Redox Behavior of a Copper‐Based Methanol Reformer for Fuel Cell Applications

Słowik, Grzegorz; Avgouropoulos, George

doi:10.1002/ente.201700883

Cited by 12 publications

(13 citation statements)

References 70 publications

(135 reference statements)

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“…The used catalyst is commercial CuZnAlOx catalyst (HiFuel R120). For practical applications, long‐term stability test of the optimal reformer was carried out under continuous methanol feed at 473 K. It can be seen from Figure that the reformer was quite stable and less than 10% decline in methanol conversion was observed during the 100 hours period, which is similar to the results reported by Joan Papavasiliou et al According to their research, the highly active CuZnAlOx catalyst (HiFuel R120) shows high tolerance under repeated on/off cycles. So the optimized reformer is promising to be integrated into an IRMFC single cell for portable, mobile, and off‐grid applications.…”

Section: Resultssupporting

confidence: 81%

Performance enhancement by optimizing the reformer for an internal reforming methanol fuel cell

Yang

et al. 2019

Energy Science & Engineering

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Internal reforming methanol fuel cell (IRMFC) has potential applications in portable or stationary power supply system, but currently performance of the IRMFC is limited by the low hydrogen production of its reformer. In order to produce more hydrogen with less volume, in this paper a single channel serpentine packed bed reformer was designed, and its bed size was optimized by experiment and numerical simulation to enhance heat transfer and increase catalyst utilization. It was found that with the bed diameter from 5.8 mm down to 3.8 mm, the reformer temperature distribution was more uniform but the bed pressure drop increased a lot. Considering performance and pressure drop, the reformer of 5 mm was optimal, per milliliters of which could supply 9.8 mL/min hydrogen at 453 K, almost twice as much as that by A. Mendes et al with one‐third of their catalyst loading. The reformer was quite stable, and less than 10% decline in methanol conversion was observed during the 100 hours period at 473 K. When incorporated into an IRMFC single cell, power density of the single cell reached 0.45‐0.55 W/cm2 at 453‐473 K under CH3OH solution and air feed, the highest in existing reports. The main drawback has to do with low stability of the IRMFC single cell at high current density.

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Section: Resultssupporting

confidence: 81%

Performance enhancement by optimizing the reformer for an internal reforming methanol fuel cell

Yang

et al. 2019

Energy Science & Engineering

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“…[47][48][49][50][51] Recently, we have demonstrated that this objective can be also achieved via in-situ electrochemical pumping of H 2 in an internal reforming methanol fuel cell, where at atmospheric pressure and low temperatures in the range of 200-210°C, the equilibrium methanol conversion is close to 100 %. [22,27,31,[52][53][54] In addition to that, inhibition of the reaction rate by the produced carbon monoxide is minimized since its concentration is well below the WGS equilibrium and follows secondary pathways, however all the kinetic reports on SRM process do not contain a relative parameter in the proposed equations.…”

Section: Introductionmentioning

confidence: 99%

Investigation of the Inhibiting Role of Hydrogen in the Steam Reforming of Methanol

et al. 2019

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Steam reforming of methanol (SRM) was investigated over palladium zinc oxide catalyst modified with chromium, copper supported on alumina modified manganese oxide and commercial copper catalyst supported on zinc oxide modified with alumina. These catalysts showed high activity and selectivity towards hydrogen and carbon dioxide at low reaction temperatures. Temperature‐programmed desorption, diffuse reflectance infrared Fourier‐transform spectroscopy and catalytic performance studies, indicated that the presence of hydrogen in the gas stream influenced the course of SRM reaction. Such effects were related to hydrogen concentration over the catalysts, the reaction temperature and also the type of catalyst. Semi‐kinetic catalytic studies evidenced that an increase in hydrogen concentration in gas stream led to the decrease of methanol conversion at low‐reaction temperatures and decrease of selectivity to CO2 at high reaction temperatures. It was pointed out that strong interactions of hydrogen with the surface of catalysts may retard transformation of surface species into the SRM products.

