重油催化裂解汽柴油二次裂解性能研究

This paper investigated the secondary cracking of gasoline and diesel from the catalytic pyrolysis of Daqing atmospheric residue on catalyst CEP-1 in a fluidized bed reactor.The results show that the secondary cracking reactivity of gasoline and diesel is poor,and the yield of total light olefins is only about 10%（by mass）.As reaction temperature increases,ethylene yield increases,butylene yield decreases,and propylene yield shows a maximum.The optimal reaction temperature is about 670℃for the production of light olefins.With the enhance- ment of catalyst-to-oil mass ratio and steam-to-oil mass ratio,the yields of light olefins increase to some extent. About 6.30%of the mass of total aromatic rings is converted by secondary cracking,indicating that aromatic hy- drocarbons are not easy to undergo ring-opening reactions under the present experimental conditions.     

用离子液体作催化剂和夹带剂时在反应萃取精馏塔中乙酸甲酯和正丁醇酯交换反应的模拟

A new reactive and extractive distillation process with ionic liquids as entrainer and catalyst (RED-IL) was proposed to produce methanol and n-butyl acetate by transesterification reaction of methyl acetate with n-butanol. The RED-IL process was simulated via a rigorous model, and high purity products of methanol and n-butyl acetate can be obtained in such a process. The effects of reflux ratio, feed mode, holdup, feed location, entrainer ratio and catalyst concentration on RED-IL process were investigated. The conversion of methyl acetate and purities of products increase with the holdup in column, entrainer ratio and catalyst content. An optimal reflux ratio exists in RED-IL process. Comparing to the mixed-feed mode, the segregated-feed mode is more effective, in which the optimal feed locations of reactants exist.     

Catalytic kinetics of dimethyl ether one-step synthesis over CeO_2–CaO–Pd/HZSM-5 catalyst in sulfur-containing syngas process

CeO_2–CaO–Pd/HZSM-5 catalyst was prepared for the dimethyl ether(DME) one-step synthesis in a continuous fixed-bed micro-reactor from the sulfur-containing syngas. The catalytic stability over hybrid catalyst of CeO_2–CaO–Pd/HZSM-5 was investigated to ensure that the kinetics experimental results were not significantly influenced by induction period and catalytic deactivation. A large number of kinetic data points(40 sets) were obtained over a range of temperature(240–300 °C), pressure(3–4 MPa), gas hourly space velocity(GHSV)(2000–3000 L·kg~(-1)·h~(-1)) and H_2/CO mole ratio(2–3). Kinetic model for the methanol synthesis reaction and the dehydration of methanol were obtained separately according to reaction mechanism and Langmuir–Hinshelwood mechanism. Regression parameters were investigated by the method combining the simplex method and Runge–Kutta method. The model calculations were in appropriate accordance with the experimental data.     

Evaluation of an improved epichlorohydrin synthesis from dichloropropanol using a microchemical system

Synthesizing epichlorohydrin (ECH) from dichloropropanol (DCP) is a complicated reaction due to the partial decomposition of ECH under harsh conditions. A microchemical system can provide a feasible platform for improving this process by conducting a separation once full conversion has been achieved. In this work, referring to a common DCP feed used in industry, the reaction performance of mixed DCP isomers with NaOH in the microchemical system on various time scales was investigated. The operating window for achieving high conver-sion and selectivity was on a time scale of seconds, while the side reactions normal y occurred on a time scale of minutes. Plenty of Cl?ions together with a high temperature were proved to be critical factors for ECH hydrolysis. A kinetic study of alkaline mediated ECH hydrolysis was performed and the requirements for an improved ECH synthesis were proposed by combining quantitative analysis using a simplified reaction model with experimen-tal results on the time scale of minutes. Compared with the conventional distillation process, this new strategy for ECH synthesis exploited microchemical system and decoupled the reaction and separation with potentials of higher productivity and better reliability in scaling up.     

