Regulation of isobutane/1-butene adsorption behaviors on the acidic ionic liquids-functionalized MCM-22 zeolite

The adsorption ratio of isobutane/1-butene on the catalyst surface is one of the most important factors for the C_4 alkylation process. Regulation of isobutane/1-butene adsorption ratio on the zeolite-supported acid catalyst is a big challenge for catalyst preparation. To regulate the isobutane/1-butene adsorption ratio, four types of ionic liquid(i.e., IL) with different alkyl chain lengths and different acid group numbers were synthesized and were subsequently immobilized onto the MCM-22 zeolite. The as-synthesized IL-immobilized MCM-22(i.e., MCM-22-IL)was characterized by FTIR, TGA, BET, XPS and XRD, and their adsorption capacities and adsorption molar ratios of isobutane to 1-butene(I/O) were investigated to correlate with surface features of MCM-22-IL. Results showed that the immobilization of ILs led to a decrease of specific surface area and pore volume. But the surface density of acid groups was increased and the adsorption molar ratio of isobutane/1-butene(I/O) was significantly improved by the immobilization of ionic liquids. The adsorption molar ratio of I/O is substantially improved from 0.75 to above 0.9 at 300 kPa upon immobilizing ILs. Although the alkyl chain length of ILs was found to have little effect on the adsorption molar ratio of I/O, the increase of acid group numbers led to a dramatic decrease in the adsorption I/O ratio. The results illustrated that immobilizing ionic liquids is an effective way to modify the textural, chemical and morphological properties of MCM-22. Accordingly, the immobilization of ionic liquids provides a novel and a feasible way to regulate the adsorption I/O ratio on an adsorbent or a solid catalyst.

Skeletal Isomerization of 1-Hexene over MCM-22 Zeolite Catalyst

The performance of MCM-22 zeolite for catalytic isomerization of 1-hexene has been studied. At a n(H2)/n(1-hexene) ratio of 8, the influence of steam treatment temperature, reaction temperature and reaction pressure on the performance of MCM-22 zeolite for catalytic skeletal isomerization of 1-hexene was examined. The experimental results showed that at a steam treatment temperature of 500℃, a reaction temperature of 270℃, a space velocity of 1.0 h-1 and a reaction pressure of 0.2 MPa, the MCM-22 zeolite exhibited excellent performance for catalytic skeletal isomerization of 1-hexene with the i-hexene yield reaching 66.15%. Compared with other commonly used molecular sieve catalysts, the MCM-22 zeolite catalyst exhibited better catalytic performance for skeletal isomerization of 1-hexene.

Study on Mechanism for Alkylation of Benzene with Propylene over β Zeolite and MCM-22 Zeolite by In-situ IR Spectrometry

为有在沸石和 MCM-22 沸石上的丙烯的苯的完化的反应机制分别地被调查由在原处，实验的红外 spectrometry.Three 类型被执行( 1 )煤气阶段的丙烯的红外系列，苯和 isopropyl 苯被记录( 2 )红外系列上述作为被吸附物质，那与沸石晶片相结合的物质被记录( 3 )反应模式的红外系列是测试结果显示出的 recorded.The 完化

OSDA-free synthesis of FeZSM-22 zeolite from natural minerals for n-octane hydroisomerization

A seed-directed approach to synthesizing Fe ZSM-22 zeolite without organic structure directing agent(OSDA)was developed by using Fe-rich diatomite as all aluminum and iron sources.The Fe ZSM-22zeolite with optimal crystallinity and purity can be obtained by systematically adjusting feed composition and synthesis conditions.Characterizations show that Fe ZSM-22 zeolite synthesized with OSDA-free owns high crystallinity,obvious thin needle-shaped morphology and high Bronsted/Lewis acid ratio.Significantly,when used for n-octane hydroisomerization reaction,its derived catalyst exhibits the best catalytic performance reflected by the highest selectivity to C_(8)isomers compared to the two reference catalysts prepared based on a Fe-containing and a Fe-free ZSM-22 synthesized through an OSDA-directed route from natural diatomite and conventional chemicals,respectively.This work provides an alternative route to sustainably synthesizing heteroatomic zeolites with high performance.

