甲醇制低碳烯烃(MTO)反应热力学研究

对甲醇制低碳烯烃反应过程进行了热力学分析。着重计算了甲醇制烯烃主副反应的反应热、吉布斯自由能、平衡常数以及烯烃产物之间的平衡关系等。甲醇制烯烃大多数反应为强放热反应,总反应热在37～53kJ/mol之间,而且大多数反应都可以自发进行,并进行到很高的程度。通过烯烃产物之间平衡关系的计算,发现计算结果与实际的甲醇制烯烃反应现象比较一致,随着反应温度的升高,乙烯平衡摩尔分数持续增大,丁烯平衡摩尔分数持续下降,而丙烯摩尔分数则先升后降。烯烃产物之间的相互转化属于热力学平衡限制。

甲醇制低碳烯烃反应体系的热力学计算与分析

采用原子矩阵法确定了甲醇制低碳烯烃独立的反应数,采用Gibbs自由能最小化方法,建立了计算烯烃产物之间平衡关系的数学模型,简化了计算过程。计算了甲醇制低碳烯烃各独立反应的Gibbs自由能及烯烃产物之间的平衡关系。热力学分析表明,甲醇制低碳烯烃反应主要为动力学控制,提高反应温度、降低反应压力和加水有利于乙烯平衡组成增加和乙烯与丙烯总平衡组成的增加,丙烯平衡组成随温度、压力变化存在最大值。计算数据与文献值比较表明,该法计算结果可靠,对甲醇制低碳烯烃的实验室研究及工业化生产有指导意义。

甲醇制丙烯反应的热力学研究

对基于ZSM-5分子筛催化剂的甲醇制丙烯反应体系进行了热力学分析,计算了不同温度下各反应的反应焓变、吉布斯自由能变和反应平衡常数,采用最小自由能法计算了C2～6烯烃的热力学平衡组成。计算结果表明,烯烃甲基化反应为放热反应,烯烃裂化反应为吸热反应,甲醇生成丙烯反应的放热量约为30 kJ/mol;烯烃甲基化可视为不可逆反应,烯烃裂化为可逆反应。不同甲醇分压下均存在最佳反应温度,使丙烯平衡组成最高,平衡质量分数接近40%。采用小孔分子筛催化剂可有效提高丙烯平衡组成。

Effects of Vanadium Oxidation Number on Light Olefins Selectivity of FCC Catalyst

Effects of vanadium on light olefins selectivity of FCC catalysts were investigated with vanadium having different oxidation numbers （hereinafter abbreviated as Oxnum）. Molecular modeling studies showed that vanadium with low Oxnum could affect the chemical conversion of large-size hydrocarbon molecules. However, the vanadium deposited on equilibrium catalyst bad high Oxnum because of the oxidation reaction taking place in the regenerator, so an activation method to reduce vanadium Oxnum named ＂selective activation＂ was introduced. It was proved by means of Electron Paramagnetic Resonance （EPR） and Temperature-Programmed Reduction （TPR） methods that the vanadium Oxnum was decreased, when the catalyst was activated. The molecular modeling studies are consistent well with the lab evaluation results. The light olefins selectivity of activated equilibrium catalysts was better than that achieved by the inactivated catalysts. Similar results were observed with the lab vanadium-contaminated catalyst. The light olefins selectivity of the catalyst was optimized when the vanadium Oxnum was close to 2 （VO）.