Simulation of biodiesel industrial production via solid base catalyst in a fixed-bed reactor

Biodiesel industrial production based on a solid base catalyst in a fixed-bed was simulated. The lab and bench scale experiments were carded out effectively, in which the kinetic model is established and it can describe the transesterification reaction well. The Antoine equation of biodiesel is regressed with the vapor-liquid data cited of literature. The non-random two liquid （NRTL） model is applied to describe the system of fatty acid methyl ester （FAME）, methanol and glycerol and parameters are obtained. The Ternary phase map is obtained from Aspen Plus via the liquid-liquid equilibrium （LLE） data. In order to describe the production in a fixed-bed performs in industrial scale after being magnified 1 000 times, the Aspen Plus simulation is employed, where two flowsheets are simulated to predict material and energy consumption. The simulation results prove that at least 350. 42 kW energy consumption can be reduced per hour to produce per ton biodiesel compared with data reported in previous references.

Mesoporogen-free synthesis of hierarchical sodalite as a solid base catalyst from sub-molten salt-activated aluminosilicate

A rapid and environmentally friendly approach to synthesize hierarchical sodalite from natural aluminosilicate mineral without the involvement of any mesoporogen or post-synthesis treatment was developed.This strategy involves three important steps:the first is the depolymerization of an aluminosilicate mineral into highly reactive silicon and aluminum species with ideal meso-scale structures through activation of a sub-molten salt.The second step is the hydrolysis and condensation of the activated aluminosilicate mineral into zeolitic precursors that also have a meso-scale structure.The third is the rapid zeolitization of the zeolitic precursors through the reversed crystal growth route at room temperature and ambient pressure to form hierarchical sodalite.The physicochemical properties of the as-synthesized sodalite were systematically characterized,and the formation mechanism of the hierarchical pore structure was discussed.When used as a solid base catalyst for Knoevenagel condensation,the as-synthesized sodalite and its potassium ion-exchanged product with hierarchical micro-meso-macroporous structure both exhibited high catalytic activity and product selectivity.

Synthesis of dimethyl adipate from cyclopentanone and dimethyl carbonate over solid base catalysts

A facile route for the synthesis of dimethyl adipate （DAP） from cyclopentanone and dimethyl carbonate （DMC） in the pres- ence of solid base catalysts has been developed. It was found that the intermediate carbomethoxycyclopentanone （CMCP） was produced from cyclopentanone with DMC in the first step, and then CMCP was further converted to DAP by reacting with a methoxide group. The role of the basic catalysts can be mainly ascribed to the activation of cyclopentanone via the abstraction of a proton in the a-position by base sites, and solid bases with moderate strength, such as MgO, favor the formation of DAP.

Transesterification of glyceryl tributyrate with methanol using strontium borate as the solid base catalyst

Four kinds of strontium borates were prepared and characterized by XRD, SEM, EDS, TG-DTA and Hammett titration method and their catalytic activities were examined in the transesterification of glyceryl tributyrate with methanol for the first time. The separate effects of the molar ratio of methanol to oil, the reaction time, and reusability were investigated. In addition, the catalytic activities of Sr（OH）2 and SrCO3 were also examined for the comparison. The results showed that the basicity and catalytic activity of these catalysts were decreased as the following order： Sr（OH）2 〉 SrB2O4·4H2O 〉 SrB6O10·5H2O 〉 SrB2O4 〉 SrB6O10 〉 SrCO3, and the reusability decreases as the following order： anhydrous strontium borates （SrBgO4, SrB6O10） 〉 hydrated strontium borates （SrB2O4·4H2O, SrB6O10·5H2O） 〉 Sr（OH）〉 The results indicate that the SrB2O4·4H2O with regular morphology, which was obtained at low temperature by a simple preparation method, might be as one kind of good potential alkaline earth salts catalyst for transesterification. Moreover, the possible reaction mechanism is proposed and analyzed.

