Experimental and thermodynamic modelling of hydrate dissociation conditions for CO2 + propane mixtures

IF 2.8 3区 工程技术 Q3 CHEMISTRY, PHYSICAL
Valderio de Oliveira Cavalcanti Filho , Rod Burgass , Antonin Chapoy
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Abstract

The possibility of hydrate formation poses a central issue for Carbon Capture and Storage (CCS) and Enhanced Oil Recovery with Water-Alternating-Gas (EOR/WAG) injection projects. In most of the cases, however, the available fluid for this purpose consists of a CO2-rich stream containing contaminants such as hydrocarbons and permanent gases. As a result, there is a growing interest in evaluating the effect of small impurities concentrations on the phase behaviour of such streams. This work investigates the impact of propane as a promoter in carbon dioxide hydrate formation, covering a concentration range in the feed gas phase between 10 and 69% on mole basis. The study also considers the Lw-LCO2-H region, taking into account liquid and supercritical transportation commonly encountered in CCS projects. Additionally, a procedure to estimate uncertainties in the graphical determination of the dissociation temperature and pressure is discussed. The thermodynamic modelling approach includes three different modifications of cubic equations of state (CEoS): asymmetric mixing rule, advanced Huron-Vidal mixing rule, and cubic-plus-association approach. An alternative procedure based on setting different sets of CO2 Kihara’s parameters when shifting between structures was also used. While satisfactory average temperature deviations were obtained for those equations of state, maximum deviation between calculated and experimental temperatures spanned from 0.5 to 2.5 K, depending on the thermodynamic model.

二氧化碳+丙烷混合物水合物解离条件的实验和热力学建模
水合物形成的可能性是碳捕集与封存(CCS)和注水采油(EOR/WAG)项目的核心问题。然而,在大多数情况下,可用于此目的的流体由富含二氧化碳的液流组成,其中含有碳氢化合物和永久性气体等污染物。因此,人们越来越有兴趣评估少量杂质浓度对此类液流相态的影响。本研究调查了丙烷作为促进剂对二氧化碳水合物形成的影响,涵盖了原料气相中 10% 至 69% 的摩尔浓度范围。研究还考虑了 Lw-LCO2-H 区域,同时考虑了 CCS 项目中常见的液态和超临界运输。此外,还讨论了一种估算解离温度和压力图形测定中不确定性的程序。热力学建模方法包括对立方状态方程(CEoS)的三种不同修改:非对称混合规则、高级休伦-维达尔混合规则和立方加关联方法。此外,还采用了一种替代程序,即在不同结构之间转换时设置不同的二氧化碳 Kihara 参数集。虽然这些状态方程获得了令人满意的平均温度偏差,但根据热力学模型的不同,计算温度与实验温度之间的最大偏差在 0.5 至 2.5 K 之间。
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来源期刊
Fluid Phase Equilibria
Fluid Phase Equilibria 工程技术-工程:化工
CiteScore
5.30
自引率
15.40%
发文量
223
审稿时长
53 days
期刊介绍: Fluid Phase Equilibria publishes high-quality papers dealing with experimental, theoretical, and applied research related to equilibrium and transport properties of fluids, solids, and interfaces. Subjects of interest include physical/phase and chemical equilibria; equilibrium and nonequilibrium thermophysical properties; fundamental thermodynamic relations; and stability. The systems central to the journal include pure substances and mixtures of organic and inorganic materials, including polymers, biochemicals, and surfactants with sufficient characterization of composition and purity for the results to be reproduced. Alloys are of interest only when thermodynamic studies are included, purely material studies will not be considered. In all cases, authors are expected to provide physical or chemical interpretations of the results. Experimental research can include measurements under all conditions of temperature, pressure, and composition, including critical and supercritical. Measurements are to be associated with systems and conditions of fundamental or applied interest, and may not be only a collection of routine data, such as physical property or solubility measurements at limited pressures and temperatures close to ambient, or surfactant studies focussed strictly on micellisation or micelle structure. Papers reporting common data must be accompanied by new physical insights and/or contemporary or new theory or techniques.
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