CFD Simulation of Ethanol Steam Reforming System for Hydrogen Production

Davidy, Alon

doi:10.3390/chemengineering2030034

Cited by 6 publications

(3 citation statements)

References 19 publications

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“…membrane-integrated reformer reactor (MRR) Methane reforming and hydrogen separation ANSYS Fluent [20] Radiation section of the top industrial steam methane reforming reactor Steam methane reforming Single program multiple data passing model [21] Wire mesh honeycomb catalytic module Diesel reforming for hydrogen production COMSOL Multiphysics 5.5 [22] Hydrogen generation for an on-site hydrogen refueling station (HRS) Steam methane reforming Ansys Fluent [23] Membrane reactor Methane steam reforming User-defined function (UDF) [24] Heat flow inside a catalyst particle of catalytic reactor Steam methane reforming Ansys Fluent [25] Hydrogen permeable membrane reactor CO 2 reforming of CH Pd-Ag membrane rector Glycerol steam reforming process COMSOL software [31] Catalytic bed reactor and ethanol burner Ethanol steam reforming system COMSOL Multiphysics [32] Fluidized bed reactor Sorption-enhanced crude glycerol steam reforming process Platform of MFIX CFD code [33] Catalytic membrane reactor Ethanol steam reforming process Comsol Multiphysics [34] Sorption-enhanced palladium membrane reactor Methane steam reforming Ansys commercial CFD code CFX [35] Wall catalytic steam reforming Steam reforming of aviation kerosene Fluent [36]…”

Section: Type Of Systemmentioning

confidence: 99%

A Review of the CFD Modeling of Hydrogen Production in Catalytic Steam Reforming Reactors

Ghasem

2022

IJMS

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Global demand for alternative renewable energy sources is increasing due to the consumption of fossil fuels and the increase in greenhouse gas emissions. Hydrogen (H2) from biomass gasification is a green energy segment among the alternative options, as it is environmentally friendly, renewable, and sustainable. Accordingly, researchers focus on conducting experiments and modeling the reforming reactions in conventional and membrane reactors. The construction of computational fluid dynamics (CFD) models is an essential tool used by researchers to study the performance of reforming and membrane reactors for hydrogen production and the effect of operating parameters on the methane stream, improving processes for reforming untreated biogas in a catalyst-fixed bed and membrane reactors. This review article aims to provide a good CFD model overview of recent progress in catalyzing hydrogen production through various reactors, sustainable steam reforming systems, and carbon dioxide utilization. This article discusses some of the issues, challenges, and conceivable arrangements to aid the efficient generation of hydrogen from steam reforming catalytic reactions and membrane reactors of bioproducts and fossil fuels.

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Section: Type Of Systemmentioning

confidence: 99%

A Review of the CFD Modeling of Hydrogen Production in Catalytic Steam Reforming Reactors

Ghasem

2022

IJMS

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“…Rengel et al [103] Pool Diesel/Gasoline L FDS/FLACS ✓ ✓ ✓ ✓ ✓ Qualitative/ Quantitative Davidy [104] Jet Heptane…”

Section: Measurements Cmentioning

confidence: 99%

Computational fluid dynamics modelling of hydrocarbon fires in open environments: Literature review

et al. 2020

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Hydrocarbon fuels are involved in most major fire accidents occurring in industrial facilities. Due to the need for an in-depth understanding of the phenomena associated with hydrocarbon fires, computational fluid dynamics (CFD) modelling has been widely employed in the field of fire risk analysis over the last decades. The aim of the present review is to provide the reader with a comprehensive compilation and discussion of the most important aspects involving CFD modelling to simulate hydrocarbon fires in open environments. The fire sizes simulated, the fuels used, the codes employed, the variables of interest measured, the simulation purposes and the results accuracy have been examined through a wide literature survey, which includes peerreviewed journals and congress papers dating from the 90s until now.

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“…The combustion of flame fuel in industrial furnaces as well as engines of various types is rapid process [12]. The heat released from fuel burning and carried by exhaust gaseous mixture and soot particles is transferred to reboiler tubes walls in by three main modes: forced and natural convection, thermal radiation, and conduction [13,14].…”

Section: Introductionmentioning

confidence: 99%

CFD Simulation of Forced Recirculating Fired Heated Reboilers

Davidy¹

2020

Processes

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An advanced algorithm has been developed in order to analyze the performance of re-boiling process of crude oil flowing inside reboilers tubes. The proposed model is composed from Heptane fire heater and a tube array. The heat flux produced from burner is transferred to the crude oil flowing inside the tube. The computational model is composed of two phases—Simulation of fire by using Fire Dynamics Simulator software (FDS) version 5.0 and then a nucleate boiling computation of the crude oil. FDS code is formulated based on CFD (Computational Fluid Dynamics) of fire heater. The thermo-physical properties (such as: thermal conductivity, heat capacity, surface tension, viscosity) of the crude oil were estimated by using empirical correlations. The thermal heat transfer to evaporating two-phase crude oil mixture occur by bubble generation at the wall (nucleate boiling) has been calculated by using Chen correlation. It has been assumed that the overall convective heat transfer coefficient is composed from the nucleate boiling convective coefficient and the forced turbulent convective coefficient. The former is calculated by Forster Zuber empirical equation. The latter is computed from the Dittus-Boelter relationship. In order to validate the nucleate boiling heat transfer coefficient, a comparison has been performed to nucleate boiling convective coefficient obtained by Mostinski equation. The relative error between the nucleate boiling convective heat-transfer coefficients is 10.5%. The FDS numerical solution has been carried out by using Large Eddy Simulation (LES) method. This work has been further extended to include also the structural integrity aspects of the reboiler metal pipe by using COMSOL Multiphysics software. It was found out, that the calculated stress is less than the ultimate tensile strength of the AISI 310 Steel alloy.

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CFD Simulation of Ethanol Steam Reforming System for Hydrogen Production

Cited by 6 publications

References 19 publications

A Review of the CFD Modeling of Hydrogen Production in Catalytic Steam Reforming Reactors

A Review of the CFD Modeling of Hydrogen Production in Catalytic Steam Reforming Reactors

Computational fluid dynamics modelling of hydrocarbon fires in open environments: Literature review

CFD Simulation of Forced Recirculating Fired Heated Reboilers

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