Flow dynamic in a packed bed filled with Ni‐Al<sub>2</sub>O<sub>3</sub> porous catalyst: Experimental and numerical approach

Pashchenko, Dmitry

doi:10.1002/aic.16558

Cited by 34 publications

(16 citation statements)

References 44 publications

(54 reference statements)

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“…The pressure drop in packed bed reactors becomes significant at high flow rates, low bed porosity or small catalyst particles, and large bed heights. [43][44][45] However, in the present work, catalyst particles in the range of 250 to 400 m were used, and the catalyst bed was not high enough to cause any significant pressure drop. A relatively low flow rate of inlet gas was used, and with the reactor, inner diameter of 6 mm, the linear velocity was 0.015 m/s.…”

Section: Catalyst Evaluationmentioning

confidence: 94%

Nonoxidative methane activation, coupling, and conversion to ethane, ethylene, and hydrogen over Fe/HZSM‐5, Mo/HZSM‐5, and Fe–Mo/HZSM‐5 catalysts in packed bed reactor

et al. 2019

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Summary A high abundance of methane and its relatively low price make it an attractive raw feedstock for the production of ethylene, which is in the consumer demand in recent years. Direct catalytic nonoxidative conversion is interesting, because it could be utilized on natural gas well sites. Monometallic and bimetallic Fe and Mo catalysts were prepared for the purpose of the coupling to ethane and ethene. Three supported materials were synthesized with the following loading of metal: 2.5‐wt% Fe, 5.0‐wt% Fe, and 2.5‐wt% Mo on HZSM‐5. Process' chemical reactions were also catalyzed with a constant 2.5‐wt% Mo/HZSM‐5, which had different amounts of Fe, namely, 0.5, 1.0, and 2.5 wt%. Fourier transform infrared (FTIR), N2 adsorption/desorption, NH3 temperature‐programmed desorption (TPD), scanning electron microscopy (SEM), transmission electron microscopy (TEM), and X‐ray diffraction (XRD) were applied for characterization. Coke, accumulated on spent solids, was determined by thermogravimetric analysis (TGA). Activity was evaluated in quartz‐packed bed reactor. All surfaces suffered from deactivation due to carbon formation. The addition of Fe to Mo increased CH4 reacted. The highest selectivity for alkenes was achieved over 1.0‐wt% Fe to 2.5‐wt% Mo/HZSM‐5. At the peak of performance, the C‐based reactivity was 52% for olefins and 2% for alkanes. Stability was accomplished over 2.5‐wt% Fe/HZSM‐5, where the rate of C2 synthesis was comparatively stable for 20 hours of the time on stream. The selective C‐basis yield for C2H4 and C2H6 was 36% and 23%, respectively. The lowest measured quantity of (carbonaceous) by‐products was deposited on 2.5‐wt% Fe/HZSM‐5 after 26 hours. Propylene was detected very limitedly.

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Section: Catalyst Evaluationmentioning

confidence: 94%

Nonoxidative methane activation, coupling, and conversion to ethane, ethylene, and hydrogen over Fe/HZSM‐5, Mo/HZSM‐5, and Fe–Mo/HZSM‐5 catalysts in packed bed reactor

et al. 2019

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“…This indicated that the methanol solution flow rate in testing range (0.5‐3.5 g/min) has little effect on hydrogen production performance of MFPS, and the MFPS can be operated at methanol flow rate of 0.8 to 3.0 g/min. With the increasing of methanol solution flow rate, the pressure drops of the reactor increased 36,37 . According to the chemical equilibrium, we known that increasing the reactor pressure will impede the MSR reaction, which leads to the decrease of MSR conversion.…”

Section: Resultsmentioning

confidence: 99%

A methanol fuel processing system with methanol steam reforming and CO selective methanation modules for PEMFC application

Wang

Mei

et al. 2020

Intl J of Energy Research

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Summary Methanol steam reforming can convert methanol solution into hydrogen rich steam, which can be used to supply for the proton exchange membrane fuel cell (PEMFC). The carbon monoxide (CO) in the produced hydrogen rich steam will be poison to the PEMFC and limits the application of this technic. This study develops a new methanol fuel processing system (MFPS) with incorporated methanol steam reforming and CO selective methanation modules for production of hydrogen rich steam with a low concentration of CO, and used to directly supply for the PEMFC. The core component of the MFPS is a highly layer‐packed microreactor, wherein methanol steam reforming, methanol combustion, and CO selective methanation reactions can occur. For the developed MFPS, an optimized methanol supply strategy is proposed to startup the MFPS, the fastest startup time is about 15.8 minutes. Experimental tests showed that the MFPS can be continuously operated for more than 100 hours with CO concentration below 10 ppm. The produced hydrogen rich steam was directly supplied for a PEMFC to generate 100 W electricity. Results obtained in this study demonstrated that the developed MFPS can produce CO‐free hydrogen rich stream for the supply of PEMFC, the generated electricity can be used to power mobile device and/or electronics.