Development of solid base catalyst X/Y/MgO/-Al_(2)O_(3) for optimization of preparation of biodiesel from Jatropha curcas L.seed oil

The preparation and regeneration conditions of the identified catalyst X/Y/MgO/?-Al2O3 with high catalytic activity were studied and optimized. The biodiesel was prepared by transesterification of Jatropha curcas seed oil produced in Guizhou with methanol at its reflux temoerature in the presence of X/Y/MgO/?-Al2O3 . The pilot plant tests were carried out in a 100 L reaction vessel. Both average yield and fatty acid methyl esters (FAME) content reached more than 96.50% under the optimum reaction conditions of the pilot plant tests designed with an oil/methanol molar ratio of 1 : 10, catalyst concentration of 1.00%, and reaction time of 3 h at reflux temperature. In addition, analysis shows that the quality of biodiesel meets the standard EN 14214.

Preparation, Characterization and Catalytic Activity of Alkyl Benzene Sulfonic Acid Carbon-Based Acid Catalyst

Based on starch and series of alkyl benzene sulfonic acid as the materials, a novel carbon-based solid acid catalyst is synthesized using hydrothermal method. This catalyst exhibits much higher catalytic activity in the reaction of esterification of Mono-fatty alcohol polyoxyethylene maleate esters with 1,4-butanediol. The structure of carbon-based solid acid catalyst was charactered by IR and XRD, characterizations showed that this catalyst exhibited high –SO3H loading. Reusability of the carbon-based solid acid catalyst for esterification showed that after recycling five times the activity remained unchanged.

钙铈基催化剂上碳酸丙烯酯和甲醇制备碳酸二甲酯的研究

采用溶胶凝胶法制备了不同比例的钙铈基催化剂,并研究了其对于碳酸丙烯酯和甲醇制备碳酸二甲酯的酯交换反应性能。结果表明,Ca∶Ce=9的催化剂在反应时间2 h,温度40℃,甲醇与碳酸丙烯酯物质的量比为15∶1,催化剂用量为碳酸丙烯酯用量4%的条件下,碳酸丙烯酯转化率达到91.1%,碳酸二甲酯选择性达到91.7%。采用XRD、N2吸附-脱附、FT-IR、XPS和CO_(2)-TPD对催化剂进行了表征。结果表明,催化剂表面的氧空穴越多,中等碱性位数量越多,越有利于甲醇的活化,催化剂的活性越好。

铌基固体酸催化剂的制备及催化玉米芯制备糠醛性能研究综合教学实验设计

本实验设计合成了一系列铌基固体酸催化剂,并对催化剂材料进行理化性质表征和催化玉米芯转化制备糠醛性能评价。通过开展本实验,使学生初步掌握玉米芯制备糠醛的工艺过程及原理,了解催化剂的制备及表征方法。本综合性实验将化学工程与工艺专业本科生实验教学工作与指导教师的科研项目相结合,培养学生的创新思维方式及团队协作精神,提高学生的实践动手能力,启发学生的科研意识,为将来从事相关专业领域的工作打下良好的基础。

糠醛MPV还原制糠醇中固体酸碱催化剂的研究进展

介绍了固体酸碱催化剂在糠醛Meerwein-Ponndorf-Verley(MPV)还原制糠醇中的研究进展。糠醛作为高度商品化的生物基平台化合物,其可通过加氢还原为更具有经济价值的化学品。MPV还原因其条件温和、安全和环保而受到生物炼制领域青睐。介绍MPV典型反应及六元环过渡态的形成过程;对不同固体酸碱催化剂在糠醛MPV还原制糠醇中的研究进展进行总结,其中锆/铪基催化剂具有优异的MPV还原性能被广泛研究;针对固体酸碱催化剂在该领域进行总结,并指出存在的主要问题和解决方法,同时对该领域未来的发展进行展望。

试论新型固体碱催化剂在有机合成中的应用

固体碱催化剂在有机合成中的应用历史悠久,是一种成熟而有效的生产工艺,其工艺应用场景广阔。为充分满足有机合成生产要求,将介绍一种新型固体碱催化剂。在了解其制备工艺的基础上,详细说明该催化剂在有机合成中的应用方案与效果。根据试验研究的内容,整个试验过程展现出了良好的催化效果,且该催化剂具有可重复使用的特点,满足工业化生产要求。

