高效MFe_(2)O_(4)(M=Zn、Mg、Cu和Mn)尖晶石催化剂应用于费托合成

一系列尖晶石催化剂,包括ZnFe_(2)O_(4)、MgFe_(2)O_(4)、CuFe_(2)O_(4)和MnFe_(2)O_(4)被用于费托合成反应(Fischer-Tropsch synthesis,FTS)。Zn、Mg、Cu和Mn很容易与Fe形成尖晶石。其中,在前处理和反应过程中,Zn和Mg能够显著维持尖晶石结构,使得CO转化率较低。在反应过程中,Cu和Mn有利于碳化铁的生成,导致CuFe_(2)O_(4)和MnFe_(2)O_(4)对FTS性能影响显著。C_(2)^(=)-C_(4)^(=)ZnFe_(2)O_(4)对烃分布和C_(2)−C_(4)烯/烷比影响很小。MgFe_(2)O_(4)的C_(5+)选择性较低,同时由于Mg的碱性作用,从而提高了选择性和C_(2)−C_(4)烯/烷比。Cu可以促进催化剂的碳化,从而使CuFe_(2)O_(4)具有较高的活性。同时,CuFe_(2)O_(4)可以显著提高C_(5+)选C_(2)^(=)-C_(4)^(=)择性。此外,Cu可以促进H_(2)的解离和活化,从而有利于烯烃的二次加氢,降低选择性和C_(2)−C_(4)烯/烷比。虽然Mn在反应过程中会促进催化剂的碳化,但MnFe_(2)O_(4)对碳链的长短影响很小。然而,Mn能促进少量ε-Fe_(2)C的生成,这是导C_(2)^(=)-C_(4)^(=)致MnFe_(2)O_(4)具有较高选择性和C_(2)−C_(4)烯/烷比的原因。同时,所有尖晶石催化剂都具有较低的二氧化碳选择性,符合当前的绿色环保发展要求。

醚后C_(4)制2-PH的原料处理工艺研究

为解决炼厂生产2-PH(2-丙基庚醇)的主流生产工艺原料(醚后C_(4))中烷烃比例较高、烷烃无法直接参与反应的问题,研究了使用N-甲酰吗啉与甲乙酮混合溶剂对炼厂醚后C_(4)进行丁烯提浓的技术方案,并基于Aspen Plus软件进行了模拟分析,为在大型炼厂中建设2-PH装置提供参考。

乙醇耦合制备C_(4)烯烃问题研究

将Co/SiO_(2)-HAP催化剂应用于乙醇制备C_(4)烯烃,通过改变催化剂的装料方式、Co/SiO_(2)和HAP装料比、乙醇加入速率、Co与SiO_(2)的重量比及温度条件来提高C_(4)烯烃的收率。研究表明,不同的催化剂组合和温度对乙醇转化率,C_(4)烯烃选择性和C_(4)烯烃收率均有影响。随着温度的增加,乙醇转化率先增加后减小,C_(4)烯烃选择性先增加后减小。通过对实验数据建立多元曲线回归模型得到当反应温度大于350℃时,主要产物为C_(4)烯烃。通过研究C_(4)烯烃收率与乙醇转化率、C_(4)烯烃选择性的关系,以获得最优C_(4)烯烃收率为目标构造单目标最优化模型,并求得C_(4)烯烃收率最优温度为400℃,催化剂组合为:Co/SiO_(2)和HAP装料比1.36;Co负载量2.78;乙醇加入速率0.89 mL/min。

Catalytic conversion of bioethanol to value-added chemicals and fuels:A review

Bioethanol produced via valorisation of renewable biomass is of great interest to many industries.The increased availability and decreased cost of bioethanol make it a promising platform molecule to produce a wide range of value-added chemicals and fuels via the catalytic conversions.This paper provides a comprehensive review of catalytic conversions of bioethanol to a variety of chemicals/fuels such as hydrogen,C_(2)-C_(4)olefins,gasoline and small oxygenates.Specifically,the focus was placed on the relationship between the catalyst property(such as pore structure,acidity,active metal sites,and catalyst supports)and the catalytic performance(including catalyst activity and stability),as well as the reaction mechanisms involved.Future research avenues on the catalyst design for improving catalytic valorisation of bioethanol are also discussed.