Low-Concentration CO<sub>2</sub> Capture from Natural Gas Power Plants Using a Rotating Packed Bed Reactor

Xie, Chenxia; Dong, Yu-Ning; Zhang, Liang‐Liang; Chu, Guang‐Wen; Luo, Yong; Sun, Baochang; Zeng, Xiaofei; Chen, Jianfeng

doi:10.1021/acs.energyfuels.8b02780

Cited by 17 publications

(6 citation statements)

References 44 publications

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“…Conventional CO 2 chemical absorption processes with packed beds (PB) require excessive packing volume in the CO 2 absorber due to the large mass transfer resistance across the gas–liquid interface . As a process intensification alternative to PB, rotating packed beds (RPB) have been experimentally investigated by many researchers for their use in CO 2 capture with chemical absorption. − Moreover, extensive process simulation efforts for CO 2 capture with RPB have been reported to capture process fundamentals of CO 2 chemical absorption and to predict CO 2 removal efficiency. ,− …”

Section: Introductionmentioning

confidence: 99%

Process Modeling of CO₂ Absorption with Monoethanolamine Aqueous Solutions Using Rotating Packed Beds

Lin

Wong

et al. 2022

Ind. Eng. Chem. Res.

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A first-principle process simulation model is presented for the chemical absorption of carbon dioxide (CO 2 ) with monoethanolamine (MEA) aqueous solutions using rotating packed beds (RPB). Built on a proven rate-based packed bed absorber model, the RPB model rigorously simulates the phase and chemical equilibria at the vapor−liquid interface, the heat and mass transfer across the gas and liquid films, the fast reactions between MEA and CO 2 in the liquid film, and the RPB hydraulics. Estimation of the rate of transfer of mass across the liquid film is central to accurate simulation of the CO 2 absorption process with MEA aqueous solutions. We show that the literature lab-scale RPB data for CO 2 removal efficiency can be satisfactorily correlated by introducing a correction factor for the effective packing surface area predicted by the Onda correlation. Given the validated RPB model, we further show that, among the gas-phase mass transfer coefficient, the liquid-phase mass transfer coefficient, and the reaction rate constant for the reaction between amine and CO 2 , the reaction rate constant is the controlling step with the greatest potential to enhance the CO 2 absorption performance in RPB.

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Section: Introductionmentioning

confidence: 99%

Process Modeling of CO₂ Absorption with Monoethanolamine Aqueous Solutions Using Rotating Packed Beds

Lin

Wong

et al. 2022

Ind. Eng. Chem. Res.

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“…7), generally referred to as HIGEE. This technology uses centrifugal fields to form highly sheared thin films where highly efficient gasliquid mass transfer can occur [34], resulting in equipment volume reduction, improve efficiency [52] and safety owing to its high gas-liquid contact area and compactness. With its intense fluid dynamics and mass transfer, low absorbent concentrations can be used in RPBs to achieve similar performance to that of a large conventional absorber column.…”

Section: Rotating Packed Bed Absorbersmentioning

confidence: 99%

“…Chamchan et al [53] observed that both the RPB and conventional packed bed absorbers demonstrated similar absorption performance and energy consumption in CO 2 capture at pilot scale but the RPB was associated with a 1/3 volume reduction compared to the conventional packed bed. In CC from flue gas with low CO 2 concentration, Xie et al [52] demonstrated the RPB to be capable of achieving a mass transfer coefficient around 2.7x higher than in a packed column, with a corresponding 2.6x reduction in equipment volume. Mass transfer rates are greatly affected by gas-liquid contact area influenced by the packing type used in RPBs, with blades [39] and structured [54].…”

Section: Rotating Packed Bed Absorbersmentioning

confidence: 99%

Process intensification technologies for CO2 capture and conversion – a review

2020

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With the concentration of CO 2 in the atmosphere increasing beyond sustainable limits, much research is currently focused on developing solutions to mitigate this problem. Possible strategies involve sequestering the emitted CO 2 for long-term storage deep underground, and conversion of CO 2 into value-added products. Conventional processes for each of these solutions often have high-capital costs associated and kinetic limitations in different process steps. Additionally, CO 2 is thermodynamically a very stable molecule and difficult to activate. Despite such challenges, a number of methods for CO 2 capture and conversion have been investigated including absorption, photocatalysis, electrochemical and thermochemical methods. Conventional technologies employed in these processes often suffer from low selectivity and conversion, and lack energy efficiency. Therefore, suitable process intensification techniques based on equipment, material and process development strategies can play a key role at enabling the deployment of these processes. In this review paper, the cutting-edge intensification technologies being applied in CO 2 capture and conversion are reported and discussed, with the main focus on the chemical conversion methods.

