乙基环己烷催化裂解制低碳烯烃反应动力学

利用小型固定床实验装置研究了乙基环己烷在基于ZSM-5分子筛介孔催化剂上的裂解性能,发现乙基环己烷具有较好的裂解性能,原料转化率在80%以上,乙丙烯收率(质量分数)可达41%,低碳烯烃收率(质量分数)接近50%,液体产物主要是苯、甲苯、二甲苯等芳香烃。同时考虑乙基环己烷催化裂解过程中的热反应与催化反应,建立了包含14个反应的动力学模型。基于4个反应温度下的裂解实验数据,求取了反应动力学模型的参数。求得的表观活化能均在90 k J·mol-1以下,主要组分收率的模型预测值与实验值的平均相对误差不高于10%。     

神华上湾煤恒温阶段直接液化反应动力学

为考察神华上湾煤的直接液化性能及反应动力学,以加氢蒽油-洗油混合油作为溶剂、负载型FeOOH作为催化剂,在0.01 t·d^-1煤直接液化连续实验装置上考察了不同反应温度（435~465℃）、不同停留时间（7~110 min）下液化产品组成的演变规律。研究发现,随着煤的裂解及加氢反应的进行,煤及沥青类物质（PAA）收率不断减小,重质液化产物逐步向轻质液化产物转化。当反应温度为455℃、停留时间为90 min时,煤转化率为90.41%（质量分数（,油收率为61.28%（质量分数（。随着反应条件进一步苛刻,油收率下降。基于上湾煤直接液化反应特性及其产物收率变化规律建立了11集总煤直接液化反应动力学候选模型,以BFGS优化算法对实验数据搜索、选优,确定了动力学模型参数。检验结果表明所建立的动力学模型可用于恒温阶段直接液化行为的模拟计算。     

神华上湾煤恒温阶段直接液化反应动力学

为考察神华上湾煤的直接液化性能及反应动力学,以加氢蒽油-洗油混合油作为溶剂、负载型FeOOH作为催化剂,在0.01 t·d~(-1)煤直接液化连续实验装置上考察了不同反应温度(435~465℃)、不同停留时间(7~110 min)下液化产品组成的演变规律。研究发现,随着煤的裂解及加氢反应的进行,煤及沥青类物质(PAA)收率不断减小,重质液化产物逐步向轻质液化产物转化。当反应温度为455℃、停留时间为90 min时,煤转化率为90.41%(质量分数),油收率为61.28%(质量分数)。随着反应条件进一步苛刻,油收率下降。基于上湾煤直接液化反应特性及其产物收率变化规律建立了11集总煤直接液化反应动力学候选模型,以BFGS优化算法对实验数据搜索、选优,确定了动力学模型参数。检验结果表明所建立的动力学模型可用于恒温阶段直接液化行为的模拟计算。     

轻烃催化裂解制低碳烯烃反应规律与原料特征化

利用小型固定床实验装置对比研究了轻烃模型化合物的催化裂解性能,从优到劣的顺序依次是正构烯烃、正构烷烃、环烷烃、异构烷烃、芳香烃。正构烷烃、异构烷烃与环烷烃催化裂解的总低碳烯烃收率有较大差别,但是总低碳烯烃选择性却均在56.57%左右。研究了直馏石脑油的催化裂解性能,发现乙丙烯收率和总低碳烯烃收率随反应温度的升高及重时空速的降低而逐渐增大;在反应温度680℃、重时空速4.32 h^-1和水油稀释比0.35的条件下,乙丙烯收率35.87%（质量）,总低碳烯烃收率为41.94%（质量）。针对轻烃催化裂解提出了原料特征化参数KF,它是原料H/C原子比、相对密度与分子量的函数,能较好地表征轻烃原料的催化裂解性能。     

SC-1型裂解炉中重烃-石脑油混合裂解性能优化

通过模拟实验,对大庆石化重烃-石脑油混合原料裂解性能进行了优化研究,考察了在SC-1型裂解炉中重烃质量分数分别为30%、35%的条件下,工艺参数对目的产物收率的影响。实验结果表明,重烃(质量分数30%、35%)-石脑油原料在SC-1型裂解炉中裂解,适宜的裂解温度均为850℃,水油质量稀释比为0.5时,三烯收率分别为53.78%、54.39%,重烃-石脑油混合裂解性能与石脑油单独裂解性能相近。重烃(质量分数35%)-石脑油原料裂解的模拟实验数据已应用于工业裂解炉中,使乙烯收率提高0.48%,三烯收率提高0.15%。     

石脑油催化裂解制低碳烯烃动力学

根据石脑油催化裂解的反应体系和集总理论,建立6集总动力学模型,采用Levenberg-Marquardt算法求解ZSM-5分子筛催化剂作用下的石脑油催化裂解动力学参数。结果表明,丙烯收率大大高于乙烯收率,丙烯与乙烯的质量比为1.0～2.0,明显高于传统的石脑油水蒸气裂解工艺,各集总的反应活化能均大于100 kJ/mol。通过对模型进行检验,发现模型计算值与实验值之间的误差均小于15%,表明该动力学模型能较好地预测石脑油催化裂解制低碳烯烃反应。     