Application of machine learning to process simulation of n-pentane cracking to produce ethylene and propene

Modeling light olefin production was one of the main concerns in chemical engineering field. In this paper, machine learning model based on artificial neural networks(ANN) was established to describe the effects of temperature and catalyst on ethylene and propene formation in n-pentane cracking. The establishment procedure included data pretreatment, model design, training process and testing process, and the mean square error(MSE) and regression coefficient(R~2) indexes were employed to evaluate model performance. It was found that the learning algorithm and ANN topology affected the calculation accuracy. GD24223, CGB2423, and LM24223 models were established by optimally matching the learning algorithm with ANN topology, and achieved excellent calculation accuracy. Furthermore, the stability of GD24223, CGB2423 and LM24223 models was investigated by gradually decreasing training data and simultaneously transforming data distribution. Compared with GD24223 and LM24223 models, CGB2423 model was more stable against the variations of training data, and the MSE values were always maintained at the magnitude of 10~(-3)–10~(-4), confirming its applicability for simulating light olefin production in n-pentane cracking.     

One-step conversion of syngas to light olefins over bifunctional metal-zeolite catalyst

Light olefins(C_2–C_4) are fundamental building blocks for the manufacture of polymers, chemical intermediates,and solvents. In this work, we realized a composite catalyst, comprising Mn_xZr _yoxides and SAPO-34 zeolite,which can convert syngas(CO + H_2) into light olefins. Mn_xZr_yoxide catalysts with different Mn/Zr molar ratios were facilely prepared using the coprecipitation method prior to physical mixing with SAPO-34 zeolite. The redox properties, surface morphology, electronic state, crystal structure, and chemical elemental composition of the catalysts were examined using H_2-TPR, SEM, XPS, XRD, and EDS techniques, respectively. Tandem reactions involved activation of CO and subsequent hydrogenation over the metal oxide catalyst, producing methanol and dimethyl ether as the main reaction intermediates, which then migrated onto SAPO-34 zeolite for light olefins synthesis. Effects of temperature, pressure and reactant gas flow rate on CO conversion and light olefins selectivity were investigated in detail. The Mn_1Zr_2/SAPO-34 catalyst(Mn/Zr ratio of 1:2) attained a CO conversion of 10.8% and light olefins selectivity of 60.7%, at an optimized temperature, pressure and GHSV of 380 °C, 3MPa and 3000 h~(-1) respectively. These findings open avenues to exploit other metal oxides with CO activation capabilities for a more efficient syngas conversion and product selectivity.     

Influence of the post-treatment of HZSM-5 zeolite on catalytic performance for alkylation of benzene with methanol

The porous material HZSM-5 zeolite with micro-mesopore hierarchical porosity was prepared by post-treatment (combined alkali treatment and acid leaching)of parent zeolite and its catalytic performance for benzene alkyl-ation with methanol was investigated.The effect of post-treatment on the textural properties was characterized by various techniques(including ICP-AES,XRD,nitrogen sorption isotherms,SEM,NH3-TPD,Py-IR and TG).The results indicated that the post-treatment could modify the structural and acidic properties of HZSM-5 zeolite.In this procedure,not only additional mesopores were created by selective extraction of silicon but also the acidity was tuned.Consequently,the modified HZSM-5 zeolite showed larger external surface area with less acid sites as compared to the parent zeolite.It was found out that the modified zeolite exhibited a higher benzene conversion and xylene selectivity for alkylation of benzene with methanol as well as excellent life span of the catalyst than conventional ones.This can be explained by the facts that the presence of additional mesopores improved the diffusion property in the reactions.Furthermore,the modified zeolite showed an appropriate Br?nsted acidity for effective suppression of the side reaction of methanol to olefins,thus reduced the accumulation of coke on the HZSM-5 zeolite,which was favorable for the catalyst stability.In comparison with the parent HZSM-5 zeolite, the modified zeolite by alkali treatment and acid leaching showed better performance for the benzene alkylation with methanol.     