高硅MCM-22分子筛的合成与催化性能

以六亚甲基亚胺(HMI)和N,N,N-三甲基-1-金刚烷基氢氧化铵(TMAdaOH)为复合有机结构导向剂合成高硅MCM-22分子筛,并负载钼制备不同SiO_(2)/Al_(2)O_(3)摩尔比的MCM-22催化剂,采用XRD、FT-IR、UV-Raman、SEM、NH3-TPD等手段对分子筛产品进行表征,并对负载型MCM-22催化剂进行重芳烃轻质化反应性能评价。结果表明:HMI和TMAdaOH复合协同作用能有效促进硅原子进入MCM-22分子筛骨架,抑制麦羟硅钠石的出现,提升分子筛的骨架结晶性和结构稳定性,其中SiO_(2)/Al_(2)O_(3)摩尔比80合成的MCM-22分子筛(S80)具有最高的微孔结晶度和丰富的中强酸分布;在反应温度为360℃、H_(2)/重芳烃原料摩尔比为3.0、反应压力为3.0 MPa、MHSV为3.0 h^(-1)的条件下,Mo/H-S80催化剂作用下碳九芳烃和碳十芳烃转化率分别为64.9%和62.7%,产物苯、甲苯和二甲苯的总选择性达到87.6%;对反应后Mo/H-S80催化剂的积炭分析结果表明,高硅MCM-22分子筛S80更易于扩散并转化重组分、控制副反应的发生,是高效轻质化的理想催化材料。

Static synthesis of high-quality MCM-22 zeolite with high SiO_2/Al_2O_3 ratio

We demonstrate a synthesis method to broaden the range of SiO2/Al2O3 ratio (30-100) of high-silica MCM-22 zeolites by prolonging the aging time of the gel before the crytallization. The synthesis conditions such as silica sources, chemical compositions of initial gel and aging time of gel were investigated in detail. High quality MCM-22 products with various morphologies have been synthesized by optimise their synthesis conditions. Our results show that increasing of the aging time can make the gel be homogenisation and promote their nucleus formation, which may avoid the for-mation of impurity phase and thus broaden the range of SiO2/Al2O3 ratio.

四丙基氢氧化铵处理时间对MCM-22分子筛及脱烯烃催化剂性能的影响

采用四丙基氢氧化铵(TPAOH)对工业HMCM-22分子筛进行处理,以处理后的分子筛为主要原料制备了MCM-22分子筛脱烯烃催化剂,优化了TPAOH的处理时间。使用XRD、N2吸附-脱附、SEM、Py-FTIR、NH3-TPD等方法对TPAOH处理后的MCM-22分子筛进行了表征,评价了催化剂对催化重整工序所得C8+芳烃中微量烯烃的脱除性能。表征结果显示,TPAOH处理后MCM-22分子筛相对结晶度增加,硅铝比降低,总比表面积和介孔比表面积增大,弱酸量与B、L酸量增多。实验结果表明,TPAOH处理后MCM-22分子筛制备的催化剂脱烯烃率提高,且无甲苯、苯生成,无芳烃损失;其中TPAOH处理时间为24 h的催化剂烯烃脱除率最高,为90.39%。

ZSM-22分子筛合成及其正十二烷烃临氢异构化性能:模板剂和动态晶化的影响

以二乙胺(DEA)或1,6-己二胺(DAH)为模板剂,分别在静态或动态条件下合成具有不同形貌和聚集状态的ZSM-22分子筛,采用XRD、SEM、EDS、TEM、NH3-TPD及N2吸附/脱附表征手段对其进行表征分析。并负载Pt在Al2O3上和ZSM-22机械混合制备双功能催化剂,考察其正十二烷的临氢异构化反应性能。结果表明,模板剂和动态晶化会改变ZSM-22分子筛的形貌及聚集状态,并且会影响其酸性、比表面积和临氢异构活性。其中,以二乙胺为模板剂,静态晶化72h合成的ZSM-22具有最优的催化性能,在310℃反应温度下,正十二烷异构化转化率为66%时,异构十二烷的选择性达到90%。但是,模板剂及动态晶化条件对单支链异构体的产物分布影响较小,异构体产物以支链靠近端位的2-甲基十一烷为主,且随着反应温度升高,2-甲基异构体选择性明显降低。

