Computational Fluid Dynamics Simulation of a Membrane Contactor for CO<sub>2</sub> Separation: Two Types of Membrane Evaluation

Alborzi, Z.; Amini, Younes; Amirabedi, Parya; Raveshiyan, Saba; Hassanvand, Amin

doi:10.1002/ceat.202300102

Cited by 8 publications

(4 citation statements)

References 107 publications

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“…In various applications, HFMC systems increase separation efficiency because of their functional physical structure, simple gas and fluid flow rate control, and high surface contact area per unit area [18,19]. Due to the good performance of HFMCs in separating CO 2 from various gas and liquid samples, much research has been done in this field in recent years [20]. For example, Nguyen et al used enzymatic CO 2 capture in membrane contactors as a different approach in the category of CO 2 separation by HFMC and acknowledged that it is a green, energy-efficient, nontoxic, and low-cost technology that has promise for industrial applications [21].…”

Section: Introductionmentioning

confidence: 99%

“…Zhao et al used a polyetheretherketone HFM for capturing CO 2 from flue gas, and they discovered that the CO 2 absorption flux of FAS-PDMS-0.6 HFM was raised by 50.9 % compared with the original membrane [22]. This method is also practical for capturing CO 2 from liquid flows, and as an example of the separation of CO 2 from liquids, CO 2 capture from seawater is noteworthy [20].…”

Section: Introductionmentioning

confidence: 99%

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A Comprehensive Parametric Study on CO₂ Removal from Natural Gas by Hollow Fiber Membrane Contactor: A Computational Fluid Dynamics Approach

Bagi,

Razlighi,

Shanbedi

et al. 2024

Chem Eng & Technol

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This study examined essential factors in the use of hollow fiber membranes that affect CO2 removal efficiency. In the simulation, a finite element model for a membrane with ten fibers was used. Each fiber is 175 mm long with inner radius of 0.75 mm and outer radius of 1.5 mm. Liquid and gas flow rates were set at 100–800 mL min−1, and adsorbent concentration was adjusted in the range of 200–1500 mol m−3 for monoethanolamine, piperazine (PZ), and ethylenediamine absorbents. Increasing the liquid flow rate, gas flow rate, and absorbent concentration leads to an increase, decrease, and increase in efficiency, respectively. Thus, using PZ as absorbent with a concentration of 1080 mol m−3 liquid and gas flow rates of 400 and 180 mL min−1, respectively, showed a CO2 removal efficiency of > 95 % for a membrane effective length of 0.3 m.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

A Comprehensive Parametric Study on CO₂ Removal from Natural Gas by Hollow Fiber Membrane Contactor: A Computational Fluid Dynamics Approach

Bagi,

Razlighi,

Shanbedi

et al. 2024

Chem Eng & Technol

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“…The mass transfer theory for porous media is also fundamental to analysing saltwater intrusion problems. Approaches employed in this field include analytical methods [33,34], the boundary element method (BEM) [35], and the FEM [36,37]. The FEM cannot reach the accuracy of analytical solutions or the BEM, but it offers the widest application.…”

Section: Introductionmentioning

confidence: 99%

“…The FEM cannot reach the accuracy of analytical solutions or the BEM, but it offers the widest application. COMSOL Multiphysics [38] is one of the finite-element modelling packages that is widely utilized for solving various partial differential equations in engineering fields [21,36,37]. It features high flexibility in combining different physics as required in complex problems like saltwater intrusion.…”

Section: Introductionmentioning

confidence: 99%

Comparing Darcy’s Law and the Brinkman Equation for Numerical Simulations of Saltwater Intrusion

Yao,

Zhang

2023

Sustainability

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Saltwater intrusion into coastal aquifers presents a significant global challenge to fresh groundwater resources. Numerical modelling represents a valuable tool to study this phenomenon. Darcy’s Law is widely applied to groundwater studies and is extended into the Brinkman Equation to account for kinetic dissipations due to viscous shear. However, their comparative performance and accuracy in density-driven flows remain unclear. To determine the circumstances where the Brinkman Equation is required, numerical simulations with both models were implemented in hypothetical coastal aquifer scenarios. The results revealed that the largest discrepancies between the two models occur inside the dispersion zone during the break-through period, with concentration differences of up to 2.5%. The mixing of freshwater and saltwater induces rapid density and velocity variations. Brinkman’s viscous term moderates the rate of change and decreases the intrusion length by up to 6.1 m in a 180 m intrusion case. Furthermore, higher permeability and a lower recharge rate both strengthen the viscous effects in most sandy coastal aquifers. The Brinkman Equation excels at capturing intricate flow patterns with large variations. Therefore, it is necessary to be employed for studies on freshwater–saltwater interfaces and other similar conditions including groundwater–surface water interfaces, non-isothermal flows, and complex geological conditions.

