中心切割二维GC-MS法测定煤直接液化加氢改质油组成

采用SYD-6536C石油产品蒸馏试验器取煤直接液化加氢改质全馏分油55.2～138.2℃的馏分段,建立了一种运用中心切割二维GC-MS法研究其单体烃组成的分析方法。实验采用PONA毛细管气相色谱柱(50m×200μm×0.5μm)对色谱条件进行优化,找到煤直接液化加氢改质油55.2～138.2℃馏分段的最佳分离条件。被测样品首先在第一根色谱柱上进行分离,然后使用Dean Switch微流控制系统把目标化合物切割至第二根色谱柱(DB-35MS 30m×250μm×0.25μm)上,进一步分离。实验将烃类化合物在PONA柱上的色谱保留规律、化合物保留指数、标准化合物保留值及质谱谱库检索等多种方法联合对煤直接液化加氢改质油在55.2～138.2℃的馏分段中66种化合物进行定性分析。鉴于被测油样中化合物的结构性质相近,忽略化合物相对校正因子的影响,采用面积归一化法NORM%进行定量分析。该方法方便快捷、精确度高,适用于低馏分段的煤直接液化加氢改质油的分析,同时也为高馏分段煤直接液化加氢改质油和其他种类油样的单体烃组成分析提供了参考。     

球状纳米介孔碳和HZSM-5分子筛在二苯并噻吩吸附脱硫中的应用

采用软模板法制备了粒径范围为50 nm～100 nm的球状纳米介孔碳(MCN),与HZSM-5分子筛机械混合获得介/微孔混合吸附剂,用于二苯并噻吩的吸附脱硫研究。XRD、BET、SEM和TEM等分析结果表明,MCN比表面积为214 m²/g,孔径为5.1 nm,混合吸附剂的比表面积、孔容、孔径均处于MCN和HZSM-5分子筛两者之间,且两者混合均匀。吸附脱硫实验表明,HZSM-5分子筛对二苯并噻吩的吸附脱硫率最差(脱硫率4.8%),而MCN的脱硫性能最优(脱硫率70%),混合吸附剂中随MCN含量增加二苯并噻吩的吸附脱硫性能逐渐提高,且MCN表现出了较好的可重复性能,经过4次循环后吸附容量保留率为79%。Freundlich等温模型比Langmuir等温模型更适合描述二苯并噻吩在上述吸附剂表面的吸附过程,吸附动力学实验数据说明二苯并噻吩在该系列吸附剂上的吸附更符合二级动力学模型。     

用TPD法研究不同硅铝比的HZSM-5分子筛的酸性质及其催化能

本文用动态程序升温热脱附法研究了不同硅铝比的HZSM-5分子筛吸附氨的程序升温热脱附谱及其酸性质。结果表明,当硅铝比的效值小子47时,HZSM-5分子筛吸附氨的酸中心数与单跑中铝原子效呈线性递增关系。当硅铝比大于47时,则偏离了该线性关系。不同硅铝比的HZSM-5分子筛的酸强度随着硅铝比的下降而增强,它们的甲苯歧化活性与其单胞中铝原子数亦有线性递增关系,随着铝原子数的增加,催化活性提高,而选择性下降。     

聚乙烯吡咯烷酮对油中酚类物质的吸附性能

煤焦油中酚类物质的有效分离,可实现其高附加值利用。针对酚类物质的分离,本研究采用聚乙烯吡咯烷酮(PVP)为吸附剂,研究了其对模型油中邻甲酚、间甲酚、对甲酚、1-萘酚和2-萘酚等的吸附性能。研究发现,PVP对酚类物质具有较大的吸附容量,其中对间甲酚、对甲酚、1-萘酚和2-萘酚的最大吸附量均可达1000 mg/g以上。同时发现,PVP上的Lewis碱性位点(C=O和C-N)可与酚羟基之间形成氢键作用,该作用的强度受酚类物质空间位阻影响。PVP具有一定的吸附选择性,在苯并呋喃或喹啉存在下,依然能够有效吸附2-萘酚。此外,使用过的PVP可再生并重复利用,同时实现酚的回收。可见,PVP是一种可用于分离煤焦油中酚类物质的优良吸附剂。     

Effects of silicon to aluminum ratio and crystal size of zeolite on catalytic properties of Cu-ZnO-Al2O3/HZSM-5 for the direct synthesis of dimethyl ether from syngas

采用水热晶化法合成了硅铝比(SiO2/Al2O3)为60、120、200和晶粒粒径分别为1.00和0.25μm的HZSM-5分子筛,并以其为甲醇脱水活性组分与铜基甲醇合成活性组分(Cu-ZnO-Al2O3)组成双功能催化剂(Cu-ZnO-Al2O3/HZSM-5),在连续流动加压固定床反应器上考察了Cu-ZnO-Al2O3/HZSM-5对合成气直接制二甲醚反应的催化性能.结果表明,随着分子筛硅铝比的提高,二氧化碳副产物的生成量逐渐减少,从而使目的产物二甲醚的选择性逐渐增大.与常规分子筛相比,小晶粒分子筛的反应活性接近,但二氧化碳和烃类副产物的选择性较低.     