煤矸石盐酸浸溶出铝铁的动力学研究（英文）

The extraction of aluminum from coal mining waste (CMW) is an important industrial process. The two major problems in applications are low aluminum dissolution efficiency and high iron content in the raw material, which affect the quantity and quality of products. To improve the aluminum recovery process, the leaching kinet-ics of CMW with hydrochloric acid was studied. A shrinking core model was used to investigate aluminum and iron dissolution kinetics. Based on the kinetic characteristics, a process for recovering aluminum was proposed and tested experimental y. It is found that the aluminum leaching reaction is controlled by surface reaction at low temperatures (40–80 °C) and by diffusion process at higher temperatures (90–106 °C). The iron dissolution process is dominated by surface reaction at 40–100 °C. The results show that iron could be dissolved or separated by concentrated hydrochloric acid. Fine grinding wil improve aluminum dissolution significantly.     

大庆常压催化裂解动力学研究

Catalytic pyrolysis of Daqing atmospheric residue on catalyst CEP-1 was investigated in a confined fluidized bed reactor. The results show that reaction temperature, the mass ratios of catalyst to oil and steam to oil have significant effects on product distribution and yields of light olefins. The yields of light olefins show the maxima with the increase of reaction temperature, the mass ratios of catalyst to oil and steam to oil, respectively. The optimized operating conditions were determined in the laboratory, and under that condition the yields of ethylene, propylene and total light olefins by mass were 15.9%, 20.7% and 44.3% respectively. The analysis of pyrolysis gas and pyrolysis liquid indicates that CEP-1 has good capacity of converting heavy oils into light olefins, and there is a large amount of aromatics in pyrolysis liquid.     

高岭土微球原位合成SAPO-34分子筛及其在流化床甲醇/二甲醚制烯烃过程中的应用(英文)

SAPO-34 zeolite is considered to be an effective catalyst for methanol or dimethyl ether conversion to olefins. In this study, we developed the in situ synthesis technology to prepare SAPO-34 zeolite in kaolin microspheres as a catalyst for fluidized methanol or dimethyl ether to olefins process. The silicoaluminophosphate zeolite was first time reported to be synthesized in kaolin microspheres. The SAPO-34 content of synthesized catalyst was about 22% as measured by three different quantitative methods (micropore area, X-ray fluorescence and energy dispersive spectroscopy element analysis). Most of the SAPO-34 zeolites were in nanoscale size and distributed uniformly inside the spheres. The catalytic performance was evaluated in fixed bed and fluidized bed reactors. Compared with the conventional spray-dry catalyst, SAPO/kaolin catalyst showed superior catalytic activities, better olefin selectivities (up to 94%, exclusive coke), and very good hydrothermal stability. The in situ synthesis of SAPO-34 in kaolin microspheres is a facile and economically feasible way to prepare more effective catalyst for fluidized MTO/DTO (methanol to olefins/dimethyl ether to olefins) process.     

碳四烃转化与利用技术研究进展及发展前景

我国来自炼油厂和石化装置的碳四(C₄)烃资源非常丰富,与此同时,C₄烃用作传统液化石油气燃气的需求量正逐渐减少,C₄烃资源综合利用成为企业的关注热点。本文介绍了国内外C₄烃转化与利用技术的开发进展及工业应用情况,包括丁烯异构化、丁烯歧化、C₄烯烃催化裂解、异丁烷脱氢、异丁烯制甲基丙烯酸甲酯(MMA)、C₄烃芳构化与烷基化等。认为对炼化一体化企业而言,将炼油厂C₄和裂解C₄整合在一起,应用增产低碳烯烃、醚后C₄生产高辛烷值汽油组分、C₄组分相互转化以及向下游高附加值产品延伸等技术,未来将具有较好的发展前景,不仅可为市场提供所需的燃料与化学品,而且有利于提升企业经济效益。     

