C4/C5烃催化裂解制低碳烯烃的研究进展

从催化剂类型、裂解工艺、催化裂解的影响因素和裂解机理4个方面对国内外C4／C5烃催化裂解制低碳烯烃的研究进行了综述。催化裂解制低碳烯烃催化剂主要采用ZSM-5分子筛系列催化剂，在此基础上发展了酸改性或水热改性高硅ZSM系列分子筛及介孔MCM41分子筛。总结了国内外C4／C5烃的裂解工艺，认为影响催化裂解的主要因素是裂解原料、催化剂类型及工艺条件。目前，裂解机理主要是自由基与碳正离子机理相结合的机理。并简述了本课题组目前有关C4烷烃催化裂解的主要研究进展。     

BO3－3／Mo－MCM－41的制备及其对2－甲氧基萘乙酰化反应的催化性能

 制备了Mo－MCM－41中孔分子筛，并将BO3－3引入到分子筛中制得BO3－3／Mo－MCM－41催化剂．采用XRD，FT－IR，ESR，BET和NH3－TPD对分子筛催化剂的结构及酸强度进行了表征．结果表明，Mo－MCM－41和BO3－3／Mo－MCM－41具有中孔分子筛的特征，有良好的长程有序 性和结晶度；但Mo并未进入分子筛骨架内部而是在分子筛表面以MoO2的形式存在；BO3－3附着于Mo－MCM－41分子筛上形成强酸中心．将BO3－3／Mo－MCM－41用于催化2－甲氧基萘乙酰化反应，考察了催化剂用量、Si／Mo比及BO3－3的引入方式对该反应性能的影响，发现BO3－3／Mo－MCM－41对2－甲氧基萘乙酰化反应具有良好的催化性能．     

MCM-41分子筛负载钼钴系催化剂的噻吩HDS研究

通过氧吸附量、噻吩吸附热及反应速率常数的测定，研究了MoO3/MCM-41、MoO3-CoO(NiO)/MCM-41系列催化剂，发现，对于MoO3/MCM-41催化剂，当MoO3的质量分数（以MCM－41为底数，即MCM－41＝1g时，MoO3含量为0．15g，下同）从15％增加到20％时，其噻吩的加氢硫（HDS）活性增大，至25％时活性下降，所对应的氧吸附量（mL/g催化剂）也是先增大后减少，并且两者有很好的线性对应关系，而且噻吩吸附热则基本保持不变，采用不同的MoO3-CoO(NiO)浸渍顺序制备的MoO3-CoO(NiO)/MCM-41催化剂中，先浸渍CoO(NiO）再浸渍MoO3的催化剂，其噻吩HDS活性明显优于对其它浸渍顺序制备的催化剂，同时催化剂的氧吸附量和噻吩吸附热也最大。     

SBA-15介孔分子筛表面的磺酸基改性及其催化性能

 采用后合成方法，将含有巯基的化合物3－巯丙基三甲氧基硅烷（MPTMS）键合在大孔径、厚孔壁的新型纯硅介孔分子筛SBA－15表面上，经氧化和酸化后得到含有强酸性的磺酸基团的固体酸催化剂SBA－15－SO3H．用X射线衍射、红外光谱、固体核磁共振及热失重等方法对改性前后的SBA－15样品进行了表征．结果表明，改性后SBA－15分子筛的结构未发生变化，MPTMS键合于分子筛的表面，改性后的分子筛具有质子酸中心．SBA－15－SO3H催化剂对十八碳烯酸与甲醇的酯化反应具有较高的活性，催化剂上的磺酸基团在反应过程中具有较好的稳定性．     

