Development of membrane reactor technology for power production with pre-combustion CO2 capture

Dijkstra, J.W.; Pieterse, J.A.Z.; Li, Hui; Boon, Jurriaan; Delft, Y.C. van; Raju, Gunabalan; Peppink, G.; Brink, R.W. van den; Jansen, D.

doi:10.1016/j.egypro.2011.01.110

Cited by 39 publications

(8 citation statements)

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“…For CO 2 capture, gas membranes separation technology has many inherent advantages such as energy efficiently, environmental friendly, easy scale-up and operation, which has great potentials to overcome the drawbacks of MEA-based systems . During the last few decades, a few studies have been reported about the analysis of the membrane technology for CO 2 capture from the viewpoints of industrial application and process design. − Merkel et al designed a process for CO 2 capture from postcombustion coal-derived flue gas with membranes, and studied the influences of process configurations and membranes parameters on the capture cost and energy consumption, which showed promise for meeting the U.S. Department of Energy (DOE) CO 2 capture cost targets. Zhang et al developed a systematic method to evaluate a postcombustion CO 2 capture with membranes systems including process simulation, capture cost and exergy analysis, which points out that the increase of CO 2 permeability can reduce the required membranes area, resulting in the decrease of the capture cost.…”

Section: Scale-up and Process Design For Co2 Separationmentioning

confidence: 99%

Ionic-Liquid-Based CO₂ Capture Systems: Structure, Interaction and Process

et al. 2017

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The inherent structure tunability, good affinity with CO, and nonvolatility of ionic liquids (ILs) drive their exploration and exploitation in CO separation field, and has attracted remarkable interest from both industries and academia. The aim of this Review is to give a detailed overview on the recent advances on IL-based materials, including pure ILs, IL-based solvents, and IL-based membranes for CO capture and separation from the viewpoint of molecule to engineering. The effects of anions, cations and functional groups on CO solubility and selectivity of ILs, as well as the studies on degradability of ILs are reviewed, and the recent developments on functionalized ILs, IL-based solvents, and IL-based membranes are also discussed. CO separation mechanism with IL-based solvents and IL-based membranes are explained by combining molecular simulation and experimental characterization. Taking into consideration of the applications and industrialization, the recent achievements and developments on the transport properties of IL fluids and the process design of IL-based processes are highlighted. Finally, the future research challenges and perspectives of the commercialization of CO capture and separation with IL-based materials are posed.

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Section: Scale-up and Process Design For Co2 Separationmentioning

confidence: 99%

Ionic-Liquid-Based CO₂ Capture Systems: Structure, Interaction and Process

et al. 2017

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Section: Precombustion Capturementioning

confidence: 99%

110th Anniversary: Process Developments in Carbon Dioxide Capture Using Membrane Technology

Kentish

2019

Ind. Eng. Chem. Res.

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Carbon capture and storage has declined in prominence as a large scale response to climate change, but carbon dioxide capture will remain important into the future for the hydrogen economy, for steel and cement, as well as chemical production. Membrane technology can be a significant component of this industry if cost competitive. While most scientific research is focussed on developing novel materials for this application, it is the process design of the membrane operations that is much more critical in reducing these costs. In post combustion capture, this involves optimisation of the pressure driving force across the membrane, either through feed compression or permeate vacuum pumping, integration of downstream cryogenic purification and the use of combustion air sweeps. In pre-combustion capture, integration of the membrane into the water gas shift reactor is key. Membrane contactors can also play a role, but must be carefully engineered to ensure pressure drop control and to minimise capillary condensation of water.

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“…An advanced technology with the potential of efficiency and cost improvements is the use of hydrogen selective membranes [3].…”

Section: Introductionmentioning

confidence: 99%