Autothermal methanol reforming for hydrogen production in fuel cell applications

Geissler, Konrad; Newson, E.; Vogel, Frédéric; Truong, Thanh-Binh; Hottinger, Peter; Wokaun, Alexander

doi:10.1039/b004881j

Cited by 137 publications

(98 citation statements)

References 11 publications

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“…The first reaction mechanism proposed as sequence the formation of H 2 and CO primarily from MD, and then the water-gas shift (WGS) would occur to produce CO 2 and H 2 [28]. Other authors stated later that the correct pathway involves the formation of CO 2 and H 2 through direct MSR, followed by the RWGS reaction [29]. According to the first mechanism, the amount of CO should be equal or higher to the equilibrium of the RWGS reaction and this condition must be verified for the whole temperature range [11,15].…”

Section: Mechanistic Modelsmentioning

confidence: 99%

Low-temperature methanol steam reforming kinetics over a novel CuZrDyAl catalyst

Silva

Mateos-Pedrero

Ribeirinha

et al. 2015

Reac Kinet Mech Cat

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A kinetic study within the low-temperature methanol steam reforming (MSR) reaction range (170 ºC -200 ºC) was performed over a novel CuZrDyAl catalyst. The physicochemical and catalytic properties of the CuZrDyAl catalyst were compared with those of a conventional CuO/ZnO/Al 2 O 3 (G66 MR, Süd-Chemie) sample, taken as reference. The in-house catalyst displays better performances, in terms of methanol conversion and H 2 production, than the reference G66 MR sample.Interestingly, the in-house catalyst is significantly more selective (namely, yielding lower CO concentration) than the commercial one, which gives extra interest for producing fuel cell grade hydrogen. Physicochemical characterization evidences that the in-house catalyst have improved reducibility of copper species compared with the G66-MR, which might account for its better performances.The parameters of a simple power-law equation and two mechanistic kinetic models were determined by non-linear regression, minimizing the sum of the residual squares; the best fitting with the experimental data was obtained when using Model 3, based on the reported work from Peppley et al. [10] for the commercial CuO/ZnO/Al 2 O 3 .This article was published in Reaction Kinetics, Mechanisms and Catalysis, 115(1), 321-339, 2015 http://dx.doi.org/10.1007/s11144-015-0846-z 03-11-2017 2 Noteworthy, is the scarce number of MSR kinetic studies at such lower temperature range.

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Section: Mechanistic Modelsmentioning

confidence: 99%

Low-temperature methanol steam reforming kinetics over a novel CuZrDyAl catalyst

Silva

Mateos-Pedrero

Ribeirinha

et al. 2015

Reac Kinet Mech Cat

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“…Recent papers have discussed the POM reaction [22][23][24], as well as the combined process for production of H 2 [25][26][27][28][29][30][31][32][33][34][35][36][37][38]. The Cu/ZnO/Al 2 O 3 catalyst, which is traditionally used for low-temperature gas-shift and methanol synthesis, has been widely used in these reactions.…”

Section: Introductionmentioning

confidence: 99%

Production of hydrogen from methanol over Cu/ZnO catalysts promoted by ZrO2 and Al2O3

Agrell

Birgersson

Boutonnet

et al. 2003

Journal of Catalysis

366

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“…This efficiency is to be compared with that of a PEM fuel cell operated with hydrogen from an autothermal methanol reformer. Geissler et al found that only 4% of the methanol's energy content is lost during the reforming and gas clean-up process (preferential CO oxidation) [23]. Only about 50% of the hydrogen energy is converted to electrical energy, and about 20% of the generated electric power is used for driving auxiliary equipment (compressors, pumps).…”

Section: Resultsmentioning

confidence: 99%

Novel Options and Limitations of Methanol‐Based Production and Storage for Mobile Applications

et al. 2014

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Methanol is considered a promising liquid fuel in context with electrochemical energy conversion and storage for mobile applications. It is shown here that a direct methanol fuel cell can be used for spontaneous charging and discharging a supercapacitor for intermediate storage of chemical energy. Thereby, protons and electrons of the methanol-derived hydrogen are stored separately in the electrical double layer of the supercapacitor electrode. The charging and discharging of this fuel cell-supercapacitor hybride device is investigated in experiments of spontaneous conditions (closed circuit) and also under externally enforced constant voltage sweep rate (cyclic voltammetry) and under constant current conditions. Alternatively, gas phase hydrogen is generated from methanol in an electroreforming process. When more efficient anode electrocatalysts become available this may become the method of choice for on-board and on demand hydrogen production in mobile applications.

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Autothermal methanol reforming for hydrogen production in fuel cell applications

Cited by 137 publications

References 11 publications

Low-temperature methanol steam reforming kinetics over a novel CuZrDyAl catalyst

Low-temperature methanol steam reforming kinetics over a novel CuZrDyAl catalyst

Production of hydrogen from methanol over Cu/ZnO catalysts promoted by ZrO2 and Al2O3

Novel Options and Limitations of Methanol‐Based Production and Storage for Mobile Applications

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