Development and Application of Carbon Deposition State Diagram for H-C-O Systems
Zhimin Ding, Xiangyang Pan, Yan Zhang, Shuo Wang, Haiyan Zheng, Fengman Shen

TL;DR
This paper introduces a new diagram to predict and prevent carbon deposition in hydrogen production processes, helping reduce costs and improve efficiency.
Contribution
A novel carbon deposition state diagram for H-C-O systems is developed, enabling precise prediction and prevention of carbon deposition.
Findings
Critical carbon deposition point coordinates were determined across various temperatures, pressures, and H2/CO ratios.
The carbon deposition state diagram was validated with experimental and industrial data, showing its practicality.
The diagram provides a theoretical basis for optimizing process parameters to avoid carbon deposition.
Abstract
In both preparing and using hydrogen-rich reducing gas (H2RG) in direct reduction, carbon deposition occurs if operating parameters are improperly controlled, affecting the entire process. Therefore, a universally applicable method is needed to determine carbon deposition in the CH4-H2-CO-H2O-CO2 system, especially the broader H-C-O system. This study establishes a novel method based on the H-C-O system’s mass balance and chemical equilibrium diagram, alongside multi-phase/multi-reaction equilibrium principles. Critical carbon deposition point coordinates (O/C, H/C) were determined under varying conditions including temperatures typically ranging from 550 °C to 900 °C, total pressures from 0.1 to 2.0 MPa, and H2/CO ratios of approximately 2.0–6.9. Connecting points under identical parameters generated critical carbon deposition curves, forming a comprehensive “carbon deposition state…
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Taxonomy
TopicsChemical Looping and Thermochemical Processes · Catalysts for Methane Reforming · Advancements in Solid Oxide Fuel Cells
