甲醇重整气中CO去除的研究进展

评述了质子交换膜燃料电池(PEMFC)甲醇重整气中CO去除的现实意义。对CO去除的常用方法钯膜及选择性氧化进行了综述,重点介绍了选择性氧化催化剂。

甲醇和甲醇重整气对直喷汽油机性能影响的对比研究

基于GT-Power并耦合层流火焰速度经验公式开展了甲醇和甲醇重整气对直喷汽油机性能影响的对比分析。首先分别基于双燃料层流火焰速度经验公式,求取了异辛烷-甲醇和汽油-甲醇重整气层流火焰速度,根据层流火焰速度计算出燃烧持续期,作为燃烧模型的输入变量,进而探讨了汽油掺混不同比例的甲醇及甲醇重整气对发动机性能的影响规律。研究结果表明:掺混甲醇重整气与直接掺混甲醇相比,发动机有效热效率和输出转矩明显增加,当量比油耗降低,CO排放水平相当,但NOx排放增加。尤其在稀燃条件下,掺混甲醇重整气使热效率增加明显,这说明燃料重整方式在提高直喷汽油机热效率方面更有应用潜力。

甲醇重整气发动机HCCI燃烧的数值模拟

对甲醇重整气发动机的HCCI燃烧过程进行模拟计算,找出其化学反应路径,探讨利用增压实现甲醇重整气HCCI燃烧的可行性.采用单区模型和详细化学反应动力学机理模拟燃烧,比较计算结果与试验结果,验证模型正确性;分析主要中间产物生成率的变化,确定关键反应,得出主要反应路径;计算增压对放热率、缸压、指示功率的影响.研究表明,甲醇重整气的HCCI燃烧呈单阶段放热,计算的着火时刻、缸内压力和NOx排放与试验值吻合;OH、H、O、HO2和H2O2是关键中间产物,它们的生成和消耗构成循环,是燃烧的主要路径;对进气适当增压可保证压燃进而省掉进气加热器并能提高指示功率,增压比过低、过高或进气中冷均不可取.

柴油机进气掺混甲醇重整气燃烧过程及排放特性

以某型四缸柴油机为研究对象,采用数值模拟计算的方法,研究了柴油机进气掺混甲醇重整气的燃烧过程中,以及重整气掺混比和喷油正时对缸内压力、燃烧放热过程、Soot和NO_(x)排放的影响。结果表明:与原机相比,掺烧甲醇重整气和氢气后,缸内压力、温度和放热率峰值均有所升高,Soot排放大幅降低,NO_(x)排放升高且滞燃期和燃烧持续期缩短;掺烧氢气及甲醇重整气均有助于改善缸内燃烧,提高燃烧等容度,提升热效率;掺烧甲醇重整气后缸内压力、燃烧温度和放热率峰值较低于柴油机掺烧氢气,Soot排放降低28.5%,NO_(x)排放升高16.9%。随着重整气掺混比的提升,缸内压力、燃烧温度和放热率峰值均进一步提升,滞燃期和燃烧持续期进一步减少,燃烧速度加快,燃烧持续期缩短,等容度燃烧加强。通过喷油正时的推迟,柴油机掺烧甲醇重整气后缸内燃烧重心后移,后燃比重增加,燃烧等容度下降,Soot排放和NO_(x)排放降低,柴油机功率降低。

DFT Study on the Catalytic Role ofα-MoC(100)in Methanol Steam Reforming

In this work,we investigated the methanol steam reforming(MSR)reaction(CH_(3)OH+H_(2)O→CO_(2)+3H_(2))catalyzed byα-MoC by means of density functional theory calculations.The adsorption behavior of the relevant intermediates and the kinetics of the elementary steps in the MSR reaction are systematically investigated.The results show that,on theα-MoC(100)surface,the O−H bond cleavage of CH3OH leads to CH3O,which subsequently dehydrogenates to CH_(2)O.Then,the formation of CH_(2)OOH between CH_(2)O and OH is favored over the decomposition to CHO and H.The sequential dehydrogenation of CH_(2)OOH results in a high selectivity for CO_(2).In contrast,the over-strong adsorption of the CH_(2)O intermediate on theα-MoC(111)surface leads to its dehydrogenation to CO product.In addition,we found that OH species,which is produced from the facile water activation,help the O−H bond breaking of intermediates by lowering the reaction energy barrier.This work not only reveals the catalytic role played byα-MoC(100)in the MSR reaction,but also provides theoretical guidance for the design ofα-MoC-based catalysts.