Sb2O3与HZSM-5的相互作用

研究了氮气气氛下于500℃处理2h后的Sb₂O₃/HZSM-5体系中Sb₂O₃在分子筛表面上的分散行为.发现处理后的体系中Sb₂O₃晶相消失,HZSM-5晶相减少,非晶相增加.经XRD相定量、氮气吸附、正己烷吸附及NH₃-TPD实验可知,高温下酸性Sb₂O₃破坏了分子筛的部分骨架,生成无定形硅铝胶,同时Sb₂O₃高分散在其中.含Sb₂O₃的无定形硅铝胶修饰了分子筛表面,减小了孔口,提高了分子筛在甲苯烷基化反应中的择形性能,对二甲苯的选择性可高达89.     

分子筛硅铝比及晶粒粒径对 Cu-ZnO-Al2O3/HZSM-5催化剂直接合成二甲醚反应性能的影响

采用水热晶化法合成了硅铝比(SiO₂/Al₂O₃)为60、120、200和晶粒粒径分别为1.00和0.25 μm的HZSM-5分子筛,并以其为甲醇脱水活性组分与铜基甲醇合成活性组分(Cu-ZnO-Al₂O₃)组成双功能催化剂(Cu-ZnO-Al₂O₃/HZSM-5),在连续流动加压固定床反应器上考察了Cu-ZnO-Al₂O₃/HZSM-5对合成气直接制二甲醚反应的催化性能。结果表明,随着分子筛硅铝比的提高,二氧化碳副产物的生成量逐渐减少,从而使目的产物二甲醚的选择性逐渐增大。与常规分子筛相比,小晶粒分子筛的反应活性接近,但二氧化碳和烃类副产物的选择性较低。     

Fe-Zn-M/HZSM-5复合催化剂上CO_2加氢性能的研究

研究了 380℃、 5 .0 MPa条件下 ,在 Fe- Zn- M/ HZSM- 5 (M=Cr、 Al)复合催化剂上进行的 CO2 催化加氢的反应 .考察了 Fe- Zn- M中 Fe含量、分子筛的硅铝比及 Fe- Zn- M/ HZSM- 5的比率对 CO2 转化率和产物选择性的影响 .结果表明 ,随着 Fe含量的增加 ,复合催化剂的活性增强、目的产物选择性降低 ;Fe- Zn- M与 HZSM- 5间有适宜的配比 ;分子筛的硅铝比影响到复合催化剂的活性和选择性 ,随着分子筛硅铝比的降低 ,复合催化剂的活性增强 ,目的产物选择性提高     

H-ZSM-5分子筛硅铝比对其催化的甲醇转化丙烯选择性的影响（英文）

本研究合成了一系列硅铝比不同(SiO_2/Al_2O_3=50-4000),但晶粒粒径相近的ZSM-5分子筛,并考察了硅铝比对甲醇转化反应丙烯选择性的影响。采用XRD、N_2吸附-脱附、NH_3-TPD和Py-FTIR方法对合成的HZSM-5分子筛进行物化性质表征。实验结果表明,随着硅铝比的增大,初始甲醇转化率降低,其中,硅铝比为50-1600的样品可以实现甲醇的完全转化。在甲醇完全转化的条件下,随着硅铝比的增大,丙烯选择性单调增加,从机理角度出发,揭示了甲醇转化制丙烯反应中,甲基化/裂化循环相较于甲基化/脱烷基化循环进行程度更大。此外,本研究提出了在甲醇完全转化条件下,保证最大丙烯选择性所需要的临界酸密度值([AS]_S),当甲醇进料量为0.162 g/min时,该临界值为0.175μmol/m~2。     

纳米薄层HZSM-5分子筛催化甲醇制丙烯

在合成系列硅铝比纳米薄层HZSM-5分子筛的基础上,研究了纳米薄层HZSM-5分子筛催化甲醇制丙烯(MTP)的反应性能.在固定床微反装置上详细考察了工艺条件对纳米薄层HZSM-5分子筛催化性能的影响,同时与纳米HZSM-5分子筛对MTP反应的催化性能进行了比较.结果表明,纳米薄层HZSM-5分子筛具有较高的目的产物选择性和较长的催化寿命.在适宜硅铝比(n(SiO2)/n(Al2O3)=213)和反应条件下(温度470°C,甲醇质量空速为3 h-1),丙烯的选择性达到46.7%,三烯(乙烯、丙烯和C4烯烃)选择性达到78.7%.其中,丙烯/乙烯的质量比可达到6.5,是纳米HZSM-5分子筛的2倍,而芳烃的选择性比纳米分子筛明显降低.这是因为纳米薄层HZSM-5分子筛比纳米HZSM-5分子筛具有较宽的(010)晶面、较大的外比表面积和介孔孔容.     