碳基固体酸催化剂的制备及其催化合成生物柴油的性能研究

采用磷酸浸渍后进行炭化-磺化法,研究得到了以竹粉为代表的活性炭原料,优化合成碳基固体酸的方法。实验结果表明,以竹炭基固体酸为催化剂,在350℃,炭化时间2 h,磺化温度1 059℃,磺化时间4 h的情况下,所制备的催化剂性能最好。而该催化剂用量为10.1%(质量分数),醇酸物质的量比为10,酯化温度为65.5℃,酯化时间为2 h的酯化效率最高,可达98.2%。研究以竹粉为原料,利用生物质制备固态酸催化剂,其在生物柴油的合成中更有前景和竞争力。

固体磷酸催化竹屑液化的反应机理

固体磷酸为催化剂液化竹屑制备生物基多元醇,利用FT-IR、GC-MS、NMR等技术和方法对液化产物组成进行了表征,研究其反应机理。研究结果表明:Vinyl ethyl carbitol等烯烃类的生成主要是通过固体磷酸催化PEG400一端脱去羟基形成的,而戊二酸物质等物质主要是由固体磷酸催化纤维素等生物质通过氧化重排而形成,除此之外,固体磷酸还解决液化产物酸值高的问题。

冶金含铁尘泥制备的Mn–Ce掺杂Fe基催化剂及特性

针对冶金工业固废–含铁冶金尘泥组分复杂的特性,结合当前冶金烧结过程NO_x排放也是钢铁行业污染治理的重中之重的现状,提出对冶金含铁尘泥进行改性制备掺杂低温催化剂的思路,并制备了Mn–Ce掺杂的含铁尘泥基催化剂(Mn_(0.05)Ce_(0.1)/ADM,ADM分别代表acidolysis,dust和mud),研究结果表明在170~430℃宽温度区间内,Mn_(0.05)Ce_(0.1)/ADM催化剂NO_x脱除率达到90%以上,并表现出优异的SO_(2)和H_(2)O抗性,抗水抗硫性测试表明Mn_(0.05)Ce_(0.1)/ADM催化剂得益于Fe、Ce优异的抗水抗硫性,其活性组分具有较好的分散性和优异的介孔结构,并降低了表面结晶度. Mn掺杂使催化剂在牺牲一定Ce^(3+)浓度和高价态Mnx+离子的同时提高了Fe^(3+)的浓度,结果使其具有最均衡脱硝活性.此外,Fe–Ce–Mn间的协同作用改善了催化剂的表面酸性从而增加了Lewis酸性位点,进而促进静电极化激活NO_(2)和硝酸盐物种生成.研究结果可为冶金固废的高附加值利用及以废治污的思路提供一定理论参考.

固载型席夫碱金属配合物对醇催化氧化研究进展

席夫碱过渡金属配合物因其易制备及特殊性能被广泛应用,但作为均相催化剂使用时,不易于与产物分离及在反应过程中易发生聚合而失去活性等问题。在分离技术的发展情况下,固载型席夫碱金属配合物作为一种极具潜力的多相催化剂而被广泛应用于各种氧化反应中,尤其苯甲醇的选择性催化氧化是研究的热点。本文综述近十年固体载体固载席夫碱过渡金属配合物对苯甲醇的选择性催化氧化性能的研究。本综述主要对磁性纳米颗粒作为载体对苯甲醇的选择性催化氧化反应进行评述。

Preparation of KOH/CaO/C Supported Biodiesel Catalyst and Application Process

KOH/CaO/C supported catalyst was prepared via incipient wetness impregnation and used in synthesis of biodiesel. First, the effects of carrier/active components mass ratio, calcination temperature and calcination time on catalytic activity were investigated aiming at biodiesel yield, and the optimal process conditions for preparation of KOH/CaO/C catalysts were: mass ratio of C/CaO was 4:6;KOH solution (mass concentration) was 25%;impregnation time was 24 h;drying temperature was 105°C and time was 4 h;calcination temperature was 500°C and time was 5 h. Then the complex catalysts prepared under the optimal conditions were applied to synthesize biodiesel, and the effects of dose of catalyst, reaction temperature, and reaction time on the yield of biodiesel were investigated. At last, the optimal process conditions for synthesis of biodiesel were concluded: methanol-oil ratio was 10:1;catalyst dose was 2% of that of soybean oil;reaction temperature was 65°C;reaction time was 5 h. The yield of as-prepared biodiesel could be 98%.

