Modelling, simulation, and membrane wetting estimation in gas‐liquid contacting processes

Pantoleontos, G.; Theodoridis, Theodoros; Mavroudi, Maria; Kikkinides, Eustathios S.; Koutsonikolas, D.; Kaldis, S.P.; Pagana, A.E.

doi:10.1002/cjce.22790

Cited by 5 publications

(27 citation statements)

References 101 publications

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“…The authors showed that the computational wetting to match the experimental data decreases with the increase of the fiber-side liquid velocity, which indicates that an inverse relationship may exist between the liquid flow rate and the wetting, as also demonstrated by Pantoleontos et al in a previous study when considering a physical-absorption case. 8 The current study improves upon the previous work by Pantoleontos et al, who presented a CO 2 -in-water physicalabsorption case along with macroscopic mass balance on the shell side, also accounting for process conditions, membrane and fluid properties, and module geometric characteristics. 8 The ubiquitous resistance-in-series approach, as shown in eq 1, is a pertinent prerequisite in the analysis attempting to interpret the underlying wetting phenomena and aspiring to discern any wetting pattern.…”

Section: Introductionsupporting

confidence: 69%

“…CO 2 removal using membrane-based gas absorption and reaction is gaining attention as an alternative to well-established industrial gas-separation and reaction equipment, such as reactive-absorption columns, because of the high mass transfer area (known a priori ) of the membrane modules per unit volume, their modular design, and easy scale-up of the process. − A membrane bundle containing hundreds of fibers is placed within the membrane module with a customizable length, and it may provide a modular solution for easy lab- and pilot-testing with a specific surface area in the range of 1500–7000 m 2 /m 3 compared to 100–800 m 2 /m 3 for conventional devices …”

Section: Introductionmentioning

confidence: 99%

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Modeling, Simulation, and Membrane Wetting Estimation in Gas–Liquid Contacting Processes Including Shell-Side Reaction: Biogas Upgrading Using DEA Solution

Pantoleontos,

Koutsonikolas,

Asimakopoulou

et al. 2024

Ind. Eng. Chem. Res.

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The basic principles of a steady-state mass transfer model and the resistance-in-series film model are assessed with the aid of a series of experiments in a gas–liquid contact membrane mini-module (3 M Liqui-Cel MM-1.7 × 5.5) using an aqueous solution of diethanolamine (DEA) of 0.25 M (mol/L) for biogas upgrading. Experimental data show that CO2 removal may exceed 67% and reach 100% in combination with the highest possible recovery of CH4 when employing biogas flow rates in the range of 2.8 × 10–5 – 3.6 × 10–5 m3/s and solvent flow rates within 0.47 × 10–5 – 0.58 × 10–5 m3/s. For the experimental data set, a correlation has been developed, effectively interpolating CO2 removal with the gas and liquid flow rates. The wetting values calculated are concentrated close to each other for the same liquid flow rate without considerably depending on the gas flow rate, especially when applying the Hikita–Yun (reaction rate–shell-side correlation) compared with the Hikita–Costello pair. Furthermore, the calculated wetting diminishes with increasing liquid flow rate, a result that is consistent with previous modeling attempts and relevant literature indications. The assumption of enhanced mass transfer in the liquid-filled part of the membrane pores due to the reaction is scrutinized, leading to objectionable computational wetting values. It is shown that for a concentration of DEA equal to 0.25 M the Hatta numbers and the enhancement factors are not equal in the whole reaction path; thus, the choice of the shell-side correlation has an appreciable impact on the overall analysis, especially for the determination of the wetting values.

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Section: Introductionsupporting

confidence: 69%

Section: Introductionmentioning

confidence: 99%

Modeling, Simulation, and Membrane Wetting Estimation in Gas–Liquid Contacting Processes Including Shell-Side Reaction: Biogas Upgrading Using DEA Solution

Pantoleontos,

Koutsonikolas,

Asimakopoulou

et al. 2024

Ind. Eng. Chem. Res.