环己酮肟低温溶剂重排反应动力学研究

实验考察了以环己烷为溶剂,环己酮肟在发烟硫酸催化下的Beckmann重排反应。结果发现,该反应能够在较低的温度下进行。在80℃、酸肟摩尔比为1.15的条件下,己内酰胺收率达到了98.68%。通过动力学实验,提出了能够预测新工艺在不同酸肟比、烟酸浓度及不同温度下的收率与时间关系的动力学模型,并借助遗传算法确定了反应动力学参数。模型预测检验及统计检验表明该动力学模型是可信的,而且模型预测值和实验结果较好地吻合。     

N-(2-羟乙基)-邻苯二甲酰亚胺的合成研究

报道了无溶剂法合成N-（2-羟乙基）-邻苯二甲酰亚胺。邻苯二甲酸酐与乙醇胺在无溶剂的条件下反应，质量收率达到99％以上，质量分数99％以上。讨论了反应温度，反应时间，物料比例及不同后处理方式对反应质量收率和质量分数的影响。该方法操作简便，实验条件温和，后处理简便，设备投入少，无污染，适合工业化生产。     

温度对地沟油催化裂解产物的影响

以小型固定流化床为实验装置,CIP-2为催化剂,研究了不同温度下地沟油催化裂解的产物分布,特别是丙烯产率和汽油馏分收率随裂解温度的变化规律。实验结果表明,液化气中丙烯质量分数最高,约占30%,且随着温度的增加逐渐增大,但反应温度大于540℃时丙烯质量分数的变化不明显。汽油馏分收率随着温度的升高先增大后降低。13C-NMR分析发现汽油馏分中芳烃取代基主要是短碳链取代,以甲基和乙基取代为主,分别占44. 2%和43. 5%。FT-IR分析表明,汽油馏分和柴油馏分中不含酯类羰基。     

生物乙醇催化脱水制乙烯的动力学研究

采用质量分数3%金属镧改性的HZSM-5分子筛催化剂,考察在较低的反应温度（200～300） ℃、固定床反应器内质量空速、催化剂粒径、反应温度以及反应物分压对乙醇转化率、产物收率和生成速率的影响,确定了乙醇脱水反应的动力学控制区域：质量空速≥20 h^-1,催化剂粒径≤0.7 mm。在此基础上,建立了生物乙醇催化脱水的动力学模型,拟合值和实验值吻合较好。     

Fe-Zn共改性ZSM-5催化作用下生物质快速热解特性研究

选取木屑和花生壳作为原料进行生物质热解,研究有机产物分布,催化剂使用Fe、Zn两种金属元素进行改性。通过X射线衍射（XRD）、扫描电镜（SEM）、傅里叶红外（FT-IR）、比表面积测试（BET）对Fe-Zn改性的ZSM-5进行分析。使用闪速裂解-气质联用仪（PY-GC/MS）对原料进行热解,探究生物质催化热解的产物分布变化。催化剂的使用使得芳烃类产物产率获得较大提升,在木屑热解中,Fe负载的分子筛催化获得了酚类的最高产率,比ZSM-5催化热解产率提升18.30%。金属改性催化剂在花生壳热解中,大幅提升了芳烃类产物产率,其中Zn负载催化剂芳烃类产物产率最高,Zn负载催化热解比直接热解的酚类产率降低了18.92%。Zn负载催化获得了最低的酮类产率,与直接热解相比酮类产率降低19.74%,显示出较强的脱羟基效果。此外Zn负载催化和Fe-Zn双金属负载催化在花生壳热解中都大幅降低了酸类产物产率,与直接热解相比酸类产率分别降低了30.46%、36.71%。     

Enhancing propylene production from catalytic cracking of Arabian Light VGO over novel zeolites as FCC catalyst additives

The catalytic cracking of vacuum gas oil over fluid catalytic cracking (FCC) catalyst containing novel additives was investigated to enhance propylene yield. A conventional ZSM-5, mesoporous ZSM-5 (Meso-Z), TNU-9 and SSZ-33 zeolite were tested as additives to a commercial equilibrium USY FCC catalyst (E-Cat). Their catalytic performance was assessed in a fixed-bed micro-activity test unit (MAT) at 520 °C and various catalyst/oil ratios. The cracking activity of all E-Cat/additives did not decrease by using these additives. The highest propylene yield of 12.2 wt.% was achieved over E-Cat/Meso-Z compared with 9.0 wt.% each over E-Cat/ZSM-5 and E-Cat/TNU-9, at similar gasoline yield penalty. The enhanced production of propylene over Meso-Z is attributed to its mesopores that suppressed secondary and hydrogen transfer reactions and offered easier transport and accessibility to active sites. The lower enhancement of propylene over the large-pore SSZ-33 additive was due to its high-hydrogen transfer activity. Gasoline quality was improved by the use of all additives, as octane rating increased by 7-12 numbers for all E-Cat/additives.     

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.     

