Kinetics of Liquid-Phase 1-Butene Hydroisomerization over Pd/Al 2 O 3 Catalysts

Competitive hydrogenation of mixtures of unsaturated compounds is a topical area of research, mainly due to their continued presence in industrial feedstocks. Here, we investigate the effects of coating a catalyst with the ionic liquid 1,3dimethylimidazole methyl sulfate [MMIM][MeOSO 3 ] at various isoconversions in the competitive hydrogenation of 1-octyne versus 1-octene. Our results indicate that solid catalyst with an ionic liquid layer (SCILL) catalysts offer advantages compared to the uncoated versions. We also investigated some of the difficulties in creating SCILL catalysts which can lead to catalyst deactivation, with crystallite morphologies appearing to play a role in catalyst deactivation with time on exposure to the atmosphere.

Section: ■ Results and Discussionmentioning

confidence: 97%

Section: Experimental Sectionmentioning

confidence: 99%

Activity and Selectivity of a Nickel SCILL Catalyst in the Competitive Hydrogenation between 1-Octene and 1-Octyne

Miller,

Friedrich,

Dasireddy

2023

Comparison of Reactive Distillation Packings Used for 1-Butene Isomerization

Chen,

Yu,

et al. 2024

The reactive distillation process of 1-butene isomerization is an important technique for utilizing abundant C4 hydrocarbons, and using proper reactive distillation packings is critical to the performance of this process. Herein, two typical packings are compared in terms of hydrodynamic properties and reaction-separation performance for 1butene isomerization. Compared to Katapak packing, the dynamic liquid holdup of Lummus packing is less sensitive to the change of liquid flow density and gas-phase kinetic energy factor, and its wet pressure drop is lower at high gas and liquid flow rates. These differences in hydrodynamic properties can be attributed to the higher void fraction and larger flow channels of Lummus packing and indicate that Lummus packing is better in operational flexibility. The simulations show that using Katapak in the reactive distillation column yields higher 1-butene conversion and 2butene purity in the product, indicating that Katapak is better in the reaction-separation performance. This can be attributed to the higher catalyst filling capacity and larger specific surface area of Katapak. These results should serve to guide the selection and design of reactive distillation packings for 1-butene isomerization.

Experimental and Kinetic Model for Enhanced Liquid-Phase Hydrogenation of o-Cresol in a Distributor-Type Multichannel Ceramic Membrane Reactor

Jiang,

Zhu,

Tang

et al. 2024

The green production process of o-methylcyclohexanol is particularly important due to its widespread industrial applications. Addressing the issue of low mass transfer efficiency of hydrogen in traditional liquid-phase hydrogenation processes, multichannel ceramic membranes as hydrogen dispersion tools are introduced, successfully achieving uniform and efficient dispersion of hydrogen in the o-cresol cyclohexane solution, thereby promoting the efficient hydrogenation of o-cresol to omethylcyclohexanol within a fixed-bed reactor. The results show that compared to conventional single-tube feeding methods, the introduction of ceramic membranes significantly enhances the ocresol conversion and o-methylcyclohexanol selectivity. By optimizing the pore size (200 nm), channel number (19 channels) of the ceramic membranes, and operating conditions, o-cresol conversion and the o-methylcyclohexanol selectivity of no less than 99.5% are achieved under optimal operating conditions. Furthermore, a macro-kinetic model for the membrane-dispersion-enhanced liquid-phase hydrogenation of o-cresol is established, which incorporates an empirical equation for hydrogen solubility. Validation results show that the model-calculated reaction rates of o-cresol are highly consistent with experimental data, with errors controlled within 5%, providing theoretical support for the precise regulation of experimental operating conditions. The work offers a new strategy for the green production of o-methylcyclohexanol.