Steam Stripping-Coupled Cycle for Thermodynamic Optimization and Carbon Cycle Intensification in CO/CO<sub>2</sub> Mixed-Gas Hydrogenation Methanol Synthesis.
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ABSTRACT: Methanol synthesis, a crucial platform chemical and clean energy carrier, plays a significant role in the global energy transition. This study focuses on thermodynamic optimization and carbon cycle intensification of the CO/CO2 hydrogenation process. A multidimensional reaction system model was developed to investigate the effects of the CO/CO2 feed ratio, H2/CO x molar ratio, reaction temperature and pressure, catalyst efficiency, and gas-liquid mass transfer resistance on product distribution. To improve carbon utilization, an innovative steam stripping-coupled cycle process was proposed, enabling efficient recovery of dissolved CO2 in the liquid phase through phase equilibrium regulation. This reduced the CO2 content from 10.72 kmol·h-1 before stripping to 1.69 × 10-4 kmol·h-1 after stripping. Under optimized operating conditions, the methanol yield reached 82.0%, and the single-pass yields of CO and CO2 were 90.7% and 72.6%, respectively. After the novel stripping cycle was adopted, the loss of liquid-phase CO2 became negligible, with carbon and hydrogen losses mainly caused by gas-phase relaxation. When the relaxation rate was set to 1.0%, the utilization of CO x and H2 reached 93.2% and 82.8%, respectively. This strategy established a dynamic reaction-separation-recycle balance, improving both resource efficiency and economic performance, and offering theoretical and technical guidance for green methanol industrialization.
SUBMITTER: Yu X
PROVIDER: S-EPMC12423964 | biostudies-literature | 2025 Sep
REPOSITORIES: biostudies-literature
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