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“…The microstructure parameters of the membrane have a significant influence on the desulfurization effect of the membrane contactor . Meanwhile, there is also no validated accurate model for the simulation of mass transfer behavior in a multichannel membrane contactor; therefore, the design and optimization of membrane contactors are hindered. − …”

Section: Introductionmentioning

confidence: 99%

Investigation of Mass Transfer Characteristics of SO₂ Absorption into NaOH in a Multichannel Ceramic Membrane Contactor

Kong

Gong

Ke³

et al. 2020

Ind. Eng. Chem. Res.

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A ceramic membrane with multichannels generally has a higher specific area and larger throughput compared to that with a single channel, which is beneficial to the industrialization of ceramic membrane contactors for SO 2 absorption. In this work, the mass transfer performance of SO 2 absorption into NaOH solution was investigated at various gas and liquid operating conditions in a membrane contactor packed with a 19-channel hydrophilic membrane. The results showed that increasing the NaOH concentration can offset the effect of membrane thickness. To analyze the mass transfer process, a 3D mass transfer model was developed to simulate the concentration distribution of the components. The simulated SO 2 fluxes were consistent with the experimental results. Additionally, the mass transfer model was applied to optimize the structure of channels in multichannel ceramic membranes. The operational mode of the multichannel ceramic membrane is optimized by blocking some inside channels to reduce the mass transfer resistance.

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“…2D models are typically used for this kind of approaches. They consider the fiber radial direction to describe mass transfer in the different phases and perform a numeric resolution considering a single fiber [20,27,28,[37][38][39][40][41].…”

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confidence: 99%

Experimental and numerical investigation binary mixture mass transfer in a gas – Liquid membrane contactor

Fougerit

Pozzobon

Pareau

et al. 2019

Journal of Membrane Science

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CO2 removal from binary mixture gaseous streams using hollow fibers membrane module under physical absorption (water) has been investigated. The impact of the gas composition on the mass transfer efficiency was experimentally investigated with a CO2/CH4 mixture of varying composition (2 = 10 − 90%), covering a wide range of process: natural gas sweetening (5-10 % CO2), post-combustion carbon capture (10-15 % CO2), for biogas upgrading to biomethane (35-50 % CO2), ... As expected, the absorbed CO2 flux is increasing with the CO2 partial pressure. Yet the absorbed CO2 flow is multiplied by a factor up to 15 between a 10 and a 90 % inlet CO2 molar fraction, while applying a factor 9 to the inlet flow parameters. This underlines the existence of a non-trivial behavior. Highlights-Absorption of a binary gas mixture was modelled in cross-flow HFMMs-CO2 absorption ratio is divided by up to a factor 15 in the presence of CH4-Resistance-in-series has to be adapted to describe HFMM mass transfer-Transition zone equations are implemented without fitted parameter-The model predicts mass transfer over a wide range of gas composition and flow rate

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Modelling, simulation, and membrane wetting estimation in gas‐liquid contacting processes

Cited by 5 publications

References 101 publications

Modeling, Simulation, and Membrane Wetting Estimation in Gas–Liquid Contacting Processes Including Shell-Side Reaction: Biogas Upgrading Using DEA Solution

Modeling, Simulation, and Membrane Wetting Estimation in Gas–Liquid Contacting Processes Including Shell-Side Reaction: Biogas Upgrading Using DEA Solution

Investigation of Mass Transfer Characteristics of SO₂ Absorption into NaOH in a Multichannel Ceramic Membrane Contactor

Experimental and numerical investigation binary mixture mass transfer in a gas – Liquid membrane contactor

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Modelling, simulation, and membrane wetting estimation in gas‐liquid contacting processes

Cited by 5 publications

References 101 publications

Modeling, Simulation, and Membrane Wetting Estimation in Gas–Liquid Contacting Processes Including Shell-Side Reaction: Biogas Upgrading Using DEA Solution

Modeling, Simulation, and Membrane Wetting Estimation in Gas–Liquid Contacting Processes Including Shell-Side Reaction: Biogas Upgrading Using DEA Solution

Investigation of Mass Transfer Characteristics of SO2 Absorption into NaOH in a Multichannel Ceramic Membrane Contactor

Experimental and numerical investigation binary mixture mass transfer in a gas – Liquid membrane contactor

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Investigation of Mass Transfer Characteristics of SO₂ Absorption into NaOH in a Multichannel Ceramic Membrane Contactor