单金属双中心Ti-MCM-41分子筛催化剂的光催化性能

 制备了单金属双中心Ti－MCM－41分子筛催化剂，通过XRD、低温N2吸附－脱附、XPS及原子吸收光谱等对催化剂进行了表征．结果表明，单金属双中心Ti－MCM－41分子筛催化剂具有良好的长程有序结构和孔结构，其比表面积大于1000m2／g，孔径分布窄，最可几孔径为2．7nm；Ti的电子结合能为458．6eV，介于骨架Ti（选择性氧化活性中心）和非骨架Ti（光催化活性中心）之间．以H2O2和·OH的生成量为基准，考察了Ti－MCM－41对苯羟化反应的催化性能随光照时间、催化剂用量、加水量、反应温度和空气流速等条件的变化，得出了光催化反应的最佳条件．在无外加氧化剂的情况下，单金属双中心Ti－MCM－41上苯的转化率为0．2％，表明其确实具有一定的光催化性能，可实现光催化－选择性氧化的反应－反应耦合．与骨架取代Ti－MCM－41和MCM－41负载TiO2催化剂相比，单金属双中心Ti－MCM－41的催化活性最高．这主要是由于它既具有光催化活性中心，又具有选择性氧化活性中心．     

新型固体超强酸催化剂的制备与裂解性能研究

采用浸渍法，将活性超强酸SO4^2-/ZrO2引入Si-MCM-41介孔分子筛，得到一种新型的固体超强酸催化剂SO4^2-/ZrO2 /Si-MCM-41，其PKA值可达-12.7，酸度分布曲线表明强酸中心数量远低于弱酸中心，XRD结果显示，Si-MCM-41骨架部分塌陷，但保留了主要骨架结构，采用Py-IP法，测定SO4^2-/ZrO2 /Si-MCM-41上酸类型以L酸为主，在催化1，3，5-三异丙苯裂解反应中该催化剂的性能优于微孔分子筛。     

CO2氧化丙烷脱氢制丙烯V-Cr/SBA-15催化剂的研究

以介孔分子筛SBA-15为载体，V和Cr为活性组分，采用浸渍法制备了不同V和Cr质量分数的V-Cr/SBA-15催化剂，研究了其对二氧化碳氧化丙烷制丙烯反应的催化性能，采用XRD、BET、TPR等分析测试技术对催化剂的结构进行了表征。结果表明，催化剂中V组分的质量分数较大时以V2O5物相存在，Cr组分以Cr2O3物相存在，它们对SBA-15分子筛的介孔特征影响不大；V、Cr单组分和双组分催化剂都具有较好的CO2氧化丙烷脱氢制丙烯的催化性能，V和Cr质量分数相同的双组分催化剂比单组分催化剂具有更高的催化活性；在V-Cr/SBA-15催化剂中，V和Cr之间存在一定的相互作用，进而改变了催化剂的氧化还原性能，提高了催化剂的催化性能。     

MCM-41分子筛负载钼钴系催化剂的程序升温硫化研究

采用程序升温硫化（TPS）技术，研究了负载于MCM－41分子筛的钼钴系催化剂的性能，根据TPOS结果可知，（1）载体和MoO3相互作用的强度顺序如下：Al2O3＞Al2O3-MCM-41＞MCM－41＞TiO2－MCM－41，说明TiO2具有削弱MCM－41和MoO3作用的能力；而Al2O3则相反，它增加了MoO3和MCM－41的相互作用。（2）助剂CoO对负载于未经改性的MCM－41载体上的MoO3的硫化没有明显的促进作用，这和以Al2O3为载体的情况下不同，在Al2O3上，MoO3和CoO可能生成Co-Mo－O复合相，从而促进了MoO3的硫化。（3）助剂CoO对负载于经TiO2和Al2O3改性的MCM－41上的MoO3的硫化起了促进作用。     