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“…A rotating packed bed (RPB) is a typical high-gravity device with efficient gas–liquid contact . In an RPB, small liquid elements like films, filaments, and droplets are obtained by the rotary motion of the rotor, which brings on a large gas–liquid interface area and fast surface renewal frequency, and thus significantly enhances mass transfer and mixing . So far, RPB has been applied in CO 2 absorption and wastewater treatment .…”

Section: Introductionmentioning

confidence: 99%

“…22 In an RPB, small liquid elements like films, filaments, and droplets are obtained by the rotary motion of the rotor, which brings on a large gas−liquid interface area and fast surface renewal frequency, and thus significantly enhances mass transfer and mixing. 23 So far, RPB has been applied in CO 2 absorption 24 and wastewater treatment. 25 A rotating zigzag bed (RZB) is an improved high-gravity device with a zigzag channel in the rotor.…”

Section: Introductionmentioning

confidence: 99%

Carbon Dioxide Absorption with an Aqueous Biphasic Absorbent in a Rotating Zigzag Bed

et al. 2022

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This study explored an intensive carbon dioxide (CO2) absorption process with aqueous biphasic absorbents containing diethylethanolamine (DEEA) and diethylenetriamine (DETA) in a rotating zigzag bed (RZB). The effects of the absorbent composition on the phase separation behavior and CO2 absorption performance were investigated. The dependence of the overall gas-phase volumetric mass transfer coefficient (K G a) and CO2 absorption efficiency on operating conditions with the DEEA + DETA solution was examined. Experimental results indicated that over 97% absorbed CO2 was focused on the bottom layer in the rich solution. The 4 mol/L DEEA + 1 mol/L DETA and 3.5 mol/L DEEA + 1.5 mol/L DETA solutions had much less volume of the bottom layer compared to absorbents with other compositions. Moreover, it was found that the lean solution flow rate, rotational speed of RZB, and temperature of lean solution had a positive influence on CO2 absorption. The K G a and CO2 absorption efficiency in the RZB with the 3.5 mol/L DEEA + 1.5 mol/L DETA solution reached 4.82 kmol/kPa m3 h and 98.7%, respectively, demonstrating an obvious advantage in CO2 absorption performance compared to the 5 mol/L monoethanolamine solution. An artificial neural network (ANN) model was established to predict K G a and CO2 absorption efficiency. The predicted data and experimental results were in good agreement with the deviations generally less than 10% for K G a and CO2 absorption efficiency. A comparison with a wetted-wall column revealed that the RZB could achieve higher mass transfer efficiency. In addition, the mechanism of phase separation in the DEEA + DETA solution was analyzed. This study demonstrates that the DEEA + DETA solution could be a viable absorbent for CO2 capture in RZB.

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Low-Concentration CO₂ Capture from Natural Gas Power Plants Using a Rotating Packed Bed Reactor

Cited by 17 publications

References 44 publications

Process Modeling of CO₂ Absorption with Monoethanolamine Aqueous Solutions Using Rotating Packed Beds

Process Modeling of CO₂ Absorption with Monoethanolamine Aqueous Solutions Using Rotating Packed Beds

Process intensification technologies for CO2 capture and conversion – a review

Carbon Dioxide Absorption with an Aqueous Biphasic Absorbent in a Rotating Zigzag Bed

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Low-Concentration CO2 Capture from Natural Gas Power Plants Using a Rotating Packed Bed Reactor

Cited by 17 publications

References 44 publications

Process Modeling of CO2 Absorption with Monoethanolamine Aqueous Solutions Using Rotating Packed Beds

Process Modeling of CO2 Absorption with Monoethanolamine Aqueous Solutions Using Rotating Packed Beds

Process intensification technologies for CO2 capture and conversion – a review

Carbon Dioxide Absorption with an Aqueous Biphasic Absorbent in a Rotating Zigzag Bed

Contact Info

Product

Resources

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Low-Concentration CO₂ Capture from Natural Gas Power Plants Using a Rotating Packed Bed Reactor

Process Modeling of CO₂ Absorption with Monoethanolamine Aqueous Solutions Using Rotating Packed Beds

Process Modeling of CO₂ Absorption with Monoethanolamine Aqueous Solutions Using Rotating Packed Beds