Periodical oscillation of particle-laden laminar flow within a tubular photocatalytic hydrogen production reactor predicted by discrete element method

Geng, Jiafeng; Tang, Junwang; Cai, Wenfang; Wang, Yechun; Jing, Dengwei; Guo, Liejin

doi:10.1016/j.ijhydene.2020.08.066

Cited by 6 publications

(1 citation statement)

References 64 publications

(69 reference statements)

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“…Nevertheless, we observe that λ finally saturates with f . An object of size w can follow the oscillatory fluid only if the characteristic time of the fluid motion t f ∼ 1/f is larger than the relaxation time t r of the object in the fluid (which scales as t r ∼ w 2 in low Reynolds number regime [49]). This sets an upper limit on f for a given object size, above which the shear cannot efficiently move the object (we obtain f max ≈ 4 Hz for a stripe of width w = 3σ).…”

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confidence: 99%

Striped Patterns in Radially Driven Suspensions with Open Boundaries

Mohammadi,

Maleki,

Wysocki

et al. 2021

Preprint

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We study the motion of radially driven fluid-immersed particles in a novel Hele-Shaw cell with open boundaries. The initially uniform suspension forms a striped pattern within a specific range of horizontal oscillation frequencies and for sufficiently large amplitudes. We observe that the initial coarsening dynamics of the stripes gradually slows down and the pattern reaches a steady state after a few minutes. The distance between the stripes in the steady state exhibits an exponentially saturating increase with increased oscillation amplitude or frequency. The width of the stripes decreases as a power-law with the frequency while its amplitude dependence follows a logistic function. We propose a mechanism-based on the interplay between shear stress, hydrodynamic interactions, and frictional forces-to link the structural characteristics of the stripes to the properties of the oscillatory external drive. We discuss the similarities of the striped patterns in our experiments to the ripples observed along curved sandy coasts.

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confidence: 99%

Striped Patterns in Radially Driven Suspensions with Open Boundaries

Mohammadi,

Maleki,

Wysocki

et al. 2021

Preprint

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A Comprehensive Review of Solar Photocatalysis & Photothermal Catalysis for Hydrogen Production from Biomass: from Material Characteristics to Engineering Application

Lei,

Wang,

et al. 2024

Chemistry A European J

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Biomass photoreforming is a promising way of producing sustainable hydrogen thanks to the abundant sources of biomass feedstocks. Solar energy provides the heat and driven force to initial biomass oxidation coupled with H2 evolution. Currently, biomass photoreforming is still far from plant‐scale applications due to the lower solar energy utilization efficiencies, the low H2 yield, and the lack of appropriate photoreactors. The production of H2 from photoreforming of native biomass and platform molecules was summarized and discussed with special attention to the prospects of scaling up the catalysis technology for mass production of hydrogen. The types of photoreforming including photocatalysis and photothermal catalysis were discussed consequently considering the different requirements for photoreactors. We also reviewed the photoreactors that support biomass photoreforming. Numerical simulation methods were implemented for the solid‐liquid two‐phase flow and inter‐particle radiative transfer involved in the reaction process. Developing concentrated photothermal catalytic flowed reactors is beneficial to scale‐up catalytic hydrogen production from biomass.

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