Anodic aluminum oxide supported Cu-Zn catalyst for oxidative steam reforming of methanol

Kim, Jung Hyeon; Jang, Young Shin; Kim, Jae Chang; Kim, Dong Hyun

doi:10.1007/s11814-018-0211-9

Cited by 15 publications

(2 citation statements)

References 40 publications

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“…Hydrogen classification on the basis of their production source and methodology. Frontiers in Thermal Engineering frontiersin.org Khani et al, 2019;Kim et al, 2019;Lian et al, 2019;Mohtashami and Taghizadeh, 2019;Sarafraz et al, 2019;Zeng et al, 2019). Traditionally, methane had remained an effective source of hydrogen production.…”

Section: Figurementioning

confidence: 99%

Hydrogen production using advanced reactors by steam methane reforming: A review

Ganguli

Bhatt

2023

Front. Therm. Eng.

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The present review focuses on the current progress on harnessing the potential of hydrogen production by Methane Steam Reforming (MSR). First, based on the prominent literature in last few years, the overall research efforts of hydrogen production using different feed stocks like ethanol, ammonia, glycerol, methanol and methane is presented. The presented data is based on reactor type, reactor operating conditions, catalyst used and yield of hydrogen to provide a general overview. Then, the most widely used process [steam methane reforming (SMR)/methane steam reforming (MSR)] are discussed. Major advanced reactors, the membrane reactors, Sorption Enhanced methane steam reforming reactors and micro-reactors are evaluated. The evaluation has been done based on parameters like residence time, surface area, scale-up, coke formation, conversion, space velocity and yield of hydrogen. The kinetic models available in recently published literature for each of these reactors have been presented with the rate constants and other parameters. The mechanism of coke formation and the rate expressions for the same have also been presented. While membrane reactors and sorption enhanced reactors have lot of advantages in terms of process intensification scale-up to industrial scale is still a challenge due to factors like membrane stability and fouling (in membrane reactors), decrease in yield with increasing WHSV (in case of Sorption Enhanced Reactors). Micro-reactors pose a higher potential in terms of higher yield and very low residence time in seconds though the volumes might be substantially lower than present industrial scale conventional reactors.

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Section: Figurementioning

confidence: 99%

Hydrogen production using advanced reactors by steam methane reforming: A review

Ganguli

Bhatt

2023

Front. Therm. Eng.

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“…Thermal conversion includes steam reforming 5, dry reforming 6, 7, and partial oxidation reforming 8, 9. Although steam reforming and partial oxidation reforming have already been put into practical use, steam reforming has a problem of energy cost for maintaining a high temperature, which is the activation temperature of a catalyst, despite its high hydrogen conversion rate.…”

Section: Introductionmentioning

confidence: 99%

Development of a Combined Plasma‐Matrix Reformer for Solid Oxide Fuel Cell Application

Chun

2021

Chem Eng & Technol

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A novel plasma‐matrix reformer (PMR) was suggested for methane conversion into hydrogen‐rich fuel. To demonstrate the possibility of reforming performance, characteristics of product gas and CH4 conversion were identified according to O2/C ratio, water vapor supply, reformed gas recirculation, and water feed in the recirculation gas affecting energy conversion and hydrogen production. When the reformed gas recirculation and water feed to the recirculation pipe were performed at the same time, hydrogen production and energy conversion efficiency were superior compared to the conventional reforming method. The optimal operating conditions of the PMR were determined. The obtained high energy conversion efficiency and hydrogen selectivity indicated the applicability to solid oxide fuel cell stacks for residential power generation.

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Hydrogen generation from methanol reforming for fuel cell applications: A review

Sun

2020

J. Cent. South Univ.

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Anodic aluminum oxide supported Cu-Zn catalyst for oxidative steam reforming of methanol

Cited by 15 publications

References 40 publications

Hydrogen production using advanced reactors by steam methane reforming: A review

Hydrogen production using advanced reactors by steam methane reforming: A review

Development of a Combined Plasma‐Matrix Reformer for Solid Oxide Fuel Cell Application

Hydrogen generation from methanol reforming for fuel cell applications: A review

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