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“…Due to the size of the used powders, a slight increase in the reactor pressure is detected (0.05 atm). However, considering the use of the particles in the form of powder and comparing the pressure drop relieved with the typical values available in the literature for fixed bed reactor, 36 the pressure drops are considered negligible.…”

Section: Methodsmentioning

confidence: 99%

Pure hydrogen production by steam‐iron process: The synergic effect of MnO ₂ and Fe ₂ O ₃

et al. 2020

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Summary In the energy transition from fossil to clean fuels, hydrogen plays a key role. Proton‐exchange membrane fuel cells (PEMFCs) represent the most promising hydrogen application, but they require a pure hydrogen stream (CO < 10 ppm). The steam iron process represents a technology for the production of pure H2, exploiting iron redox cycles. If renewable reducing agents are used, the process can be considered completely green. In this context, bio‐ethanol can be an interesting solution that is still not thoroughly explored. In this work, the use of ethanol as a reducing agent in the steam iron process will be investigated. Ethanol, at high temperature, decomposes mainly in syngas but can also form coke, which can compromise the process effectiveness, reacting with water and producing CO together with H2. In this work, the deposition of coke is avoided by controlling the duration of the reduction step; in fact, the data demonstrated that coke deposition is significantly dependent on reduction time. Tests were carried out in a fixed bed reactor using hematite (Fe2O3) as raw iron oxide adopting several reduction times (7 minutes‐25 minutes), which correspond to different amount of ethanol fed (5 mmolC2H5OH/gFe2O3‐17,95 mmolC2H5OH/gFe2O3). The effect of the addition of MnO2 to increase the reduction degree of iron oxides was explored using different amount of MnO2 (10 wt% and 40 wt% with respect to Fe2O3). The tests were performed at fixed temperatures of 675°C and atmospheric pressure. The optimization of the reduction time, in the chosen operating condition, performed only with Fe2O3, shows that, feeding an amount of 5 mmolC2H5OH/gFe2O3, coke deposition is avoided and, therefore, a pure H2 stream in oxidation is obtained. The addition of MnO2 leads to increased H2 yield and process efficiency, confirming its positive effect on the reduction degree of the solid bed. A reaction pathway to demonstrate the synergic effect of Fe2O3 and MnO2 in the reduction step was proposed in this article.

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Flow dynamic in a packed bed filled with Ni‐Al₂O₃ porous catalyst: Experimental and numerical approach

Cited by 34 publications

References 44 publications

Nonoxidative methane activation, coupling, and conversion to ethane, ethylene, and hydrogen over Fe/HZSM‐5, Mo/HZSM‐5, and Fe–Mo/HZSM‐5 catalysts in packed bed reactor

Nonoxidative methane activation, coupling, and conversion to ethane, ethylene, and hydrogen over Fe/HZSM‐5, Mo/HZSM‐5, and Fe–Mo/HZSM‐5 catalysts in packed bed reactor

A methanol fuel processing system with methanol steam reforming and CO selective methanation modules for PEMFC application

Pure hydrogen production by steam‐iron process: The synergic effect of MnO ₂ and Fe ₂ O ₃

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Flow dynamic in a packed bed filled with Ni‐Al2O3 porous catalyst: Experimental and numerical approach

Cited by 34 publications

References 44 publications

Nonoxidative methane activation, coupling, and conversion to ethane, ethylene, and hydrogen over Fe/HZSM‐5, Mo/HZSM‐5, and Fe–Mo/HZSM‐5 catalysts in packed bed reactor

Nonoxidative methane activation, coupling, and conversion to ethane, ethylene, and hydrogen over Fe/HZSM‐5, Mo/HZSM‐5, and Fe–Mo/HZSM‐5 catalysts in packed bed reactor

A methanol fuel processing system with methanol steam reforming and CO selective methanation modules for PEMFC application

Pure hydrogen production by steam‐iron process: The synergic effect of MnO 2 and Fe 2 O 3

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Flow dynamic in a packed bed filled with Ni‐Al₂O₃ porous catalyst: Experimental and numerical approach

Pure hydrogen production by steam‐iron process: The synergic effect of MnO ₂ and Fe ₂ O ₃