离子液体在低碳烯烃/烷烃分离中的应用研究进展

低碳烯烃/烷烃的高效分离是石油化工领域可持续发展的关键过程之一,传统的低温精馏过程选择性低、能耗大。离子液体作为一种结构可调的绿色溶剂为低碳烃的高效分离提供了新的思路。本文综述了近年来国内外离子液体在低碳烯烃/烷烃分离中的研究进展,总结了常规离子液体、功能化离子液体以及含过渡金属的离子液体在低碳烯烃/烷烃分离中的应用,阐明了离子液体中阴阳离子、功能化基团、过渡金属与低碳烯烃相互作用的机理,着重介绍了合成金属功能化离子液体、添加金属盐、添加金属纳米粒子3种向离子液体中引入过渡金属方式的特点以及过渡金属的种类、比例,有机配体的类型对离子液体烯烃/烷烃分离性能的影响,并探讨了该方向的研究和发展趋势。     

多孔材料烷烃/烯烃分离技术的研究

以模拟油品为原料,在小型固定床（200 mL）反应器上考察了硅胶、γ-Al₂O₃、13X分子筛、Y分子筛及ZSM-5分子筛等多孔材料对烷烃/烯烃的吸附分离性能;其中硅胶的烷烃/烯烃分离效果最好,在吸附温度为40 ℃、压力为0.5 MPa、解吸剂为正辛烷/甲基环己烷的条件下,烷烃/烯烃分离度最高达到0.81;与其他类型硅胶相比,平均孔径为4~6 nm的B型硅胶传质效果更好,吸附-脱附过程更易趋于平衡。经过焙烧和溶剂再生的吸附剂,与新鲜剂相比,分离效果没有明显的降低。     

丝素蛋白在离子液体中的溶解特性研究

文章以离子液体为溶剂,研究了丝素蛋白在离子液体中的溶解特性。首先研究了丝素蛋白在不同结构的离子液体1-烯丙基-3-甲基咪唑氯化物（[AMIM]C1）和1-丁基-3_-甲基咪唑氯化物（[BMIM]c1）中的溶解速率和溶解度。结果发现,相同条件下,丝素蛋白在[AMIM]cl中具有较快的溶解速率和较大的溶解度;随温度的升高,溶解速度加快,合适的温度为95～105℃;随着丝素蛋白浓度的增大,相同条件下丝素蛋白在离子液体中的溶解速度减慢。XRD结果表明,丝素蛋白的非晶相部分首先被溶解,晶相部分结构被破坏后与溶剂作用逐渐被溶解。采用粘度法测定了丝素蛋白分子质量随溶解时间和温度的变化,结果表明：随加热时间增加和温度升高,蛋白质分子质量减小。为保证丝素蛋白的稳定性和溶解速率,温度一般控制在100℃以下,溶解时间小于5h。     

离子液体萃取分离烃类化合物的研究进展

溶剂萃取分离技术广泛应用于石油化工领域,为石油石化产品的分离和提纯生产提供了有力的技术支撑。离子液体的结构可设计性、化学稳定性和热稳定性、极低的蒸气压等优点,使其在烃类化合物分离领域受到了研究者广泛关注。本文首先介绍了离子液体的性质及分类,根据分离目标不同,归纳了离子液体在芳烃-饱和烃分离、脱硫脱氮、烯烃-烷烃分离领域取得的最新进展,探讨了离子液体在油品分离领域研究中存在的问题和未来发展方向。文中指出：阳离子烷基侧链和极性是影响其对芳烃萃取效果的关键因素,然而对实际体系芳烃-饱和烃分离还有待进一步研究;离子液体对杂原子含硫含氮化合物均表现出较强的分离能力,但是碱性氮化物和非碱性氮化物不易通过一种离子液体同时脱除;氢键碱性是影响离子液体分离烯烃的关键因素,然而大部分离子液体对烯烃选择性仍然不高。根据不同的分离任务,从分子水平上认识离子液体结构与分离效果的关系,进而设计出兼具高效分离能力和低环境影响的新型离子液体,对提升油品中关键组分的高附加值转化利用具有重要意义。     

SAPO-34分子筛应用研究进展

综述了SAPO-34分子筛催化低碳物转化制低碳烯烃(甲醇、二甲醚、卤化烷烃制烯烃、乙醇脱水制乙烯)、C_4～C_8直链烯烃/烷烃裂解制低碳烯烃、烷烃氧化或直接脱氢反应制烯烃、催化烃类或H_2选择性还原NO_x、制备膜分离材料以及在发光体材料等领域中的应用。系统分析sAPO-34分子筛在各领域应用进展,有利于理解材料的物化性能对其催化性能、热稳定性及水热稳定性、选择性渗透和分子筛分离性能的影响,有利于实现对SAPO-34分子筛的认识取得突破性进展,拓展SAPO-34分子筛应用领域,并为其他催化材料的设计提供借鉴。     