Hydroisomerization performance of platinum supported on ZSM-22/ZSM-23 intergrowth zeolite catalyst

Hydroisomerization catalysts Pt/ZSM-22, Pt/ZSM-23, and Pt/ZSM-22/ZSM-23 were prepared by supporting Pt on ZSM-22, ZSM-23, and intergrowth zeolite ZSM-22/ZSM-23, respectively. The typical physicochemical properties of these catalysts were characterized by X-Ray Diffraction （XRD）, N2 absorption-desorption, Pyridine-Fourier Transform Infrared （Py-FTIR）, Transmission Electron Microscopy （TEM）, X-Ray Fluorescence （XRF）, Scanning Electron Microscopy （SEM） and NH3- Temperature Programmed Desorption （NH3-TPD）, and the performance of these catalysts in n-dodecane hydroisomerization was evaluated in a continuous down-flow fixed bed with a stainless steel tubular reactor. The characterization results indicated that the intergrowth zeolite ZSM-22/ZSM-23 possessed the dual structure of ZSM-22 and ZSM-23, and the catalyst Pt/ZSM-22/ZSM-23 had similar pores and weak acidity to Pt/ZSM-22 and Pt/ZSM-23 catalysts. Moreover, Pt/ZSM-22/ZSM-23 catalyst showed a high selectivity in hydroisomerization of long chain n-alkanes to mono-branched isomers. The evaluation results for n-dodecane hydroisomerization indicated that the activity of Pt/ZSM-22/ZSM-23 was the lowest, while the hydroisomerization selectivity was the highest among the three catalysts. The maximum yield of i-dodecane product was 68.3% over Pt/ZSM-22/ZSM-23 at 320 ℃.

双有机结构导向剂合成高硅MCM-22分子筛及其催化性能

采用六亚甲基亚胺(HMI)和N,N,N-三甲基-1-金刚烷基氢氧化铵(TMAdaOH)为双有机结构导向剂(OSDA),通过对晶化时间、OSDA用量和投料硅铝比等参数的考察,优化了高硅铝比、高结晶度MCM-22分子筛的合成条件。采用X射线衍射(XRD)、扫描电镜(SEM)、氮气物理吸附-脱附、氨程序升温脱附(NH_(3)-TPD)、热重分析(TGA)等手段表征其物化性质,同时考察其催化三异丙苯(TiPB)裂解的性能。结果表明:在双有机结构导向剂的作用下,以宽投料硅铝比合成的MCM-22分子筛具有晶相纯、固体收率高、酸性质可调的优点;投料n(SiO_(2))n(Al_(2)O_(3))为60~100的高硅MCM-22分子筛催化三异丙苯裂解的性能比投料n(SiO_(2))n(Al_(2)O_(3))=30的常规MCM-22分子筛更好。

MCM-22分子筛用于二甲苯异构化的性能研究

以六亚甲基亚胺(HMI)作为模板剂,采用动态水热合成法合成不同硅铝比的MCM-22分子筛;以MCM-22分子筛作为酸性组分,负载铂制备转化型二甲苯异构化双功能催化剂(Pt MCM-22)。通过X射线衍射(XRD)、比表面积测试法(BET)、扫描电子显微镜(SEM)、傅里叶变换红外光谱(FT-IR)等测试手段对分子筛样品的形貌和性质进行表征。使用微型活塞流反应器对催化剂的反应性能进行评价,并与采用丝光沸石(MOR)分子筛制备的催化剂进行性能对比。结果表明,MCM-22分子筛用于二甲苯异构化反应具备优秀的异构化活性和反应选择性,且分子筛酸性质会影响其反应性能。

HYDROXYLATION OF PHENOL BY IRON(Ⅱ)-PHENANTHROLINE(PHEN)/MCM-41 ZEOLITE

MCM-41 zeolite and Iron (Ⅱ) -Phen/MCM-41 zeolite have been preparedand characterized by XRD,IR, NH3-TPD, BET and UV-Vis. The Iron(Ⅱ)-Phen/MCM-41 zeolite+30% H2O2 system is capable for catalyzing hydroxylation of Phenol.