C4/C5烃催化裂解制低碳烯烃的研究进展

从催化剂类型、裂解工艺、催化裂解的影响因素和裂解机理4个方面对国内外C4/C5烃催化裂解制低碳烯烃的研究进行了综述。催化裂解制低碳烯烃催化剂主要采用ZSM-5分子筛系列催化剂,在此基础上发展了酸改性或水热改性高硅ZSM系列分子筛及介孔MCM-41分子筛。总结了国内外C4/C5烃的裂解工艺,认为影响催化裂解的主要因素是裂解原料、催化剂类型及工艺条件。目前,裂解机理主要是自由基与碳正离子机理相结合的机理。并简述了本课题组目前有关C4烷烃催化裂解的主要研究进展。     

以硅胶和三氯化钛为原料合成Ti-MCM-41分子筛 Ⅱ. Ti-MCM-41分子筛的表征

 利用N2吸附,TG－DTA,FT－IR,UV－Vis和UV－Raman光谱等技术对以硅溶胶和TiCl3水溶液为原料合成的中孔Ti－MCM－41分子筛的孔结构和钛的配位状态进行了详细的表征．N2吸附等温线表明,Ti－MCM－41分子筛的孔径比纯硅MCM－41分子筛小,钛的加入使分子筛的单胞体积大大增加,比表面积和孔壁厚度也显著增大．TG－DTA结果表明,Ti－MCM－41分子筛中存在着两种不同的模板剂键合位．FT－IR,UV－Vis及UV－Raman光谱表明,Ti原子存在于分子筛骨架中且以四面体方式配位,没有结晶状态的TiO2形成．     

Study on the Pyrolysis of Cellulose for Bio-Oil with Mesoporous Molecular Sieve Catalysts

Mesoporous materials possess a hexagonal array of uniform mesopores, high surface areas, and moderate acidity. They are one of the important catalysts in the field of catalytic pyrolysis. In this paper, mesoporous materials of Al-MCM-41, La-Al-MCM-41, and Ce-Al-MCM-41 were synthesized, characterized, and tested as catalysts in the cellulose catalytic pyrolysis process using a fixed bed pyrolysis reactor. The results showed that mesoporous materials exhibited a strong influence on the pyrolytic behavior of cellulose. The presence of these mesoporous molecular sieve catalysts could vary the yield of products, which was that they could decrease the yield of liquid and char and increase the yield of gas product, and could promote high-carbon chain compounds to break into low-carbon chain compounds. Mesoporous molecular sieve catalysts were benefit to the reaction of dehydrogenation and deoxidation and the breakdown of carbon chain. Further, La-Al-MCM-41 and Ce-Al-MCM-41 catalysts can produce more toluene and 2-methoxy-phenol, as compared to the non-catalytic runs.     

碱性条件下废轮胎真空热裂解研究

研究了废轮胎橡胶粉在450℃～600℃真空热解系统中热解的特性，以及温度和添加Na2CO3、NaOH对热解气液态产物的影响。实验表明，真空下废轮胎热解油收率在550℃时达到最大值，为48%左右。添加3%的NaOH能明显促进废轮胎橡胶热解，480 ℃时油产率达到最大值49.66%，随后随着温度的升高油产率呈现下降趋势。添加3%的Na2CO3对热解的促进作用不明显。热解气体产物主要有H2、CO、CH4、CO2、C2H4、C2H6以及少量其他化合物。NaOH的加入使气体产品中的H2相对体积分数明显增加，而CH4、CO、C2等的体积分数降低。通过GC和GC-MS分析热解石脑油发现，热解油品中含有11%以上的柠檬油精。     

Scrap Tires Pyrolysis: Product Yields,Properties and Chemical Compositions of Pyrolytic Oil

This investigation involves an experimental study on the pyrolysis of scrap tires under different operating conditions such as feedstock size and pyrolysis temperature by highlighting the properties of the whole liquid products generated during each thermal degradation process. The complete conversion temperature for the pyrolysis of used tires was close to 500?550°C. The characteristics of liquid fraction were determined by elemental analysis, chromatographic and spectroscopic techniques and distillation data. All the obtained atomic ratios are around 1,4 which is significant that such pyrolytic liquids are a mixture of aliphatic and aromatic compounds derived from polymeric materials. Analysis of the pyrolytic oil (pyro-oil) by chromatographic analysis showed that it was a complex mixture of organic compounds C₅?C₂₆, aromatics and a large proportion of light hydrocarbons that can be used as liquid fuels. Furthermore, the comparison distillation data indicates that more than 40% of such pyrolytic oil fraction with the boiling point range between 180?360°C is specified for diesel. It is noted that the viscosity decreases obviously from 4.87 to 1.79 with the increase in temperature.     

