碳酸钠溶液中的二氧化碳捕获:传质动力学和 DTAC 表面活性剂的增强机制

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引用次数: 0

摘要

碳酸钠溶剂吸收剂因其绿色环保、成本低廉、无腐蚀性等优点,已被广泛研究用于减少二氧化碳排放,以应对全球变暖问题。然而,在将碳酸钠作为吸收剂用于二氧化碳捕集的过程中,对其传质过程还没有统一的认知,导致对工业化大规模工艺缺乏指导。此外,表面活性剂的传质增强机理能有效改善传质性能,但文献中并未对其进行有效探讨。基于此,本文首先采用分子动力学方法分析了表面活性剂加入后的溶液特性,并对表面活性剂进行了优化。随后,采用经典的溶解氧测试方法,测量碳酸钠溶液吸收二氧化碳时的气液传质系数。根据这种传质系数测量方法,分析了加入表面活性剂的碳酸钠溶液的传质过程。结果表明,在 30 °C 下,浓度为 5 wt% 和 10 wt% 的碳酸钠溶液不满足伪一阶快速化学反应动力学假设。为了提高二氧化碳的吸收传质速率,引入了十二烷基三甲基氯化铵(DTAC)表面活性剂,在 5 wt%浓度溶液中,与未增强溶剂相比,传质速率提高了 119%,满足了假一阶快速化学反应假设。引入表面活性剂后,屏障效应降低了液相传质系数,但在 5 wt%浓度的碳酸钠溶液中出现了马兰戈尼效应,提高了液相传质系数。这一发现揭示了表面活性剂 DTAC 促进碳酸钠传质的机理,对于引入表面活性剂后在脱碳领域的应用具有重要的工程意义。
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Carbon dioxide capture in sodium carbonate solution: Mass transfer kinetics and DTAC surfactant enhancement mechanism

Sodium carbonate solvent absorbent has been widely studied for CO2 reduction to deal with global warming because of its green, low cost, and non-corrosive advantages. However, in the application of sodium carbonate as an absorbent for CO2 capture, there is no unified cognition of the mass transfer process, which leads to the lack of guidance for the industrial large-scale process. Moreover, the mechanism of mass transfer enhancement of surfactants, which can effectively improve the mass transfer performance, has not been effectively explored in the literature. Based on this, this paper firstly adopts the molecular dynamics method to analyze the solution characteristics after surfactant addition and optimize the surfactant. Subsequently, a classical dissolved oxygen test method was used to measure the gas-liquid mass transfer coefficient for CO2 absorption into sodium carbonate solution. And based on this mass transfer coefficient measurement method, the mass transfer process of sodium carbonate solution with surfactant was analyzed. The results showed that the sodium carbonate solution with 5 wt% concentration and 10 wt% concentration at 30 °C did not satisfy the pseudo first-order fast chemical reaction kinetics assumption. To improve CO2 absorption mass transfer rate, dodecyl trimethyl ammonium chloride (DTAC) surfactant was introduced, which was improved by 119 % compared with non-enhanced solvent at 5 wt% concentration solution, and the assumption of pseudo first order fast chemical reaction was satisfied. After the introduction of surfactant, the barrier effect decreased the liquid phase mass transfer coefficient, but the Marangoni effect happened in the 5 wt% concentration of sodium carbonate solution, which enhanced the liquid-phase mass-transfer coefficient. This finding reveals the mechanism of mass transfer promotion of sodium carbonate by the surfactant DTAC, which is of great engineering significance for the application in the field of decarbonization after the introduction of surfactant.

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