Kinetic study of crude oil-to-chemicals via steam-enhanced catalytic cracking in a fixed-bed reactor

This study presents new experimental results on the direct conversion of crude oil to chemicals via steam-enhanced catalytic cracking. We have organized the experimental results with a kinetics model using crude oil and steam co-feed in a fixed-bed flow reactor at reaction temperatures of 625, 650, and 675°C over the Ce-Fe/ZSM-5 catalyst. The model let us find optimum conditions for crude oil conversion, and the order of the steam cracking reaction was 2.0 for heavy oil fractions and 1.0 for light oil fractions. The estimated activation energies for the steam cracking reactions ranged between 20 and 200 kJ/mol. Interestingly, the results from kinetic modelling helped in identifying a maximum yield of light olefins at an optimized residence time in the reactor at each temperature level. An equal propylene and ethylene yield was observed between 650 and 670°C, indicating a transition from dominating catalytic cracking at a lower temperature to a dominating thermal cracking at a higher temperature. The results illustrate that steam-enhanced catalytic cracking can be utilized to effectively convert crude oil into basic chemicals (52.1% C2-C4 light olefins and naphtha) at a moderate severity (650°C) as compared to the conventional high-temperature steam cracking process.     

Catalytic production of olefins using natural halloysite nanotubes

The production of C₂-C₄ olefins by deep catalytic cracking and the thermocontact pyrolysis of vacuum gas oil, commercial-grade cottonseed oil, and a vacuum gas oil-cottonseed oil 90: 10 mixture in the temperature range of 600–800°C is studied using natural halloysite extracted from kaolinite fields in the form of aluminosilicate sheets rolled in nanotubes. It is found that in the deep catalytic cracking of vacuum gas oil at 600°C using halloysite as a catalyst, the gain in the yield of ethylene is 6.4–10.1 wt %, compared to yields of this product when using ZSM-5 catalyst. Adding 10% commercial-grade cottonseed oil to the vacuum gas oil further increases the yield of ethylene by 2.2 wt % with a simultaneous 3.3 wt % rise in the yield of propylene. The cracking of pure cottonseed oil under identical conditions yields ethylene and propylene of 16.1 and 9.2 wt %, respectively. The possibility of using halloysite nanotubes as a heating surface for the thermal pyrolysis of the above feedstocks at temperatures of 700–800°C in order to obtain yields of C₂-C₃ olefins exceeding those of identical products in industry, and of reusing halloysites in the thermoconversion of the studied feedstocks via their complete regeneration, is confirmed.     

碳五烷烃裂解制低碳烯烃反应性能的分析

考察了碳五烷烃的热裂解和催化裂解反应性能,发现正戊烷和异戊烷的裂解反应产物存在差异;进一步分析了正戊烷和异戊烷的裂解反应机理,以及裂解生成低碳烯烃和甲烷的区别。结果表明,在热裂解条件下,正戊烷的（乙烯+丙烯）选择性高于异戊烷,异戊烷的丁烯和甲烷选择性高于正戊烷;650℃时,正戊烷和异戊烷的热裂解产品中（乙烯+丙烯）、丁烯、甲烷的选择性分别为37.48%、7.23%、6.75%和19.57%、25.16%、9.36%。而在催化裂解条件下,异戊烷的（乙烯+丙烯）、丁烯、甲烷选择性均高于正戊烷;650℃时,正戊烷和异戊烷的催化裂解产品中（乙烯+丙烯）、丁烯、甲烷的选择性分别为37.16%、9.11%、7.80%和47.70%、14.45%、13.79%。此外,发现在高温裂解条件下异构烷烃比正构烷烃容易裂解生成丁烯和甲烷。     

基于Py-GC/MS的玉米秸秆快速热解实验研究

以玉米秸秆为原料,利用Py-GC/MS设备在不同热解条件下进行快速热解实验,并对热解气相产物进行在线检测分析,考察了热解时间、热解温度及ZSM-5催化剂对玉米秸秆热解特性及热解产物分布的影响.实验结果表明:热解温度越高,热解反应越充分,且热解温度为550℃时对应的热解产物品质最高,其中芳香族化合物最高达28.3％;随着...     

烯烃裂解增产丙烯催化剂再生性能

由于烯烃裂解技术反应自身的特点,催化剂容易积炭失活,需要进行多次再生,因此,催化剂的再生性能对烯烃裂解技术至关重要。在实验室对中国石化中原石油化工有限责任公司烯烃裂解工业装置的ZSM-5催化剂进行了多次反应和再生试验,考察其烯烃裂解反应性能,并运用TG、XRD、NH₃-TPD、氮气物理吸附以及SEM等对再生前后的催化剂样品进行表征。结果表明,开发的烯烃裂解催化剂经过13次的反应再生过程,新鲜催化剂与再生催化剂的比表面积和孔容基本相同,烯烃转化率、丙烯及乙烯收率无明显变化,烯烃转化率仍大于73%,丙烯和乙烯收率分别大于32%和10%。且催化剂骨架结构和酸中心稳定,在多次反应与再生过程中的酸量保持不变,具有良好的再生性能。