Validation of cubic EoS mixing rules and multi-fluid helmholtz energy approximation EoS for the phase behaviour modelling of CO2-rich binary mixtures at low temperatures

IF 2.7 4区 环境科学与生态学 Q3 ENERGY & FUELS
Franklin Okoro, Antonin Chapoy, Pezhman Ahmadi, Rod Burgass
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引用次数: 0

Abstract

The transportation of CO2 from the capture site to the storage location is a crucial phase in carbon capture, utilisation and storage (CCUS) process. For offshore operations, ship transportation is considered a viable alternative, and this would entail operations at low temperatures (down to 223.15 K). A review of the literature revealed that there is limited experimental data on CO2-rich systems at low temperatures, thus, the need to investigate the phase behaviour of CO2-rich systems at these conditions. This study validated and compared the accuracies of Peng–Robinson (PR) equation of state (EoS) with three different mixing rules (the classical with original and adjusted binary interaction parameters, the Wong–Sandler, and the Orbey–Wong–Sandler mixing rules) against the multi-fluid helmholtz energy approximation (MFHEA - with original and adjusted binary-specific reducing parameters) EoS in the prediction of bubble points of CO2-rich binary systems (CO2-CH4, CO2–O2, CO2–Ar, and CO2–N2) for CCUS applications. The experimental studies used for the validation of the models were conducted at low temperatures (228.15–273.15 K with overall uncertainties of 0.14 K) and for five different CO2 mole ratios (99.5, 99, 98.5, 98 and 95% with overall uncertainties of 0.032%) using the constant composition expansion method. The overall uncertainty of the pressure measurements was 0.03 MPa. From the study, it was observed that there was a significant effect of binary interaction parameters (BIP) adjustment on the performance of PR-EoS with classical mixing rule, especially for the CO2–N2 system. For all the systems, the predictions of PR-EoS with the classical mixing rules and the adjusted BIPs were the most accurate in terms of the average absolute deviations from the experimental data. The model also predicted the literature data well in comparison with the other models (with less than 5% deviations for all the data points). Further analysis also proved that the model dew point predictions were in reasonable agreement with the available literature data at the considered conditions. As a result, the model could be adopted to fill the existing knowledge gaps of the studied systems at conditions (143.15–223.15 K) where experimental studies were not feasible. © 2024 The Author(s). Greenhouse Gases: Science and Technology published by Society of Chemical Industry and John Wiley & Sons Ltd.

Abstract Image

用于富含二氧化碳的二元混合物在低温下的相行为建模的三次方程混合规则和多流体舵霍兹能量近似方程的验证
将二氧化碳从捕获地点运输到贮存地点是碳捕获、利用和贮存(CCUS)过程中的一个关键阶段。对于近海作业,船舶运输被认为是一个可行的替代方案,这将需要在低温(低至 223.15 K)条件下作业。文献综述显示,低温下富二氧化碳系统的实验数据有限,因此有必要研究这些条件下富二氧化碳系统的相态。本研究在预测富二氧化碳二元体系(CO2-CH4、CO2-O2、CO2-Ar 和 CO2-N2)的气泡点时,验证并比较了彭-罗宾逊(PR)状态方程(EoS)与多流体舵霍兹能量近似(MFHEA - 具有原始和调整的二元特定还原参数)的三种不同混合规则(具有原始和调整的二元相互作用参数的经典混合规则、Wong-Sandler 混合规则和 Orbey-Wong-Sandler 混合规则)在 CCUS 应用中的准确性。用于验证模型的实验研究是在低温(228.15-273.15 K,总体不确定性为 0.14 K)条件下,采用恒定成分膨胀法对五种不同的二氧化碳摩尔比(99.5、99、98.5、98 和 95%,总体不确定性为 0.032%)进行的。压力测量的总体不确定性为 0.03 兆帕。研究发现,二元相互作用参数(BIP)的调整对采用经典混合规则的 PR-EoS 的性能有显著影响,尤其是在 CO2-N2 系统中。就与实验数据的平均绝对偏差而言,采用经典混合规则和经调整的 BIP 的 PR-EoS 对所有系统的预测都是最准确的。与其他模型相比,该模型还能很好地预测文献数据(所有数据点的偏差均小于 5%)。进一步的分析还证明,在考虑的条件下,该模型的露点预测与现有文献数据相当吻合。因此,在无法进行实验研究的条件下(143.15-223.15 K),该模型可用于填补所研究系统的现有知识空白。© 2024 The Author(s).温室气体:由化学工业协会和 John Wiley & Sons Ltd. 出版。
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来源期刊
Greenhouse Gases: Science and Technology
Greenhouse Gases: Science and Technology ENERGY & FUELS-ENGINEERING, ENVIRONMENTAL
CiteScore
4.90
自引率
4.50%
发文量
55
审稿时长
3 months
期刊介绍: Greenhouse Gases: Science and Technology is a new online-only scientific journal dedicated to the management of greenhouse gases. The journal will focus on methods for carbon capture and storage (CCS), as well as utilization of carbon dioxide (CO2) as a feedstock for fuels and chemicals. GHG will also provide insight into strategies to mitigate emissions of other greenhouse gases. Significant advances will be explored in critical reviews, commentary articles and short communications of broad interest. In addition, the journal will offer analyses of relevant economic and political issues, industry developments and case studies. Greenhouse Gases: Science and Technology is an exciting new online-only journal published as a co-operative venture of the SCI (Society of Chemical Industry) and John Wiley & Sons, Ltd
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