离子液体[BMIM]OH对SO_2的吸收性能

为了开发可以循环利用、绿色化的环境友好型脱硫剂,以离子液体[BMIM]OH为吸收剂,研究了其对气体SO_2的溶解性能,考察了温度对吸收过程、解吸过程的影响,以及纯离子液体和负载硅胶后的离子液体的循环吸收能力。研究结果表明,在0.1 MPa,25℃时的平衡吸收量达每1 mol ILs吸收1.84 mol SO_2,溶解量随温度的升高而减少。吸收后的[BMIM]OH可以通过加热的方式进行解吸,6次循环实验的平均解吸率达到了99.3%,平均每1 mol的离子液体能够解吸出1.47 mol SO_2。采用硅胶负载后的离子液体仍表现出良好的循环吸收和解吸能力,4次循环的平均解吸率为96.6%。[BMIM]OH有望应用于工业过程中SO_2的分离与回收。     

用于CO_2分离的[bmim][Tf_2N]-PAN共混膜制备及性能

咪唑类离子液体对CO2有良好的溶解性,利用其进行气体分离可以同时提高膜对CO2的选择性和渗透性。利用1-丁基-3-甲基咪唑双三氟甲磺酰亚胺([bmim][Tf2N])离子液体对CO2具有较高的溶解选择性,将[bmim][Tf2N]和聚丙烯腈(PAN)共混制备膜液,涂覆在聚丙烯(PP)支撑层上,利用溶剂蒸发法制备共混复合膜。结果表明,[bmim][Tf2N]的添加对复合膜气体分离性能有明显提高,在离子液体质量分数达到50%后,离子液体逐渐变为连续相,增加了CO2气体的传递通道;气体渗透性能显示其CO2渗透速率可达34.76 GPU,CO2/N2和CO2/CH4理想选择性分别可达49.51和25.14;在随后改变操作压力和测试温度的实验中发现,增大跨膜压差和测试温度均有利于复合膜渗透速率的提升。     

低压下[C6mim][PF6]用于二氧化碳吸收及解吸性能研究

研究了接近1 atm、293～333 K条件下[C6mim][ PF6]静态吸收二氧化碳的动力学特性,结果表明,温度和真空度对解吸效率有显著影响.363 K时该离子液体对吸收二氧化碳后解吸率达到66.67％,而真空条件下,室温时的解吸率就能达到95％.探讨了吸收-解吸循环使用次数及保存时间对该离子液体吸收-解吸二氧化碳性能的影响,发现吸收-解吸过程中[ C6mim][ PF6]的质量损失率低于0.05％,经过58次循环及约240天保存后,其吸收二氧化碳的容量和速率未发生明显改变.同时对其吸收过程的活化能及溶解焓等参数进行了拟合计算:Ea为5 836.93 J/mol,△H为10 957.66 J/mol.     

PEG基功能化离子液体的脱硫性能

合成一系列含有长醚链的PEG基咪唑对甲苯磺酸盐(PEG基功能化离子液体), 检测其脱硫与再生性能, 并测定其脱硫过程中物性(密度、黏度和表面张力)变化。结果表明, PEG基功能化离子液体具有良好的脱硫与再生性能, 而且该离子液体的脱硫性能随醚链增长而增强, 20℃时SO₂与离子液体摩尔比达到5.51以上, 吸收的SO₂在80℃条件下可彻底解吸。由¹H NMR图谱和Raman光谱分析结果表明, PEG基咪唑功能化离子液体对SO₂的吸收为物理吸收。脱硫后的PEG基功能化离子液体密度增大, 表面张力减小, 黏度较脱硫之前显著降低。     

催化裂化汽油临氢异构化/芳构化改质过程的反应特性

采用工业Ni-Mo/Al₂O₃-HZSM-5催化剂在小型固定床加氢微反装置上对催化裂化（FCC）汽油临氢改质过程的反应特性进行了研究,通过考察反应温度、压力、空速和氢油体积比对改质后的FCC汽油烃类组成的影响,分析了汽油中不同烃类的转化性能。结果表明,氢油比对产物组成影响不大,高温、低压、低空速有利于增加芳烃的选择性,低温、高压、高空速则有利于增加异构烷烃的选择性;临氢改质后,FCC汽油的烯烃含量明显降低,芳烃和异构烷烃含量增加,因而产品汽油的辛烷值基本保持不变;全馏分、轻馏分和重馏分FCC汽油临氢改质实验结果表明,烯烃含量较高的轻馏分具有更高的转化活性;在FCC汽油临氢改质过程中,同碳数的端烯烃反应活性高于内烯烃,直链烯烃的反应活性高于支链烯烃。     