活化气氛对CO2加氢制取低碳烯烃Fe-K催化剂构-效关系

CO₂加氢直接制取低碳烯烃是实现其资源化利用的重要途径。通过热分解法制备了5种不同K含量（1%、3%、5%、7%、9%）的Fe-K催化剂用于CO₂加氢反应,结果表明Fe95-K5（95% Fe-5% K,质量分数）催化剂具有最优的活性及C₂～C₄烯烃选择性;随后对Fe95-K5催化剂进行了10% H₂/Ar、10% CO/Ar及5% CO/5% H₂/Ar 3种不同气氛活化处理以及CO₂加氢反应。结果发现,10% CO/Ar活化的催化剂具有最高的C₂～C₄烯烃选择性（38.1%）及链增长能力（α=0.644）。此外,还通过X射线衍射、Raman、程序升温等表征技术揭示了催化剂在不同活化气氛下的结构演变历程。研究发现,10% CO/Ar与5% CO/5% H₂/Ar活化的催化剂会生成γ₁型碳化铁结构,而10% H₂/Ar活化的催化剂则会在反应过程中生成γ₂型碳化铁结构,两种碳化铁结构对CO₂解离均有促进作用。     

A LUMPED KINETIC MODEL FOR DEHYDRATION OF ETHANOL TO HYDROCARBONS OVER HZSM-5

A kinetic model for the conversion of ethanol to hydrocarbons over HZSM-5 catalyst has been developed. The model is based on data from ethanol dehydration experiments conducted in a fixed-bed integral reactor at atmospheric pressure and temperatures of 150°C to 360°C, and is the first which integrates the major reaction pathways of both dehydration and higher hydrocarbon formation over ZSM-5 zeolite. In the model C₃-C₆ olefins, C₃-C₅ paraffins, and C₆⁺ hydrocarbons are treated as lumped species, while ethanol, diethyl ether, ethylene, and ethane are treated individually. Nonlinear parameter estimation using quasilinearization and least squares as the objective function has been implemented to estimate rate constants, adsorption equilibrium constants, and activation energies. The Langmuir-Hinshelwood rate expressions successfully correlated the experimental data.     

全结晶ZSM-5分子筛催化剂研究及工业应用

制备了全结晶ZSM-5分子筛催化剂,采用XRD、SEM、N2物理吸附-脱附及NH3-TPD等对催化剂进行表征,并考察其用于碳四烯烃催化裂解制丙烯(OCC)反应的催化性能。结果表明,制备的全结晶ZSM-5分子筛催化剂比常规成型的催化剂具有更高的结晶度、更大的比表面积、更丰富的孔结构以及更多的活性中心。高空速有利于反应的进行,提高压力对反应不利,升高温度有利于提高产物丙烯收率。在实验室研究的基础上,将全结晶ZSM-5分子筛催化剂用于OCC工业装置,取得良好的应用效果。     

CuZnTiO2/SAPO-34双功能催化剂的设计、制备及其用于CO2加氢制烯烃性能

CO₂加氢经甲醇（含氧中间体）制低碳烯烃工艺路线,可实现成醇、脱水两步反应串联协同进行,打破费托合成产物Anderson-Schulz-Flory（ASF）分布限制,高选择性地制取低碳烯烃。传统甲醇合成Cu基催化剂加氢能力较强,在两步反应中产物以CH₄、低碳烷烃为主。实验设计、制备了CuZnTiO₂/(Zn-)SAPO-34复合催化剂,实现了CO₂加氢在Cu基复合催化剂上高选择性合成C₂～C₄烯烃（约60%）。研究表明,两步反应过程中甲醇体积分数较低（＜6%）,且高温下逆水煤气变换反应严重,导致催化剂酸性变化对产物分布的影响较大。调变两类活性位点比例发现,CH₄的产生与串联反应存在竞争关系,SAPO-34酸量的增加抑制了CH₄的生成,促进串联反应正向进行;合适的酸性有助于生成C₂～C₄烯烃。控制成醇、脱水两类活性位点接触距离可调变烯烃的二次反应,降低加氢能力,改善产物分布。     

