Review and selection criteria of classical thermodynamic models for acid gas absorption in aqueous alkanolamines

Suleman, Humbul; Maulud, Abdulhalim Shah; Man, Zakaria

doi:10.1515/revce-2015-0030

Cited by 64 publications

(36 citation statements)

References 88 publications

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“…Being computationally simple, this model has been preferably and broadly used by previous researchers with good correlation of their experimental data [7,25,29]. Usually, all the nonidealities of the process system are combined in a single/dual correction parameter(s) of the model, that is a function of amine concentration, carbon dioxide loadings, and/or pressure [33], yielding a good relationship between the model's results and the experimental data. Hence, a study on the modeling of CO 2 solubility using the Kent and Eisenberg approach appears desirable.…”

Section: Introductionmentioning

confidence: 99%

VLE of Carbon Dioxide-Loaded Aqueous Potassium Salt of L-Histidine Solutions as a Green Solvent for Carbon Dioxide Capture: Experimental Data and Modelling

Syalsabila

Maulud

Suleman³

et al. 2019

International Journal of Chemical Engineering

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In this study, vapour-liquid equilibrium of CO2-loaded aqueous potassium salt of L-histidine was studied for a wide range of temperature (313.15–353.15 K), pressure (150–4000 kPa), and solvent concentrations (1–2.5 molar). The experimental results show that L-histidine has an excellent absorptive capacity for carbon dioxide. When compared to conventional solvent (monoethanolamine) and amino acid salt (potassium L-lysinate) at similar process conditions, L-histidine has superior absorption capacity. Moreover, modified Kent–Eisenberg model was used to correlate the VLE of the studied system with excellent agreement between the model and experimental values. The model exhibited an AARE% of 7.87%, which shows that it can satisfactorily predict carbon dioxide solubilities in aqueous potassium salt of L-histidine at other process conditions. Being a biological component in origin, almost negligibly volatile, and highly resistant to oxidative degradation, L-histidine offers certain operational advantages over other solvents used and has a promising potential for carbon dioxide capture.

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Section: Introductionmentioning

confidence: 99%

VLE of Carbon Dioxide-Loaded Aqueous Potassium Salt of L-Histidine Solutions as a Green Solvent for Carbon Dioxide Capture: Experimental Data and Modelling

Syalsabila

Maulud

Suleman³

et al. 2019

International Journal of Chemical Engineering

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“…It is necessary to determine the concentrations of the various dissolved molecular and ionic species which are in equilibrium. Humbul et al presented an extensive review on available thermodynamic models and their selection using alkanolamines in treatment of NG. However, in this article, equilibrium models relating to separation of acid/sour gas components from NG are discussed to show the state‐of‐art application of thermodynamic properties of different solvents in the separation system (absorber).…”

Section: Process Modelingmentioning

confidence: 99%

Mathematical Modeling, Parametric Estimation, and Operational Control for Natural Gas Sweetening Processes

Selvan

Panda

2017

ChemBioEng Reviews

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As a result of the increased energy demand and the required environmental compliance, purification of natural gas (NG) need to be processed through more efficient technologies. Most the NG sources contain H2S and CO2 as acidic contaminants causing corrosion, reduction in the calorific value of the fuel, and toxicity. Removal of these gases (gas sweetening) is mostly performed in a reactive absorber followed by a stripper for solvents regeneration. Amine solvents are very suitable due to their natural affinity towards the acid gases. In the setting‐up of newer plants or retrofitting of old units in existing plants to improve the efficiency of the sweetening process, modeling, optimization, and safer operational control of the process have drawn the attention of many researchers. The development of better models must take into account the synthesis and implementation of proper control strategies. Rate‐based, equilibrium, and kinetic models supported by thermodynamic properties of the components have been discussed here and experiments carried out to identify new process models have also been presented.

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“…Chunxi and Fürst [38] developed a rigorous electrolyte equation of state model to describe the vapor liquid equilibria of hydrogen sulfide loaded aqueous alkanolamines. Several modifications and improvements of these models have been developed and reviewed in detail, elsewhere [5,39].…”

Section: Introductionmentioning

confidence: 99%

A simple model for estimating hydrogen sulfide solubility in aqueous alkanolamines in the high pressure-high gas loading region

Suleman

Thomsen

Fosbøl

et al. 2021

Journal of Sulfur Chemistry

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Review and selection criteria of classical thermodynamic models for acid gas absorption in aqueous alkanolamines

Cited by 64 publications

References 88 publications

VLE of Carbon Dioxide-Loaded Aqueous Potassium Salt of L-Histidine Solutions as a Green Solvent for Carbon Dioxide Capture: Experimental Data and Modelling

VLE of Carbon Dioxide-Loaded Aqueous Potassium Salt of L-Histidine Solutions as a Green Solvent for Carbon Dioxide Capture: Experimental Data and Modelling

Mathematical Modeling, Parametric Estimation, and Operational Control for Natural Gas Sweetening Processes

A simple model for estimating hydrogen sulfide solubility in aqueous alkanolamines in the high pressure-high gas loading region

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