～ 70mL/min。在该条件下 ,碳二烃的选择性可以达到 95 % ;催化剂对甲烷转化率的影响顺序为MnO2 /Al2 O3 >Ni/Al2 O3 >MoO3 /Al2 O3 >Ni/NaY >Pd/ZSM 5 >Ni/H4Mg2 Si3 O4>Ni/ZSM 5 >Co/ZSM 5 >无催化剂。     

Effects of Temperature and Catalyst to Oil Weight Ratio on the Catalytic Conversion of Heavy Oil to Propylene Using ZSM-5 and USY Catalysts

It is useful for practical operation to study the rules of production of propylene by the catalytic conversion of heavy oil in FCC (fluid catalytic cracking). The effects of temperature and C/O ratio (catalyst to oil weight ratio) on the distribution of the product and the yield of propylene were investigated on a micro reactor unit with two model catalysts, namely ZSM-5/Al2O3 and USY/Al2O3, and Fushun vacuum gas oil (VGO) was used as the feedstock. The conversion of heavy oil over ZSM-5 catalyst can be comparable to that of USY catalyst at high temperature and high C/O ratio. The rate of conversion of heavy oil using the ZSM-5 equilibrium catalyst is lower compared with the USY equilibrium catalyst under the general FCC conditions and this can be attributed to the poor steam ability of the ZSM-5 equilibrium catalyst. The difference in pore topologies of USY and ZSM-5 is the reason why the principal products for the above two catalysts is different, namely gasoline and liquid petroleum gas (LPG), repspectively. So the LPG selectivity, especially the propylene selectivity, may decline if USY is added into the FCC catalyst for maximizing the production of propylene. Increasing the C/O ratio is the most economical method for the increase of LPG yield than the increase of the temperature of the two model catalysts, because the loss of light oil is less in the former case. There is an inverse correlation between HTC (hydrogen transfer coefficient) and the yield of propylene, and restricting the hydrogen transfer reaction is the more important measure in increasing the yield of propylene of the ZSM-5 catalyst. The ethylene yield of ZSM-5/Al2O3 is higher, but the gaseous side products with low value are not enhanced when ZSM-5 catalyst is used. Moreover, for LPG and the end products, dry gas and coke, their ranges of reaction conditions to which their yields are dependent are different, and that of end products is more severe than that of LPG. So it is clear that maximizing LPG and propylene and restricting dry gas and coke can be both achieved via increasing the severity of reaction conditions among the range of reaction conditions which LPG yield is sensitive to.     

Dealuminated ZSM—5 Zeolite Catalyst for Ethylene Oligomerization to Liquid Fuels

Ethylene oligomerization using ZSM-5 zeolite was investigated to study the role of Broensted acid sites in the formation of higher hydrocarbons,The oligomeriztion of olefins,dependent on the acidity of ZSM-5 zeolite ,is an important step in the conversion of natural gas to liquied fuels,The framework Si/Al ratio reflects the number of potential acid sites and the acid strength of the ZSM-5 catalyst,ZSM-5 with the mole ratio SiO2/Al2O3 equal to 30 was dealuminated for different periods of time according to the acidic ion-exchange method to produce ZSM-5 with various Si/Al ratios,The FT-IR analysis revealed that the integrated framework aluminum band,non-framework aluminum band,and silanol groups areas of the ZSM-5 zeolites decreased after being dealuminated,The performanc of the dealuminated zeolite was tested for ethylene oligomerization.The results demonstrated that the dealumination of ZSM-5 led to higher ethylene conversion,but the gasoline selectivity was reduced compared to the performance of a ZSM-5 zeolite ,The characterization results revealed the amount of aluminum in the zeolitic framework,the crystallinity of the ZSM-5 zeolite,and the Si/Al ration affected the formation of Broensted acid sites,The number of the Broensted acid sites on the catalyst active sites is important in the olefin conversion to liquied hydrocarbons.