2012
DOI: 10.1016/j.cej.2012.07.013
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Development of pilot WGS/multi-layer membrane for CO 2 capture

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Cited by 20 publications
(7 citation statements)
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“…In turn, the equilibria of eqs – were shifted toward the products side, and a high purity of H 2 could be derived directly at the permeation side . Membrane reactors have been extensively employed in steam reforming of natural gas or higher hydrocarbons, water shift reaction, , dry reforming of methane, and so forth. A sorption-enhanced reactor where in situ adsorption of CO 2 was integrated with reforming reactions was another available technology to shift the reforming reactions toward the hydrogen side. Sorption enhanced steam reforming of COG (SE-SRCOG) has been demonstrated to be able to achieve 4.0-fold H 2 amount amplification at 550–650 °C. A more compact and efficient technique was the membrane-assisted sorption-enhanced steam reforming method (MA-SE-SR), which incorporated sorbents into a membrane reactor, so an extra-high-purity hydrogen stream could be directly obtained, and CO 2 could also be easily enriched by the cyclic reforming/calcination process.…”
Section: Introductionmentioning
confidence: 99%
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“…In turn, the equilibria of eqs – were shifted toward the products side, and a high purity of H 2 could be derived directly at the permeation side . Membrane reactors have been extensively employed in steam reforming of natural gas or higher hydrocarbons, water shift reaction, , dry reforming of methane, and so forth. A sorption-enhanced reactor where in situ adsorption of CO 2 was integrated with reforming reactions was another available technology to shift the reforming reactions toward the hydrogen side. Sorption enhanced steam reforming of COG (SE-SRCOG) has been demonstrated to be able to achieve 4.0-fold H 2 amount amplification at 550–650 °C. A more compact and efficient technique was the membrane-assisted sorption-enhanced steam reforming method (MA-SE-SR), which incorporated sorbents into a membrane reactor, so an extra-high-purity hydrogen stream could be directly obtained, and CO 2 could also be easily enriched by the cyclic reforming/calcination process.…”
Section: Introductionmentioning
confidence: 99%
“…In turn, the equilibria of eqs 1−3 were shifted toward the products side, and a high purity of H 2 could be derived directly at the permeation side. 22 Membrane reactors have been extensively employed in steam reforming of natural gas 23−26 or higher hydrocarbons, 27−29 water shift reaction, 30,31 dry reforming of methane, 32 and so forth. A sorption-enhanced reactor where in situ adsorption of CO 2 was integrated with reforming reactions was another available technology to shift the reforming reactions toward the hydrogen side.…”
Section: ■ Introductionmentioning
confidence: 99%
“…To shift the steam reforming reaction toward the products side and achieve high conversion of feedstocks at mild operating temperatures, different enhancing technologies were developed. The sorption-enhanced reforming method, which used the proper high-temperature sorbent to capture CO 2 in situ during steam reforming, can achieve high H 2 production and fuel conversion at mild temperature and lower steam/carbon ratio. Another available technology is the membrane-assisted reforming method, which uses a selective dense metal membrane, usually palladium-based membranes, to separate H 2 from the reactive bed during the reforming process. To avoid damage of the membrane, the membrane reactor was mostly operated under a temperature < 600 °C. , To achieve a more compact and efficient reforming system, a novel technique has been proposed such as membrane-assisted sorption-enhanced steam reforming (MA-SE-SR), which combined membrane separation and in situ CO 2 sorption into single units. MA-SE-SR exhibits advantages including the following. (i) The conversion of reactants and selectivity to hydrogen was expected to be further promoted by the synergetic enhancements of CO 2 adsorption and H 2 separation.…”
Section: Introductionmentioning
confidence: 99%
“…Steam and some corrosive gases are included, such as H 2 S. Therefore, high thermal, mechanical and chemical stability of the membranes are required for the WGS membrane reactors. To date, several types of inorganic membranes, such as Pd and Pd-based alloy membranes [9][10][11][12][13], silica membranes [14][15][16], and zeolite membranes [17][18][19][20][21], have been studied as WGS membrane reactors for H 2 production.…”
Section: Introductionmentioning
confidence: 99%
“…al. [10] developed a pilot-scale WGS reactor (1 Nm 3 •h -1 feed gas) using Pd-Cu membranes. The CO 2 concentration of retentate flow reached 80 vol.% and the H 2 concentration of permeate flow was over 99 vol.%.…”
Section: Introductionmentioning
confidence: 99%