Kinetic separation of carbon dioxide and methane on a copper metal-organic framework

Separation of carbon dioxide and methane is an important issue in upgrading low-quality natural gas. Adsorption equilibria and kinetics of CO(2) and CH(4) on a copper metal-organic framework (MOF), Cu(hfipbb)(H(2)hfipbb)(0.5) [H(2)hfipbb=4,4'-(hexafluoroisopropylidene) bis(benzoic acid)], were investigated to evaluate the feasibility of removing CO(2) from CH(4) in a pressure swing adsorption process using this new MOF adsorbent. The heat of adsorption of CO(2) on the Cu-MOF at zero-coverage (29.7 kJ/mol) is much lower than those on a carbon molecular sieve and a zeolite 5A adsorbent; and the heat of adsorption of CH(4) on the Cu-MOF (21.4 kJ/mol) is similar to that on the zeolite 5A adsorbent and smaller than that on a carbon molecular sieve. The Cu-MOF being investigated has apertures of (~3.5 × 3.5 ?), which favors the kinetically controlled separation of CO(2) and CH(4). The kinetic selectivity is found to be 26 at 298 K, and the overall selectivity (combining the equilibrium and kinetic effects) is about 25 for an adsorption separation process. These results suggest that the Cu-MOF adsorbent is an attractive alternative adsorbent for the CO(2)/CH(4) separation.     

Adsorption separation performance of H2/CH4 on ETS-4 by concentration pulse chromatography

To exploit an effective adsorbent to separate hydrogen and methane, microporous titanium silicate molecular sieve NaETS-4 was synthesized and modified by strontium. The adsorption characteristics and diffusion behaviors of the prepared titanosilicate molecular sieve were studied by concentration pulse chromatography. And the effects of ion-exchange and dehydration temperature on adsorbent structure and gas diffusion were also discussed. The results showed that the thermal stability and Henry＇s Law constants were enhanced and micropore diffusivity decreased after exchanging Na＋ with Sr2＋. With the increase of dehydration temperature, Henry＇s Law constant and micropore diffusivity of CI-I4 decreased in both NaETS-4 and SrETS-4. While for 1-12 in SrETS-4, the increase of Henry＇s Law constant and the decrease of diffusion rate can be attributed to the shrinks of pore diameter resulting from the relocation of Sr2＋. Correspondingly, the kinetic selectivity of H2/CH4 reached 8.91 indicating its potentiality in separating H2 and CH4.     

Protein adsorption on the mesoporous molecular sieve silicate SBA-15: effects of pH and pore size

A mesoporous molecular sieve silicate, SBA-15, with three pore sizes (38.1 A, 77.3 A, and 240 A) has been synthesized using a non-ionic, tri-block copolymer as a template in a sol-gel method. The effects of synthesis conditions on the pore size and pore-size distribution of this adsorbent have been described. The adsorption of proteins on these crystalline, ordered, materials has been studied. The kinetics of adsorption and equilibrium capacity have been probed with three proteins of different dimensions. The effects of electrostatic interactions and protein size are illustrated. It has been shown that SBA-15 materials can be tailored to show size selectivity for proteins, and very high capacities (450 mg/g) can be obtained. Furthermore, the rates of adsorption are shown to be dependent on the pore size, protein structure and solution pH.     

HZSM-5分子筛用于合成聚甲醛二甲基醚

以磷酸二氢铵为前驱体,使用浸渍法制备了一系列不同磷含量改性的HZSM-5分子筛,并结合X射线衍射、N2吸附和氨程序升温脱附等表征结果探讨了催化剂硅/铝比、粒径尺寸、晶体结构、孔结构及表面酸性对其催化甲醇和三聚甲缩反应生成聚甲醛二甲基醚(PODEn)反应性能的影响,同时与商业催化剂进行了比较.结果表明,硅铝比为50,粒径尺寸为5μm,P2O5含量较低(0～6%)的HZSM-5分子筛表现出较高的催化活性和PODEn选择性.在130℃,原料甲醇和三聚甲醛的质量比为2:1的优化条件下反应时,三聚甲醛转化率可达到95.2%,PODEn(n=2～5)的选择性为62.9%,略好于商业催化剂.     