静态水热晶化法高效合成MCM-22分子筛

采用静态水热晶化法 ,在Na2 O Al2 O3 SiO2 HMI H2 O(HMI :六亚甲基亚胺 )体系中 ,在HMI/SiO2 摩尔比为 0 0 9,H2 O/SiO2 摩尔比为 12 ,晶化时间为 6 0～ 80h的条件下 ,合成了MCM 2 2分子筛 .利用固体硅胶表面的吸附性能提高模板剂的局部浓度 ,从而实现了分子筛的高效合成 .对合成条件的研究结果表明 ,以比表面积 (4 86m2 /g)大、反应性能好的硅胶为硅源是静态水热晶化法高效合成MCM 2 2分子筛的关键 ,而成胶老化方式对MCM 2 2分子筛的晶化影响不大 .产物的晶相和转晶的类型取决于合成凝胶的初始硅铝比 .当SiO2 /Al2 O3 摩尔比 =18～ 80时可以合成出MCM 2 2 ,当SiO2 /Al2 O3 =13～ 17时可以合成出MCM 49.硅铝比较低 (如SiO2 /Al2 O3 =2 0 )时 ,MCM 2 2分子筛易转晶为MOR分子筛 ,而在硅铝比较高 (如SiO2 /Al2 O3 =5 0 )时 ,可转晶为ZSM

BETA和MCM-22沸石在丙烯与苯烷基化反应中的催化性能

以六亚甲基亚胺为模板剂,采用动态晶化水热法合成了MCM-22沸石,并对其进行了物相表征。采用XRD、TG、FT-IR等手段测定了BETA及MCM-22沸石的孔结构和酸性质,还考察了它们的活性、稳定性以及对产物的选择性。结果表明,催化剂的活性和稳定性与催化剂的酸性和孔结构有密切关系。BETA沸石比MCM-22沸石的初始活性高、稳定性低。在相同的反应条件下,就催化反应的产物中目的产物异丙苯(以丙烯为基准计)的选择性而言,MCM-22沸石比BETA沸石低1％～2％;就正丙苯的含量而言,MCM-22沸石比BETA沸石低3～4倍。

MCM-22沸石的孔结构和酸分布特性对苯与丙烯烷基化反应产物分布的影响

根据测试结果 ,得到了MCM 2 2和具有相同硅铝比的 β沸石的酸中心数及其分布 ,系统地研究了反应条件对苯与丙烯烷基化反应产物分布的影响 ;结合扩散系数与扩散势能 ,讨论了产物分布与MCM 2 2沸石孔道及酸性质的关系 ,并与 β沸石进行了比较 .苯烷基化反应发生在MCM 2 2沸石的外表面上 ,其空间位阻较小 ;在相同的反应条件下 ,与发生在 β沸石十二元环孔道内的苯烷基化反应相比 ,异丙苯的选择性低 2 %～ 4%,二异丙苯的选择性高 0 5 %～ 5 %,三异丙苯的生成量多 10余倍 .位于MCM 2 2沸石十元环二维正弦波形孔道的B酸中心 ,由于空间位阻大 ,很难发生苯烷基化反应 ,但可发生丙烯齐聚反应 ,故MCM 2 2沸石上有较多的丙烯齐聚物生成 .β沸石上生成正丙苯的量是MCM 2 2沸石上的 3～ 4倍 .

MCM-22分子筛的稳定性研究

采用三段晶化法合成了MCM-22分子筛,研究了MCM-22分子筛的热稳定性,分别用盐酸、NaOH和铵盐溶液在沸腾条件下处理MCM-22分子筛6h,考察MCM-22分子筛对酸、碱、铵盐的稳定性。实验结果表明,MCM-22分子筛的热稳定性较好,当焙烧温度达950℃时,MCM-22分子筛的相对结晶度下降30%,骨架结构基本保持不变;MCM-22分子筛的相对结晶度随盐酸浓度的增加而略有下降,但骨架结构保持不变,MCM-22分子筛具有良好的耐酸性;当c(NaOH)≤2mol/L时,MCM-22分子筛结构完全被破坏,成为无定形物,当c(NaOH)>3mol/L时,不仅原分子筛结构全部破坏,且形成了新的化合物,MCM-22分子筛的耐强碱性较差;MCM-22分子筛经1.5mol/L的NH4F溶液处理后,骨架结构完全被破坏,但对其他铵盐表现出较好的稳定性。