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Optimizing CO₂ Purification in a Negative CO₂ Emission Power Plant

Amiri,

Mikielewicz,

Ziółkowski

et al. 2024

Chem Eng & Technol

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In the pursuit of mitigating CO2 emissions, this study investigates the optimization of CO2 purification within a negative CO2 emission power plant using a spray ejector condenser (SEC) coupled with a separator. The approach involves direct‐contact condensation of vapor, primarily composed of an inert gas (CO2), facilitated by a subcooled liquid spray. A comprehensive analysis is presented, employing a numerical model to simulate a cyclone separator under various SEC outlet conditions. Methodologically, the simulation, conducted in Fluent, encompasses three‐dimensional, transient, and turbulent characteristics using the Reynolds stress model turbulent model and mixture model to replicate the turbulent two‐phase flow within a gas–liquid separator. Structural considerations are delved into, evaluating the efficacy of single‐ and dual‐inlet separators to enhance CO2 purification efficiency. The study reveals significant insights into the optimization process, highlighting a notable enhancement in separation efficiency within the dual‐inlet cyclone, compared to its single inlet counterpart. Specifically, a 90.7 % separation efficiency is observed in the former, characterized by symmetrical flow patterns devoid of wavering CO2 cores, whereas the latter exhibits less desirable velocity vectors. Furthermore, the investigation explores the influence of key parameters, such as liquid volume fraction (LVF) and water droplet diameter, on separation efficiency. It is ascertained that a 10 % LVF with a water droplet diameter of 10 µm yields the highest separation efficiency at 90.7 %, whereas a 20 % LVF with a water droplet diameter of 1 µm results in a reduced efficiency of 50.79 %. Moreover, the impact of structural modifications, such as the addition of vanes, on separation efficiency and pressure drop is explored. Remarkably, the incorporation of vanes leads to a 9.2 % improvement in separation efficiency and a 16.8 % reduction in pressure drop at a 10 % LVF. The findings underscore the significance of structural considerations and parameter optimization in advancing CO2 capture technologies, with implications for sustainable energy production and environmental conservation.

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Computational Fluid Dynamics Simulation of a Membrane Contactor for CO₂ Separation: Two Types of Membrane Evaluation

Cited by 8 publications

References 107 publications

A Comprehensive Parametric Study on CO₂ Removal from Natural Gas by Hollow Fiber Membrane Contactor: A Computational Fluid Dynamics Approach

A Comprehensive Parametric Study on CO₂ Removal from Natural Gas by Hollow Fiber Membrane Contactor: A Computational Fluid Dynamics Approach

Comparing Darcy’s Law and the Brinkman Equation for Numerical Simulations of Saltwater Intrusion

Optimizing CO₂ Purification in a Negative CO₂ Emission Power Plant

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Computational Fluid Dynamics Simulation of a Membrane Contactor for CO2 Separation: Two Types of Membrane Evaluation

Cited by 8 publications

References 107 publications

A Comprehensive Parametric Study on CO2 Removal from Natural Gas by Hollow Fiber Membrane Contactor: A Computational Fluid Dynamics Approach

A Comprehensive Parametric Study on CO2 Removal from Natural Gas by Hollow Fiber Membrane Contactor: A Computational Fluid Dynamics Approach

Comparing Darcy’s Law and the Brinkman Equation for Numerical Simulations of Saltwater Intrusion

Optimizing CO2 Purification in a Negative CO2 Emission Power Plant

Contact Info

Product

Resources

About

Computational Fluid Dynamics Simulation of a Membrane Contactor for CO₂ Separation: Two Types of Membrane Evaluation

A Comprehensive Parametric Study on CO₂ Removal from Natural Gas by Hollow Fiber Membrane Contactor: A Computational Fluid Dynamics Approach

A Comprehensive Parametric Study on CO₂ Removal from Natural Gas by Hollow Fiber Membrane Contactor: A Computational Fluid Dynamics Approach

Optimizing CO₂ Purification in a Negative CO₂ Emission Power Plant