A Simplified Method for Modeling of Pressure Losses and Heat Transfer in Fixed-Bed Reactors with Low Tube-to-Particle Diameter Ratio

Świeboda, T.; Krzyżyńska, Renata; Bryszewska-Mazurek, A.; Mazurek, Walentyna; Wysocka, A

doi:10.3390/en14030784

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A Short Review Of the Contributions In This Issue1

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2022

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Cited by 2 publications

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“…The article [3] entitled "A Simplified Method for Modeling of Pressure Losses and Heat Transfer in Fixed-Bed Reactors with Low Tube-to-Particle Diameter Ratio" focuses on modeling fixed bed reactors using porous models. The proposed simplified methodology showed that complicated methods of mapping the internal structure of the bed can be avoided.…”

Section: A Short Review Of the Contributions In This Issuementioning

confidence: 99%

Turbulence and Fluid Mechanics

Malecha

2022

Energies

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Section: A Short Review Of the Contributions In This Issuementioning

confidence: 99%

Turbulence and Fluid Mechanics

Malecha

2022

Energies

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Relay Upgrading of Biomass Producer Gas Via Shift-Methanation Plus CO2 Adsorption in a Symbiotic Fixed-Bed Reactor: Concept Proposition and Numerical Visualization

Dong

Luo

Huang

et al. 2022

Journal of Energy Resources Technology

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Producer gas from biomass gasification is a feasible supplementary source to overcome the shortage of energy supply. However, the relatively high CO content and low heating value (LHV) greatly restrict raw biomass producer gas for extensive application. The technical combination of shift-methanation reaction and CO2 adsorption is proved to be an effective upgrading method. Different from the conventional tandem way of connecting shift-methanation and CO2 adsorption, this work firstly attempts to integrate the two units into a fixed-bed reactor to form a cooperative symbiotic relationship. The relay upgrading process of biomass producer gas is numerically investigated over Ni-based catalyst and mesoporous carbon adsorbent using computational fluid dynamics (CFD) method. It is found that the CO content can be effectively reduced from 30.8% to below 5% and lower heating value on wet basis can be increased from 6.5 MJ/Nm3 to over 10 MJ/Nm3. The influence of catalyst and adsorbent bed volume on the composition of product gas is evaluated. Meanwhile, the effect of catalyst and adsorbent bed gap is also analyzed. Given the similarity of catalyst and adsorbent bed, the impact of their sequence on the upgrading performance is discussed. At last, for continuous run, a regeneration cycle involving reaction-adsorption coupled with N2 purge is designed and the cycle simulation is conducted to better understand the flow behavior and reaction/adsorption characteristic.

show abstract

A Simplified Method for Modeling of Pressure Losses and Heat Transfer in Fixed-Bed Reactors with Low Tube-to-Particle Diameter Ratio

Cited by 2 publications

References 17 publications

Turbulence and Fluid Mechanics

Turbulence and Fluid Mechanics

Relay Upgrading of Biomass Producer Gas Via Shift-Methanation Plus CO2 Adsorption in a Symbiotic Fixed-Bed Reactor: Concept Proposition and Numerical Visualization

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