Abstract
Reaching CO2 reduction goals for 2030 and beyond involves cross-sectoral information sharing and transdisciplinary research collaborations. The International Future Laboratory for Hydrogen Economy at the Technical University of Munich (TUM) has proposed a network model for an international green hydrogen economy based on three pillars: electrically assisted gasification, reversible solid oxide cells, and biocatalytic synthesis. Advanced artificial intelligence (AI)-based machine learning approaches are utilised to evaluate and optimise SOC-ready clean syngas preparation. Using DoE, the pre-reforming process of various syngas constellations has been evaluated. The possibility of developing and simulating the complex thermochemistry of syngas-containing fuel using a CFD model of a pre-reformer is approved. The model is utilised to create data for the successful construction and training of an AI-based machine-learning model. A multi-regression study illustrates the interactions between process factors in order to comprehend and improve the fuel outlet conditions of the pre-reforming process, which are essential for the fuel inlet region of solid oxide cells. The ML model and numerical CFD predictions are in excellent agreement showing less than 1% error. It was possible to precisely define the operating parameters for three distinct syngas configurations in order to achieve 500 °C fuel outlet conditions. Consequently, the results contribute to a better knowledge of the preparation of high-quality, pure syngas, furthering sustainable research and r-SOC operation in a safe, consistent manner.
Original language | English |
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Pages (from-to) | 24002-24017 |
Number of pages | 16 |
Journal | International Journal of Hydrogen Energy |
Volume | 48 |
Issue number | 62 |
DOIs | |
State | Published - 22 Jul 2023 |
Keywords
- AI
- Hydrogen
- Machine learning
- Sustainability
- Syngas
- r-SOC