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“…Moreover, this type of fuel cell can also tolerate high concentrations of CO, as high as 2 vol.%, in the reformed hydrogen-rich gas stream, thus making the methanol fuel processor more simple and lighter in weight and volume, since both WGS and PROX catalytic reactors and the accompanied heat exchangers and other peripherals will not be necessary [1,2]. Recently, Avgouropoulos et al [1][2][3][4][5] demonstrated the functionality of an Internal Reforming Methanol Fuel Cell (IRMFC), where the methanol gets reformed by a Cu-based catalyst incorporated into the anode compartment of HT-PEMFC. This option offers more room for simplification of the design and control of a compact power unit, which will be very attractive for portable and off-grid applications.…”

Section: Introductionmentioning

confidence: 99%

“…Steam Reforming of Methanol (SRM) is an endothermic catalytic process that provides at relatively low temperatures (<250 • C) and ambient pressure, a hydrogen-rich gas stream (hydrogen up 75%) with low CO concentration (usually around 1-2%; mainly produced via methanol decomposition or/and reverse-WGS, thus diminishing hydrogen selectivity of SRM process) [6][7][8][9] exchangers and other peripherals will not be necessary [1,2]. Recently, Avgouropoulos et al [1][2][3][4][5] demonstrated the functionality of an Internal Reforming Methanol Fuel Cell (IRMFC), where the methanol gets reformed by a Cu-based catalyst incorporated into the anode compartment of HT-PEMFC. This option offers more room for simplification of the design and control of a compact power unit, which will be very attractive for portable and off-grid applications.…”

Section: Introductionmentioning

confidence: 99%

“…Therefore, highly efficient methanol reforming catalysts should be developed, matching the operation level of IRMFC (i.e., 200-220 • C). Towards this aim the research community employs new chemical synthesis methods for the preparation of nanostructured catalysts with high selectivity, extremely high activity, low energy demands and long-life time [4,5,[10][11][12]. These properties can be achieved only by controlling the size, the shape, the particle size distribution, the composition and the electronic structure of the surface, the thermal and chemical stability of the specific nanocomponents.…”

Section: Introductionmentioning

confidence: 99%

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Steam Reforming of Methanol over Nanostructured Pt/TiO2 and Pt/CeO2 Catalysts for Fuel Cell Applications

et al. 2018

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A research and technological challenge for fuel processors integrated with High Temperature Polymer Electrolyte Membrane Fuel Cells (HT-PEMFCs), also known as Internal Reforming Methanol Fuel Cells (IRMFCs), operating at 200–220 °C, is the development of highly efficient catalysts, which will be able to selectively (low CO and other by-products formation) produce the required quantity of hydrogen at these temperatures. In this work, various amounts of platinum were dispersed via deposition-precipitation (DP) and impregnation (I) methods onto the surface of hydrothermally prepared ceria nanorods (CNRs) and titania nanotubes (TNTs). These nanostructured catalysts were evaluated in steam reforming of methanol process targeting the operation level of IRMFCs. The (DP) method resulted in highly (atomically) dispersed platinum-based catalysts, as confirmed with Scanning Transmission Electron Microscopy (STEM) analysis, with a mean particle size of less than 1 nm in the case of 0.35 wt.% Pt/CNRs catalyst. Ultra-fine dispersion of platinum species correlated with the presence of oxygen vacancies, together with the enrichment of CNRs surface with active metallic phase resulted in a highly active catalyst achieving at 220 °C a hydrogen production rate of 5500 cm3 min−1 per g of loaded platinum.

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Redox Behavior of a Copper‐Based Methanol Reformer for Fuel Cell Applications

Cited by 12 publications

References 70 publications

Performance enhancement by optimizing the reformer for an internal reforming methanol fuel cell

Performance enhancement by optimizing the reformer for an internal reforming methanol fuel cell

Investigation of the Inhibiting Role of Hydrogen in the Steam Reforming of Methanol

Steam Reforming of Methanol over Nanostructured Pt/TiO2 and Pt/CeO2 Catalysts for Fuel Cell Applications

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