Catalytic palladium‐based membrane reactors: A review

Shu, Jun; Grandjean, Bernard P. A.; Neste, A. Van; Kaliaguine, Serge

doi:10.1002/cjce.5450690503

Cited by 659 publications

(378 citation statements)

References 109 publications

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“…It is well recognized that membrane reactor (MR) technology is a well-established reality in the production of hydrogen through reforming processes, as an option to the TRs [46,67]. Dense metal membranes can operate at medium pressures and temperatures (for example, for steam reforming and water-gas shift reactions) [68].…”

Section: Pd-based Membranementioning

confidence: 99%

“…Moreover, due to Le Chatelier's principle, the reaction can be shifted towards the reaction products, with a consequent enhancement of the conversion and with the further benefit of collecting high grade hydrogen in the permeate side of the MR. Therefore, dense self-supported Pd-based MRs seem to be more adequate over other technologies to generate PEMFC-grade hydrogen due to the full hydrogen perm-selectivity of the membrane, while, depending on the finite value of the hydrogen perm-selectivity of the composite membrane, the purified hydrogen can be supplied to other kinds of fuel cells or to high temperature PEMFCs, whose CO content can be up to 20,000 ppm [67,[69][70][71][72][73][74][75].…”

Section: Pd-based Membranementioning

confidence: 99%

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Pure Hydrogen Production in Membrane Reactor with Mixed Reforming Reaction by Utilizing Waste Gas: A Case Study

et al. 2016

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A rise in CO2 and other greenhouse gases’ concentration from gas refinery flares and furnaces in the atmosphere causes environmental problems. In this work, a new process was designed to use waste gas (flue gas and flare gas) of a domestic gas refinery to produce pure hydrogen in a membrane reactor. In particular, the process foresees that the energy and CO2 content of flue gas can provide the heat of the mixed reforming reaction to convert flare gas into hydrogen. Furthermore, the characteristics of the feed stream were obtained via simulation. Then, an experimental setup was built up to investigate the performance of a membrane reactor allocating an unsupported dense Pd-Ag membrane at the mentioned conditions. In this regard, a Ni/CeO2 catalyst was loaded in the membrane reformer for mixed reforming reaction, operating at 450 °C, in a pressure range between 100 and 350 kPa and a gas hourly space velocity of around 1000 h−1. The experimental results in terms of methane conversion, hydrogen recovery and yield, as well as products’ compositions are reported. The best results of this work were observed at 350 kPa, where the MR was able to achieve about 64%, 52% and 50% for methane conversion, hydrogen yield and recovery, respectively. Furthermore, with the assistance of the experimental tests, the proposed process was simulated in the scaling up to calculate the needed surface area for MR in the domestic gas refinery.

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Section: Pd-based Membranementioning

confidence: 99%

Section: Pd-based Membranementioning

confidence: 99%

Pure Hydrogen Production in Membrane Reactor with Mixed Reforming Reaction by Utilizing Waste Gas: A Case Study

et al. 2016

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“…For Shu et al . [112] the Pd cost is not the limiting step for the application of Pd-based MRs in several small and medium processes, but considering large plants and the hydrogen economy, the cost of Pd could be a key factor in the development of Pd-based MRs.…”

Section: Dense and Composite Metallic Membranesmentioning

confidence: 99%

The water‐gas shift reaction: from conventional catalytic systems to Pd‐based membrane reactors—a review

Mendes

Madeira

et al. 2009

Asia-Pacific J Chem Eng

192

109

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The water-gas shift (WGS) reaction is a well-known step for upgrading carbon monoxide to hydrogen in the production of synthesis gas. For more than 90 years after its first industrial application, many issues in respect of the catalyst, process configuration, reactor design, reaction mechanisms and kinetics have been investigated. More recently, a renewed interest in the WGS reaction carried out in hydrogen perm-selective membrane reactors (MRs) has been observed because of the growing use of polymeric electrolyte membrane (PEM) fuel cells that operate using high-purity hydrogen. Moreover, MRs are viewed as an interesting technology in order to overcome the equilibrium conversion limitations in traditional reactors.This article reviews the most relevant topics of WGS MR technology -catalysis and membrane science. The most used catalysts and relevant progress achieved so far are described and critically reviewed. The effects of the most important parameters affecting the WGS in MRs are detailed. In addition, an overview on the most used membranes in MRs is also presented and discussed. 

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“…In the last decades, membrane catalysis has been studied by several research and the significant progress in this field is summarized in several review articles (Armor 1998, Lin 2001, Lu 2007, Mcleary 2006, Sanchez 2002, Saracco 1994, Shu 1991.…”

Section: Introductionmentioning

confidence: 99%