Reaction Mechanism Development for Methane Steam Reforming on a Ni/Al2O3 Catalyst

Richter, Jana; Rachow, Fabian; Israel, Johannes; Roth, N; Charlafti, Evgenia; Günther, Vivien; Flege, Jan Ingo; Mauß, Fabian

doi:10.3390/catal13050884

Cited by 7 publications

(2 citation statements)

References 33 publications

(59 reference statements)

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“…There are other possible side reactions, like a direct reaction between CH 4 and CO 2 , CH 4 and CO, and methane decomposition, etc. These side reactions are more abundant if heterogeneous catalysts are used in the process [28,29]. The production of H 2 depends on the equilibrium of the reforming and adjustment reactions (Equations ( 1) and ( 2)), and it can be maximized with low pressures, high temperatures in reforming, and a high excess of steam [30,31].…”

Section: Drmmentioning

confidence: 99%

A Review on the Use of Catalysis for Biogas Steam Reforming

Nogales-Delgado,

Álvez-Medina,

Montes

et al. 2023

Catalysts

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Hydrogen production from natural gas or biogas, at different purity levels, has emerged as an important technology with continuous development and improvement in order to stand for sustainable and clean energy. Regarding biogas, which can be obtained from multiple sources, hydrogen production through the steam reforming of methane is one of the most important methods for its energy use. In that sense, the role of catalysts to make the process more efficient is crucial, normally contributing to a higher hydrogen yield under milder reaction conditions in the final product. The aim of this review is to cover the main points related to these catalysts, as every aspect counts and has an influence on the use of these catalysts during this specific process (from the feedstocks used for biogas production or the biodigestion process to the purification of the hydrogen produced). Thus, a thorough review of hydrogen production through biogas steam reforming was carried out, with a special emphasis on the influence of different variables on its catalytic performance. Also, the most common catalysts used in this process, as well as the main deactivation mechanisms and their possible solutions are included, supported by the most recent studies about these subjects.

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Section: Drmmentioning

confidence: 99%

A Review on the Use of Catalysis for Biogas Steam Reforming

Nogales-Delgado,

Álvez-Medina,

Montes

et al. 2023

Catalysts

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“…The SMR reaction typically occurs at elevated temperatures (900-1200 K) and pressures (5-25 bar) [6,9], with a preference for high temperatures and low pressures. Due to the production of high concentrations of carbon monoxide (CO) in the reaction products, the SMR process is inherently coupled with the water-gas shift reaction (WGS) (2).…”

Section: Introductionmentioning

confidence: 99%

Analytical and Numerical Thermodynamic Equilibrium Simulations of Steam Methane Reforming: A Comparison Study

Varandas,

Oliveira,

Borges

2024

Reactions

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Computer simulation is a crucial element in the design of chemical processes. Although numerous commercial software options are widely recognized, the expense associated with acquiring and sustaining valid software licenses can be prohibitive. In contrast, open-source software, being freely available, provides an opportunity for individuals to study, review, and modify simulation models. This accessibility fosters technology transfer and facilitates knowledge dissemination, benefiting both academic and industrial domains. In this study, a thermodynamic equilibrium steady-state analysis of steam methane reforming using a natural-gas-like intake fuel was conducted. An analytical method was developed on the Microsoft Excel platform, utilizing the material balance equations system. The obtained results were compared to numerical methods employing the free-of-charge chemical process simulation software COCO and DWSIM. The investigation explored the influence of temperature, pressure, and steam-to-carbon ratio to determine optimal operating conditions. The findings suggest that higher temperatures and lower pressures are highly favorable for this process, considering that the choice of steam-to-carbon ratio depends on the desired conversion, with a potential disadvantage of coke formation at lower values. Consistent results were obtained through both analytical and numerical methods. Notably, simulations performed using DWSIM showed a deviation of 6.42% on average compared to COCO values. However, it was observed that the analytical method tended to overestimate the results by an average of 3.01% when compared to the simulated results from COCO, highlighting the limitations of this analytical approach.

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