基于Fe负载的HZSM-5催化热解制备生物油实验研究

通过离子交换法制备含2%Fe(质量分数)的HZSM-5催化剂,采用X射线衍射仪(XRD)、激光粒度分析仪以及比表面积及孔径分析仪对催化剂进行表征,并在550℃下进行木屑的催化热解实验。对无催化剂和不同比例催化剂条件下得到的生物油进行GC-MS分析,结果表明,在Fe负载的HZSM-5作用下,生物油产率明显升高(最大增幅7%),轻质组分产率明显升高,重质组分产率略微升高。同时,轻质组分中的酮类、呋喃等含氧化合物含量降低,酚类、酸含量升高;重质组分中的酮类、呋喃类等含氧化合物含量明显降低,酚类、萘类含量明显增多。Fe负载的HZSM-5催化剂对木屑的热解反应有较好的催化效果,加强了对热解初始蒸汽的择形修饰,从而抑制了生物质三组分木质素初始热解产物中的醌类等容易一次或二次结焦物质的生成,孔道结构对蒸汽的二次反应被抑制,产物向较小分子的轻质产物上富集。     

Adsorption separation performance of H2/CH4 on ETS-4 by concentration pulse chromatography

To exploit an effective adsorbent to separate hydrogen and methane, microporous titanium silicate molecular sieve NaETS-4 was synthesized and modified by strontium. The adsorption characteristics and diffusion behaviors of the prepared titanosilicate molecular sieve were studied by concentration pulse chromatography. And the effects of ion-exchange and dehydration temperature on adsorbent structure and gas diffusion were also discussed. The results showed that the thermal stability and Henry's Law constants were enhanced and micropore diffusivity decreased after exchanging Na⁺ with Sr²⁺. With the increase of dehydration temperature, Henry's Law constant and micropore diffusivity of CH₄ decreased in both NaETS-4 and SrETS-4. While for H₂ in SrETS-4, the increase of Henry's Law constant and the decrease of diffusion rate can be attributed to the shrinks of pore diameter resulting from the relocation of Sr²⁺. Correspondingly, the kinetic selectivity of H₂/CH₄ reached 8.91 indicating its potentiality in separating H₂ and CH₄.     

树脂填充聚醚砜纤维吸附剂对牛血清蛋白吸附性能的研究

重点研究树脂填充聚醚砜(PES)纤维吸附剂与模型蛋白质牛血清蛋白(BSA)之间的吸附与脱附行为.结果表明,蛋白质BSA在树脂填充PES纤维吸附剂中的平衡吸附过程较好地符合朗格缪尔吸附模型,树脂Lewatit CNP80ws填充PES吸附剂的最大吸附容量约为139mg BSA/g吸附剂.表面具有开孔结构的树脂填充PES纤维吸附剂的吸附速率较快,在不同结构纤维吸附剂中BSA的扩散系数在1·82×10-14~8·7×10-14m2/s范围内变化.另外,考察了BSA溶液的pH与洗脱剂等因素对吸附剂吸附与脱附性能的影响,研究结果对蛋白质的实际分离纯化具有重要的参考价值.     

Molecular Exclusion Separation of 1-Butene Isomers by a Robust Metal–Organic Framework under Humid Conditions

Separating n-butene and i-butene by adsorption is an energy-efficient alternative, but designing porous adsorbents that distinguish the subtle differences between the isomers is extremely challenging. Currently, adsorbents that can sieve 1-butene isomers and are stable enough to withstand humid gas mixtures are largely unmet. Herein, we propose a robust ultramicroporous metal–organic framework (MET-Fe) that can separate 1-butene isomers through molecular exclusion. The pore aperture size (4.6 Å) precisely matches the kinetic diameters of the isomers, as verified by static and kinetic adsorption experiments and theoretical calculations. Furthermore, dynamic breakthrough experiments confirmed the excellent separation performance, easy regeneration, and remarkable reusability of MET-Fe in both dry and humid conditions. With its high selectivity, large breakthrough capacity, and outstanding stability, MET-Fe provides an ideal platform for industrial butene isomers separation.     

Simulation of pressure swing adsorption modules having laminated structure

A mathematical model was formulated for the bulk separation of binary gas mixtures in micro-structured pressure swing adsorption (PSA) modules consisting of parallel channels lined with adsorbent. Axial and radial dispersion in the gas phase and mass transfer resistance in the adsorbent phase were taken into consideration. The partial differential equations governing the concentration profiles in the gas and adsorbent phases were solved by orthogonal collocation. The model enabled the prediction of the concentration profiles in both the gas and adsorbent phases (as a function of location and time), the product purity and the separation efficiency. The effects of model parameters and operating conditions on the module performance were investigated. Simulation of oxygen enrichment from air by molecular sieve 13X indicated that long modules with thin layers of adsorbent, narrow gas flow channel heights and large numbers of flow channels give the best separation.