Essential Quality Attributes of Tangible Bio‐Oils from Catalytic Pyrolysis of Lignocellulosic Biomass

This review covers the characteristics of pyrolysis and catalytic pyrolysis bio‐oils by focusing on the fundamental factors that determine bio‐oil upgradability. The abundant works on the subject of bio‐oil production from lignocellulosic biomass were studied to establish the essential attributes of the bio‐oils for assessment of the oil stability and upgradability. Bio‐oils from catalytic pyrolysis processes relating to catalysts of different compositions and structures are discussed. A general relationship between the higher heating value and the oxygen content in the catalytic pyrolysis oils exists, but this relationship does not apply to the thermal pyrolysis oil. Reporting bio‐oil yield is meaningful only when the oxygen content of the oil is measured because the pyrolytic oil stability is mainly determined by the oxygen content. Isoenergy plot that associates bio‐oil yield with oxygen content is presented and discussed.     

餐饮垃圾热解制取生物燃油的实验研究

主要研究温度、餐饮垃圾种类以及催化剂对餐饮垃圾热解所制生物燃油的产率和品质的影响。结果表明,猪肉和米饭的最佳产油温度均为410℃,白菜的最佳产油温度为450℃。米饭、白菜、猪肉的产油率分别为45.02%、25.60%、71.26%。采用氧弹热量计对其热值进行测定,米饭和白菜热解油的高位热值较低,分别为18.30MJ/kg和17.49MJ/kg;而猪肉热解油的高位热值为36.57 MJ/kg, 并且黏稠度较高。催化剂Co-MCM-41的催化效果明显,使餐饮垃圾的产油率由41.99%提高到66.30%,同时使热解油中的含氧化合物明显降低,而烷烃类和烯烃类的含量明显增加,高位热值由30.30MJ/kg提高到32.74MJ/kg。通过物理吸附仪对新制备的和使用一次后再生的催化剂Co-MCM-41进行表征,结果表明,催化剂Co-MCM-41再生后孔容、孔径和比表面积变化不大,性质基本不变,活性依然存在。
     

Peat semicoking and hydrocracking

This work deals with thermochemical conversion of peat into solvent-soluble oil and volatile gaseous products by using pyrolysis and catalytical hydrocracking methods. Distribution of liquid compounds between solubilized in water, benzene, and in acetone was determined and as a result the oil yield as total solubles was calculated. Chromatographic and FTIR-spectroscopic methods were used to characterize the composition of conversion products. Investigation of peat pyrolysis regularities in comparison with those of oil shale by using Rock-Eval analysis demonstrated essential differences between peat and oil shale as pyrolysis feedstock. As a result of hydrocracking the total oil yield was increased more than twice compared with that of semicoking, 29.8 and 13%, respectively. Hydrocracking and semicoking led to significant deoxygenation of oil and solid residual conversion products via oxygen removal as carbon dioxide and water. Hydroxyl-, carboxyl-, carbonyl- and other oxygen functionalities in peat initial matter being hydrocracked and modified, the oil was characterized by elevated hydrocarbon content and decreased that of polar oxygen compounds. As the oxygen content of the product decreases, the energy content significantly increases and peat oil, particularly its hydrophobic fractions, can be used for synthetic liquid fuel.     