Solubility of light alkanes and alkenes in ionic liquids

The solubility of light hydrocarbons in a variety of ionic liquids was studied, and it was found that ionic liquids containing Cu(Ⅰ) had higher solubility for hydrocarbons and alkene/alkane solubility selectivity, and Et₃NHCl-2.1CuCl ionic liquid was preferred. The effects of temperature and pressure on the solubility of light hydrocarbons were investigated for the selected ionic liquid. It was found that low temperature and high pressure were favorable for the dissolution of light hydrocarbons, and the alkene/alkane solubility selectivity decreased with the increase of temperature and pressure. The alkene/alkane solubility selectivity was above 8.3 at the temperature of 30℃ and the pressure of 0.2 MPa. The initial dissolution rate of hydrocarbons in ionic liquid was large, but it decreased rapidly with prolonging time, and the dissolution rate of alkenes was higher than that of alkanes at the same conditions. The alkene/alkane separation selectivity increased with decreasing content of alkenes in the mixture of alkenes and alkanes. Light hydrocarbons dissolved in ionic liquids could be desorbed by means of increasing temperature, restoring the dissolution capability of ionic liquids to hydrocarbons. Alkanes were easier to be desorbed than alkenes, and small-molecule hydrocarbons were easier to be desorbed than large-molecule hydrocarbons. The desorption percentage exceeded 92% under optimal conditions. Ionic liquid had a good reusable performance in the absorption and separation of light alkanes and alkenes. The solubility only decreased by less than 5% when it was reused five times, and the alkane/alkane solubility selectivity was basically not affected by reusing times. Software Gaussian 09 was used to study the interaction between anions of ionic liquids and light alkanes and alkanes, and the solubility difference of light alkenes and alkanes in different ionic liquids was well explained.     

Comparison of adsorption behaviour of light alkanes and alkenes on Kureha activated carbon

Adsorption equilibria of light alkanes and alkenes on Kureha activated carbon were investigated using a volumetric method. Single-component adsorption isotherms are reported at pressures up to 120 kPa and at temperatures in the range from 194 to 338 K for ethane and ethene and from 273 to 358 K for propane and propene. The Tóth model appropriately describes the equilibrium data over the whole range of conditions. The saturation capacity for the alkene extracted by the Tóth model is higher than for the corresponding alkane, attributed to the higher packing efficiency of the alkene molecules inside the micropores. An interesting reversal in alkane/alkene adsorption selectivity with pressure is observed: at low pressures the selectivity towards the alkanes is driven by energetic effects while at high pressures the selectivity is towards the alkenes due to entropic effects.     

离子液体对气体的溶解性研究进展

概述了不同离子液体对CO2,O2,SO2,CH4等以及烯烃和烷烃气体的溶解性。文献资料分析表明,气体在离子液体中的溶解性差别很大,离子液体中的阴离子对气体的溶解度影响较大,而阳离子的影响较小。大部分气体在离子液体中的亨利系数随温度的升高而增大。气体在[bmim][PF6]中的溶解度比在[bmim][BF4]中的稍大。低温时[bmim][PF4]离子液体对CO2气体的吸收效果较好;[hmim][Tf2N]离子液体对SO2气体的吸收较好。在将离子液体用于气体吸收时可优先考虑Tf2N^-阴离子和具有较长侧链的眯唑型离子液体。     

Room temperature ionic liquids as replacements for conventional solvents – A review

Room temperature ionic liquids are salts that are liquids at ambient temperature. They are excellent solvents for a broad range of polar organic compounds and they show partial miscibility with aromatic hydrocarbons. Typical room temperature ionic liquids have a stable liquid range of over 300 K and have a very low vapor pressure at room temperature. Ionic liquids that are not hydrolyzed show a wide range of solubility in water. These unique properties have suggested that they might be useful as environmentally benign solvents that could replace volatile organic compounds (VOC). By varying the length and branching of the alkane chains of the cationic core and the anionic precursor, the solvent properties of ionic liquids should be able to be tailored to meet the requirements of specific applications to create an almost infinitely set of “designer solvents”. A review of recent applications of ionic liquids is presented along with some results of measurements of liquid-liquid equilibria and partition coefficients with alcohols. The results are compared with predictions based on quantum mechanic calculations.     

