Techno-Economic Analysis of Electrochemical Refineries Using Solid Oxide Cells for Oxidative Coupling of Methane

Fabian Rosner, Mike C Tucker, Boxun Hu, Hanna Breunig
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Abstract

With the shift away from fossil resources, there is a need for alternative pathways to carbon-based commodities such as ethylene. The electrochemical oxidative coupling of methane (OCM) enables the synthesis of higher hydrocarbons from simple organic molecules i.e., methane and has the potential to replace conventional ethylene production in the future. However, current solid oxide OCM cell development is still in an early stage and more comprehensive system-level analyses are needed to better understand operating conditions and economics to guide research and development. For this purpose, process models and new integration strategies for the electrochemical OCM process were developed. The integration of the electrochemical OCM unit into the plant revealed to be challenging based on current solid oxide cell designs and will be discussed as part of this presentation. The performance of the OCM plant is benchmarked against current state-of-the-art ethane steam cracker plants. In this context, key performance metrics are efficiency, direct and indirect carbon dioxide emissions, power consumption, plant cost and cost of ethylene. Of particular interest are aspects of hydrogen co-production and carbon dioxide utilization as well as the impact of carbon dioxide emission factors from the grid, which have shown to be of particular importance for electrochemical processes. Moreover, critical aspects of heat integration will be discussed including fuel pre-heating, carbon deposition and thermal cell management. The analysis will provide new insights into economic cost driving factors and the impact of cell cost, current density, overpotentials and Faraday efficiency upon the cost of ethylene. Based upon this information, performance targets will be recommended that will allow electrochemical OCM to become economically competitive in a free market environment.
固体氧化电池用于甲烷氧化偶联的电化学精炼厂技术经济分析
随着对化石资源的依赖逐渐减少,人们需要寻找替代途径来生产乙烯等碳基大宗商品。甲烷的电化学氧化偶联(OCM)可以从简单的有机分子(如甲烷)合成高级碳氢化合物,并有可能在未来取代传统的乙烯生产。然而,目前固体氧化物OCM电池的开发仍处于早期阶段,需要更全面的系统级分析,以更好地了解操作条件和经济性,从而指导研究和开发。为此,提出了电化学OCM工艺模型和新的集成策略。根据目前的固体氧化物电池设计,将电化学OCM单元集成到工厂中是具有挑战性的,这将作为本次演讲的一部分进行讨论。OCM装置的性能以目前最先进的乙烷蒸汽裂解装置为基准。在这种情况下,关键绩效指标是效率、直接和间接二氧化碳排放、电力消耗、工厂成本和乙烯成本。特别令人感兴趣的是氢气联合生产和二氧化碳利用的各个方面,以及电网二氧化碳排放因素的影响,这已显示对电化学过程特别重要。此外,热集成的关键方面将讨论包括燃料预热,碳沉积和热电池管理。该分析将为经济成本驱动因素以及电池成本、电流密度、过电位和法拉第效率对乙烯成本的影响提供新的见解。根据这些信息,将建议性能目标,使电化学OCM在自由市场环境中具有经济竞争力。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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