C6~C8烯烃水合催化剂的研究进展

环己烯、正己烯、正辛烯等C₆~C₈烯烃是重要的化工原料,用途广泛。综述了环己烯及正己烯,正辛烯等C₆~C₈烯烃水合催化剂的研究进展。环己烯水合法制备环己醇是一种绿色制备工艺,其催化剂由最初的硫酸、磺酸等均相催化剂逐渐向分子筛等非均相催化剂过渡,其中HZSM-5分子筛以其高选择性、高活性成为工艺上常用的催化剂。环己烯间接水合法合成环己醇的途径具有高选择性,高转化率,低能耗的优点,其催化剂的研究也处在一个高速发展阶段。正己烯、正辛烯水合催化剂的研究较少。未来离子液体等新型水合催化剂将会成为环己烯水合制备环己醇的研究重点。     

FCC汽油降烯烃工艺及催化剂研究进展

针对国VI汽油标准大幅度降烯烃的需要及乙醇汽油对有机含氧化合物含量的严格要求,从分子炼油角度出发,按照烯烃碳数C_4、C_5～C_6、C_5～C_8的顺序分别介绍并分析催化裂化(FCC)汽油降烯烃后处理技术,包括MTBE生产、烷基化、醚化、异构化/芳构化工艺发展状况、优缺点与应用局限。由于乙醇汽油的推广,MTBE生产技术与轻汽油醚化技术将面临停产的困境与改造的挑战,而烷基化、异构化/芳构化等生产高辛烷值汽油组分的技术是更具潜力的FCC汽油降烯烃技术,将得到大力发展。此外,总结常用工业催化剂及其改性研究,并简述存在问题与发展方向,提出汽油组分比例优化、MTBE装置改造等建议与展望,为FCC汽油降烯烃工艺技术路线选择提供借鉴。     

国内外乙烯生产工艺和催化剂研究进展

概述乙烯主要的生产工艺如蒸气裂解制乙烯、石脑油催化裂解制乙烯、重油催化裂解制乙烯、炼厂气干气制乙烯、C_4制乙烯、甲醇制乙烯、乙醇制乙烯、甲烷制乙烯、合成气制乙烯和生物法制乙烯等。主要比较工艺特点、反应机理、催化剂以及典型工艺等方面。认为由于原料的差异,煤基工艺发展相对较为成熟,石油基工艺发展相对缓慢,利用煤基乙烯生产工艺和催化剂将有助于开发石油基的工艺和催化剂。     

MnOx助剂对Fe/SiO2催化剂费-托合成制低碳烯烃动力学的影响

探讨了MnO_x助剂对Fe/SiO₂催化剂经由费-托反应(Fischer-Tropsch)制备低碳烯烃(FTO)的影响。通过浸渍法制备了Fe₂₀/SiO₂和Fe₂₀-Mn_1.0/SiO₂催化剂,结果表明MnO_x助剂显著提升了CO转化率和C₂～C₄烯烃的时空收率。程序升温吸附实验表明MnO_x助剂增加了Fe基催化剂表面碱性,促进了CO的解离吸附。运用幂指数模型,研究了Fe₂₀/SiO₂和Fe₂₀-Mn_1.0/SiO₂催化剂上FTO反应动力学,得到了各产物生成活化能与H₂/CO反应级数。最后,结合动力学研究与程序升温表征结果,对Fe基催化剂FTO反应机理,尤其是MnO_x助剂提高Fe₂₀/SiO₂催化剂上低碳烯烃选择性的作用进行了讨论。     

碳五烃催化裂解制取丙烯/乙烯反应性能

以ZSM-5分子筛为催化剂,碳五烃混合物为裂解原料,考察空速对碳五烃催化裂解制丙烯/乙烯反应性能的影响。结果表明,在580℃和实验空速范围,随着空速的增加,碳五烷烃及烯烃转化率整体呈下降趋势,但碳五烯烃转化率远高于碳五烷烃。乙烯及丙烯收率在空速3 h-1时达到最大,分别为10.51%和13.02%。碳四烯烃收率随空速的升高而降低,但各丁烯异构体相对于总烯烃的质量分布接近热力学平衡态。