CFD modeling of a mini-pilot scale CO2 hydrogenation to hydrocarbons reactor using both direct and indirect pathway-based kinetic model

IF 7.2 2区 工程技术 Q1 CHEMISTRY, MULTIDISCIPLINARY Journal of CO2 Utilization Pub Date : 2024-08-01 DOI:10.1016/j.jcou.2024.102914
Yubeen Jung , Ji-Eun Min , Hae-Gu Park , Ki-Won Jun , Jeong-Rang Kim , Mingyo Jeon , Myung-June Park
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Abstract

Both indirect CO2 hydrogenation (reverse water gas shift (RWGS) followed by CO-based Fischer-Tropsch synthesis (FTS)) and direct CO2-based FTS were considered for CO2 hydrogenation, and a kinetic model for the chain-length distribution of hydrocarbon products was developed. For independent estimation, the kinetic parameters were estimated by fitting the experimental data using powder catalysts under various conditions, mainly including CO/CO2 ratios. The contribution of indirect CO2 hydrogenation (RWGS followed by CO-FTS) was more favorable than that of direct CO2-FTS, and CO2 conversion and product selectivity were significantly dependent on the temperature and hydrogen fraction. The effectiveness factor was estimated for the pellet-type catalysts, and values less than one validated the existence of mass-transfer resistance. Computational fluid dynamics (CFD) modeling was used to simulate the three-dimensional thermal behaviors of a mini-pilot-scale reactor with a substantially large diameter loaded with a pellet-type catalyst and inert materials. Both a low catalyst loading in the early stage of the reactor and the use of an additional inner cooling tube showed a stable temperature profile, with the peak temperature maintained below 350 °C (the critical temperature to prevent the thermal decomposition of chemicals) and fast heating of cold feed in the early stage. The CFD results with no inner tube showed thermal runaway in the second reactor, and the simulation with arbitrarily reduced heat of the reaction (70 % of the actual value) resulted in a peak temperature higher than 410 °C. Further quantitative analysis indicated that the no-inner-tube case's reduced heat transfer area per unit volume was responsible for its thermally unstable behavior.

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使用基于直接和间接途径的动力学模型对小型中试规模二氧化碳加氢制烃类反应器进行 CFD 建模
考虑了二氧化碳加氢的间接二氧化碳加氢(反向水煤气变换(RWGS),然后是基于二氧化碳的费托合成(FTS))和基于二氧化碳的直接费托合成,并建立了碳氢化合物产物链长分布的动力学模型。为了独立估算,使用粉末催化剂在各种条件下(主要包括 CO/CO2 比率)拟合实验数据,估算动力学参数。与直接 CO2-FTS 相比,间接 CO2 加氢(先 RWGS 后 CO-FTS)的贡献更大,而且 CO2 转化率和产物选择性与温度和氢组分有显著关系。对颗粒型催化剂的有效因子进行了估算,其值小于 1 证明存在传质阻力。计算流体动力学(CFD)模型用于模拟一个装有颗粒型催化剂和惰性材料、直径很大的小型中试规模反应器的三维热行为。反应器早期阶段催化剂装填量较低和使用额外的内冷却管都显示出稳定的温度曲线,峰值温度保持在 350 ℃ 以下(防止化学品热分解的临界温度),早期阶段冷进料快速升温。无内管的 CFD 结果表明,第二反应器出现热失控,任意降低反应热(实际值的 70%)的模拟结果显示峰值温度高于 410 ℃。进一步的定量分析表明,无内管情况下单位体积传热面积的减少是其热不稳定行为的原因。
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来源期刊
Journal of CO2 Utilization
Journal of CO2 Utilization CHEMISTRY, MULTIDISCIPLINARY-ENGINEERING, CHEMICAL
CiteScore
13.90
自引率
10.40%
发文量
406
审稿时长
2.8 months
期刊介绍: The Journal of CO2 Utilization offers a single, multi-disciplinary, scholarly platform for the exchange of novel research in the field of CO2 re-use for scientists and engineers in chemicals, fuels and materials. The emphasis is on the dissemination of leading-edge research from basic science to the development of new processes, technologies and applications. The Journal of CO2 Utilization publishes original peer-reviewed research papers, reviews, and short communications, including experimental and theoretical work, and analytical models and simulations.
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