固体碱催化剂在乙烯基醚合成中的应用

乙烯基醚是精细化工中一类重要的中间体和聚合单体,乙烯基醚的主要合成方法有乙炔法、酯交换法、缩醛热分解法、脱卤化氢法等。其中乙炔法合成乙烯基醚采用的固体碱催化剂易分离、可重复使用、选择性高,设备腐蚀、环境污染危害小,可实现大规模工业化生产。综述了近几年固体碱催化剂的类型和制备方法,并对其催化合成乙烯基醚进行展望。

Li/Y_(2)O_(3)催化合成二甘醇乙烯基醚的应用研究

以市售氧化钇为载体,采用过量浸渍法制备一系列不同锂含量的Li/Y_(2)O_(3)固体碱催化剂,对其进行SEM、XRD和CO_(2)-TPD等表征,用于催化二甘醇(DEG)和乙炔反应生成二甘醇乙烯基醚(DEGD)。考察了Li负载量、催化剂用量、反应温度、反应时间对转化率的影响。实验结果表明,Li负载量为10%时,m(cat)∶m(DEG)=0.08,反应温度为175℃,反应时间为8 h,二甘醇的转化率为37.9%。催化剂循环使用5次后,也能表现出较好的稳定性。

固体碱催化剂Na_(2)SiO_(3)/MgO催化大豆油合成生物柴油的研究

以MgO为载体,采用等体积浸渍法制备固体碱催化剂Na_(2)SiO_(3)/MgO。通过X射线衍射(XRD)和傅里叶变换红外光谱(FT-IR)分别对催化剂和产物进行表征。通过单因素试验和正交试验优化了大豆油制备生物柴油的工艺条件。结果表明:当Na_(2)SiO_(3)/MgO中的Na_(2)SiO_(3)负载量为20%(以MgO质量计)、醇油摩尔比为10∶1、催化剂用量4%(以大豆油质量计)、反应温度55℃、反应时间3h时,生物柴油的产率可以达到98.77%。XRD表征结果表明,当Na_(2)SiO_(3)的负载量为20%时,Na_(2)SiO_(3)以单层分散的形式附着在载体MgO表面,且没有形成新的晶体。FT-IR表征结果表明,所合成产物分子的官能团结构与目的产物相符。

双功能碳基固体酸催化木糖制备糠醛的研究

本研究以明胶和植酸(PA)为碳源,并掺杂FeCl_(3)·6H_(2)O和ZnCl_(2),通过硫酸磺化法制备了双功能碳基固体酸催化剂用于高效催化木糖制备糠醛。采用SEM、BET、FT-IR、STEM-EDS等方法对不同炭化温度下制备的催化剂进行了表征,揭示了催化剂的物理化学性质。并考察了催化剂的炭化温度、FeCl_(3)·6H_(2)O与ZnCl_(2)物质的量比、反应温度、反应时间、γ-戊内酯(GVL)与H_(2)O的体积比、催化剂用量对木糖转化为糠醛(FF)的影响。结果表明,600℃炭化制备的催化剂CNPS600-Fe_(4)-Zn_(2)催化效果较好,用0.03 g的CNPS600-Fe_(4)-Zn_(2)(FeCl_(3)·6H_(2)O与ZnCl_(2)物质的量比为4∶2)在3 mL的GVL/H_(2)O(体积比为9∶1)溶剂体系中催化0.06 g木糖制备FF,当反应温度为170℃、反应时间为120 min时,木糖的转化率为99.6%,FF的摩尔产率可达85.8%。此外,还对催化剂的循环性能进行了测试,经五次循环实验后FF摩尔产率和木糖转化率均能保持在原来的80%以上,表明该催化剂具有较高的催化活性和较好的水热稳定性。