Mitigating phase changes in the gas-phase that disrupt CO2 capture in membrane contactors: CO2-NH3-H2O as a model ternary system

IF 4.9 Q1 ENGINEERING, CHEMICAL
B.A. Luqmani , V. Nayak , A. Brookes , A. Moore , P. Vale , M. Pidou , E.J. McAdam
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Abstract

Solid and liquid products can form in the gas phase of membrane contactors applied to reactive ternary systems for CO2 absorption, which poses a critical barrier for carbon capture applications. The mechanism initiating these unwanted phase changes in the gas phase is unclear. This study therefore systematically characterises CO2 absorption in distinct regions of the vapour-liquid equilibrium (VLE) within an illustrative ternary system (CO2-NH3-H2O), to provide an explanation for the formation and mitigation of these solid and liquid products in the gas-phase. Unstable CO2 absorption and increased pressure drop indicated product formation within the gas-phase, which occurred at high CO2 capture ratios. Temporal analysis of gas-phase composition enabled gas-phase products to be related to the relative ternary composition. This was subsequently correlated to distinct regions of the VLE. Consequently, mitigation strategies can be developed with recognition for where products are least likely to form. Pressurisation was proposed to modify the relative gas-phase ammonia composition to reposition conditions within the VLE. The commensurate increase of CO2 into the solvent shifts the ammonia-ammonium equilibrium towards ammonium to indirectly reduce vapour pressure. This synergistic strategy allows sustained operation of membrane contactors for CO2 separation within reactive ternary systems which are critical to delivering carbon capture economically at scale.

Abstract Image

缓解气相中破坏膜接触器二氧化碳捕集的相变:以 CO2-NH3-H2O 为模型的三元系统
应用于二氧化碳吸收反应三元系统的膜接触器的气相中会形成固态和液态产物,这对碳捕集应用构成了关键障碍。引发气相中这些不必要相变的机制尚不清楚。因此,本研究系统地描述了一个示例性三元系统(CO2-NH3-H2O)中气液平衡(VLE)不同区域的二氧化碳吸收情况,为气相中这些固态和液态产物的形成和缓解提供了解释。不稳定的二氧化碳吸收和增大的压降表明气相中产物的形成,这发生在高二氧化碳捕集比的情况下。通过对气相成分进行时间分析,可以将气相产物与相对三元成分联系起来。这随后与 VLE 的不同区域相关联。因此,在制定减排策略时,可以考虑在最不可能形成产物的区域。建议通过加压来改变气相氨的相对组成,以重新定位 VLE 内的条件。溶剂中二氧化碳的相应增加会使氨-铵平衡向铵方向移动,从而间接降低蒸汽压力。这种协同策略可使膜接触器在反应性三元系统中持续运行,以分离二氧化碳,这对大规模经济地进行碳捕获至关重要。
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