酸碱双功能MgO/HMCM-22催化剂上Knoevenagel缩合反应

采用浸渍法制备了一系列MgO改性催化剂MgO/HMCM-22,利用X射线衍射、N2物理吸附-脱附、扫描电镜、傅里叶变换红外光谱、NH3及CO2程序升温脱附等技术对所制催化剂进行了表征.结果表明,MgO改性后MCM-22分子筛仍保持原有的结构;随着MgO负载量的增加,催化剂的碱强度和碱含量显著增加,而强酸含量明显减少,弱酸酸位有所增加.以Knoevenagel缩合为探针反应,考察了所制催化剂的性能.在优化的反应条件下,MgO/HMCM-22上苯甲醛转化率高达92.6%.催化剂MgO/HMCM-22和MgO/NaMCM-22的催化性能明显优于HMCM-22和MgO.酸中心和碱中心均对该缩合反应起着重要的促进作用.MgO/HMCM-22对Knoevenagel缩合反应显示出较高的催化活性,体现出明显的酸碱协同催化作用.

磷改性MCM-22分子筛上苯与1-十二烯烷基化合成十二烷基苯

采用浸渍法制备了一系列用于苯和1-十二烯烷基化合成十二烷基苯的磷改性MCM-22分子筛,以X射线衍射(XRD)和固体27Al3、1P核磁共振,N2吸附,氨程序升温脱附(NH3-TPD),热重(TG)和红外光谱(FT-IR)等表征技术,结合固定床连续流动反应器中的性能评价,较为系统地研究了磷改性对MCM-22分子筛的结构、表面酸性及其烷基化催化性能的影响.结果表明,用磷改性MCM-22分子筛虽然不会影响分子筛的晶体结构,但是会破坏分子筛上的Si-O-Al键,使部分四配位铝转化为六配位铝.由于聚合态的磷酸盐可能与Al发生键合,多聚态磷酸盐数量随着磷含量的增加而增多,从而改变了分子筛的孔道大小和酸性,使得强酸减少,弱酸增多,酸强度降低,总酸量和B酸中心数随着磷含量的增加呈现先增后减的规律,L酸减少.适当的磷含量有利于提高MCM-22分子筛对苯与1-十二烯烷基化反应的催化选择性和稳定性,改性磷含量为0.5%左右时产物2-十二烷基苯收率最高.

Co改性Mo/MCM-22催化剂上甲烷无氧芳构化及积炭研究

研究了Co的添加对Mo/MCM 2 2催化剂甲烷无氧芳构化反应性能的影响 .发现用共浸渍法制备的Co/Mo摩尔比为 0 2的催化剂具有较高的活性 ,而先浸渍Mo后浸渍Co的催化剂具有较好的稳定性 .XRD实验表明 ,Co及Mo的氧化物均高度分散在分子筛表面 ,其担载降低了分子筛的衍射强度 .不同接触时间下催化剂的反应结果表明 ,接触时间长 ,积炭选择性随接触时间增加而迅速增加 ;接触时间短 ,积炭选择性随接触时间增加而减少 .积炭催化剂的TG研究表明 ,催化剂上的积炭主要有两种形式 .低温积炭随反应时间增加而迅速增多 ,高温积炭的变化则较为缓慢 .低温积炭可能是导致催化剂活化和失活的主要原因 .高温积炭可能是一种大分子量的碳氢物种 ,位于MCM 2 2分子筛的“超笼”中 ,表明MCM 2

不同形貌MCM-22分子筛的合成及其催化性能

在MCM-22分子筛的合成中,通过调节水热晶化参数、改变硅源及搅拌条件,得到了具有片状、饼状、球形且晶粒尺寸不同的MCM-22分子筛,采用XRD、SEM和氮气物理吸附对样品进行表征,并考察了其在连续固定床苯与乙烯液相烷基化反应及在1,3,5-三异丙苯裂解反应中的催化性能。结果表明,MCM-22分子筛的形貌对其催化性能影响显著,晶粒尺寸越大、聚集程度越高,其在苯烷基化反应和1,3,5-三异丙苯裂解反应中的催化性能越差。