Colony-Specific Cuticular Hydrocarbon Profile in Formica argentea Ants

The cuticular hydrocarbons of the ant Formica argentea were identified by gas chromatography/mass spectrometry. Behavioral bioassays tested the role of each class of cuticular hydrocarbon in nestmate recognition, and statistical analyses looked for potential colony-specific signatures. The cuticular hydrocarbons of F. argentea consist of n-alkanes, alkenes, and methyl-branched alkanes. Behavioral bioassays demonstrated that changes in the alkene and methyl-branched alkane signature of F. argentea increased aggression, but changes in alkanes did not. Statistical analyses demonstrated that F. argentea workers present a colony-specific hydrocarbon profile based on their methyl-branched C₂₉ alkane signature. Using this signature alone, it is possible to group worker ants statistically by nest, suggesting that methyl-branched C₂₉ alkanes may be important in nestmate recognition for this species. These results support the idea that variation in positional isomers of cuticular hydrocarbons of the same carbon chain length may provide enough information for nestmate recognition. Although the addition of alkenes increased aggression in F. argentea, alkenes did not provide a colony-specific signature. This study reinforces the idea that investigators studying nestmate recognition should not examine cuticular hydrocarbon profiles as a whole but rather, should look for colony-specific signatures embedded in parts of the profile.     

纤维素在离子液体中的溶解特性研究

测定了纤维素在不同结构的离子液体——1-烯丙基-3-甲基咪唑氯化物([AMIM]Cl)和1-丁基-3-甲基咪唑氯化物([BMIM]Cl)中的溶解度和溶解速率。结果发现:相同条件下,纤维素在[AMIM]Cl中具有较大的溶解度和较快的溶解速率;随着纤维素聚合度的增大,相同条件下,纤维素在离子液体中的溶解度降低。进一步通过WXRD、FT-IR、13C NMR和黏度法分析了溶解前后纤维素的化学结构、结晶结构和聚合度,结果表明:纤维素在离子液体中的溶解属于直接溶解,纤维素经离子液体溶解和再生后,晶型由纤维素I转变为纤维素II;溶解时间和温度对再生纤维素的聚合度有较大的影响,随着溶解时间的延长和溶解温度的提高,再生纤维素聚合度降低。     

Electrochemical Promotion by Potassium of Rh-Catalysed Fischer–Tropsch Synthesis at High Pressure

Rh-catalysed Fischer–Tropsch synthesis at high pressures exhibits reversible electrochemical promotion by potassium. At 473 K and 14 bar, 43 products were detected, comprising alkanes, alkenes and primary alcohols. Potassium increased selectivity towards alkenes and primary alcohols as a result of actual increases in the rates of formation of these products – an apparently unprecedented observation. Alkane formation was progressively suppressed by added alkali. These findings are discussed in terms of K-induced acceleration and retardation of possible rate limiting steps for alkene and alkane formation, respectively. Plausible mechanisms are discussed.     

Effects of kinds of ionic liquid catalysts on alkylations of 1-and 2-methylnaphthalene with alkenes

Alkylations of 1-and 2-methylnaphthalene with long-chain alkenes in different alkyl-containing amine ionic liquids were investigated at room temperature. The effects of both anions and cations of ionic liquids on the alkylations were studied in detail. Results show that the anions determine, to a large extent, the physical and chemical properties of ionic liquids, but organic cations mainly influence physical properties, and have only a little impact on the catalytic performance. High conversion of alkylating agent and excellent selectivity for the desired products were obtained. The products and unreacted reactants were easily isolated from catalysis systems by extraction with cyclohexane. Thanks to the less expensive reagents and the easier synthesis process, methyl and ethylamine chloroaluminate ionic liquids could become novel practical catalysts for long-chain alkylation of methylnaphthalene with alkenes.     

氨基功能型离子液体吸收CO2的性能

氨基功能型离子液体在常温常压下对CO₂具有较强的吸收选择性能,在分离固定CO₂方面具有较好的应用前景。合成了4种氨基功能型离子液体,对产物进行了IR和¹H NMR表征,探究了这些功能型离子液体的CO₂吸收性能及再生性能。结果表明,4种氨基功能型离子液体均具有强于常规型离子液体的CO₂吸收性能,再生性能良好,可循环使用;离子液体的CO₂溶解度受黏度影响显著,随吸收温度的升高而降低,随吸收压力的升高,吸收剂浓度的增加而增大;强化传质能提高再生效率,多次的再生对离子液体的吸收性能没有明显影响。