以吸附为基础的二氧化碳捕获工艺的操作性与经济性权衡

Steven Sachio, Adam Ward, Ronny Pini, Maria M. Papathanasiou
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引用次数: 0

摘要

可调度的低碳电力是向可持续能源系统过渡的基础,可为间歇性可再生能源电力的整合提供平衡负荷。在这种负载跟随运行中,燃烧后碳捕集工艺必须能够高度瞬态运行。在此,我们开发了一个计算框架,将二氧化碳捕集的压力-真空变速吸附工艺的工艺设计、可操作性和技术经济评估融为一体。我们证明,成本最优设计的工艺灵活性有限,难以对烟气条件的干扰做出反应。可以通过放宽对运行的二氧化碳回收限制来引入灵活性,尽管这要以牺牲工艺的捕获效率为代价。我们发现,基于吸附技术的工艺设计可以提高灵活性,同时在二氧化碳回收和纯度的操作限制方面提高性能。本文的研究结果表明了工艺经济性和工艺可操作性之间的权衡,要将二氧化碳捕集装置整合到低碳能源系统中,就必须合理利用这两者。Papathanasiou & Pini 博士及其同事提出了一种基于模型的方法,用于高效设计基于吸附剂的燃烧后碳捕集。他们量化了操作性与成本之间的权衡,并确定了满足二氧化碳纯度和回收约束条件的合适候选设计。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Operability-economics trade-offs in adsorption-based CO2 capture processes

Operability-economics trade-offs in adsorption-based CO2 capture processes
Dispatchable low-carbon power underpins the transition to a sustainable energy system, providing balancing load for the integration of intermittent renewable power. In such load-following operation, the post-combustion carbon capture process must be capable of highly transient operation. Here we have developed a computational framework that integrates process design, operability and techno-economic assessment of a pressure-vacuum swing adsorption process for CO2 capture. We demonstrate that the cost-optimal design has limited process flexibility, challenging reactiveness to disturbances in the flue gas conditions. Flexibility can be introduced by relaxing the CO2 recovery constraint on the operation, albeit at the expense of the capture efficiency of the process. We discover that adsorption-based processes can be designed to enhance flexibility, while improving performance with respect to the operational constraints on CO2 recovery and purity. The results herein demonstrate a trade-off between process economics and process operability, which must be rationalised to integrate CO2 capture units in low-carbon energy systems. Drs Papathanasiou & Pini, and colleagues present a model-based approach for efficient design of sorbent-based post-combustion carbon capture. They quantify operability-cost trade-offs and identify suitable candidate designs that satisfy CO2 purity and recovery constraints.
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