Catalytical and thermal pyrolysis of polyolefins

Polyolefins have a high potential for alternative oil production since they contain only carbon and hydrogen atoms. By pyrolysis of these materials up to 95% can be obtained as oil and gas. Upgrading the products by catalytic cracking of polyolefins is a subject of growing interest in the last years as less energy is needed for the pyrolysis and more valuable products are formed. Numerous studies have been reported in which a variety of catalysts such as zeolites, silica-alumina, mesoporous MCM-41, solid acids and reaction conditions have been investigated. In our studies we used Lewis acids and mixtures of Ziegler–Natta catalyst such as TiCl₄, AlCl₃ to pyrolyse polypropylene. Experiments were carried out in a batch reactor as well as in a fluidized bed process. The pyrolysis temperature can be decreased by 100 °C compared to runs without catalysts. A drastic increase in the amount of low boiling compounds (C4 hydrocarbons) can be observed by the use of the catalysts instead of longer chained hydrocarbons.     

Characterization of the water-insoluble pyrolytic cellulose from cellulose pyrolysis oil

Water-insoluble pyrolytic cellulose with similar appearance to pyrolytic lignin was found in cellulose fast pyrolysis oil. The influence of pyrolysis temperature on pyrolytic cellulose was studied in a temperature range of 300–600 °C. The yield of the pyrolytic cellulose increased with temperature rising. The pyrolytic cellulose was characterized by various methods. The molecular weight distribution of pyrolytic cellulose was analyzed by gel permeation chromatography (GPC). Four molecular weight ranges were observed, and the M_w of the pyrolytic cellulose varied from 3.4 × 10³ to 1.93 × 10⁵ g/mol. According to the elemental analysis (EA), the pyrolytic cellulose possessed higher carbon content and lower oxygen content than cellulose. Thermogravimetric analysis (TGA) indicated that the pyrolytic cellulose underwent thermo-degradation at 127–800 °C and three mass loss peaks were observed. Detected by the pyrolysis gas chromatography–mass spectrometry (Py-GC/MS), the main pyrolysis products of the pyrolytic cellulose included saccharides, ketones, acids, furans and others. Fourier transforms infrared spectroscopy (FTIR) also demonstrated that the pyrolytic cellulose had peaks assigned to CO stretching and glycosidic bond, which agreed well with the Py-GC/MS results. The pyrolytic cellulose could be a mixture of saccharides, ketones, and their derivatives.     

生物油中酚类化合物加氢脱氧催化剂研究进展

随着化石能源日益匮乏,生物质热裂解制备生物油广受关注.然而,生物油中含有大量酚、呋喃、醛、酮等含氧化合物,含氧量高达50%,导致其热值低、化学稳定性差等,因而阻碍了它的广泛应用,必须对其进行加氢脱氧精制降低含氧量.在生物油中众多含氧化合物中,酚羟基氧被认为是最难被脱除的.对酚类含氧化合物加氢脱氧催化剂及反应进行了简单综述,并提出了如何进一步提高催化剂性能的有效方法.     

Selective fast pyrolysis of biomass impregnated with ZnCl2: Furfural production together with acetic acid and activated carbon as by-products

Fast pyrolysis of biomass materials impregnated with ZnCl₂ offered a promising way to obtain a liquid product rich in furfural (FF) and acetic acid (AA), and the pyrolytic solids could be used as the precursors to prepare activated carbons (ACs). In this study, a lab-scale fast pyrolysis set was designed and used for the quantitative production of the three chemicals. The maximum FF was produced from the corncob impregnated with at least 15 wt% ZnCl₂ and at the pyrolysis temperature around 340 °C, with the yield of more than 8 wt% compared with only 0.49 wt% from the raw corncob. Meanwhile, AA of around 4 wt% could be obtained. The content of the FF and AA was over 50 wt% and 25 wt% on the water-free basis of the pyrolytic liquids. In addition, ACs were prepared from the pyrolytic solids, and they exhibited similar properties as those prepared from direct activation of ZnCl₂-impregnated biomass materials.