Fluid flow and mixing in a channel with dual bluff bodies

Xiao, Jian; Jing, Dalei

doi:10.1063/5.0187211

Physics of Fluids

2024

DOI: 10.1063/5.0187211

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Fluid flow and mixing in a channel with dual bluff bodies

Jian Xiao,

Dalei Jing

Abstract: Placing bluff bodies in a mixing channel is an important technique to enhance mixing. This paper numerically investigates the effects of transversal spacing and axial spacing of two bluff bodies on the outlet mixing efficiency (Mout), the pressure loss (ΔP), and the combined performance parameter η (the ratio of Mout to dimensionless ΔP) of fluid flow within mixing channels with dual bluff bodies having three cross-sectional shapes of circle, square, and sector with Reynolds numbers based on bluff body dimensi… Show more

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Cited by 3 publications

References 41 publications

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Heat and mass transfer performance of low Reynolds number flow behind a cylinder connecting with an L-shaped flexible body within a microchannel

Hu,

Li,

Chen

et al. 2024

Physics of Fluids

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In order to enhance the heat and mass transfer performance of laminar flow within a microchannel at a low Reynolds number, this paper introduces an asymmetric structure of an L-shaped flexible body connecting to a cylinder into the microchannel and studies the effects of the geometric dimensions of the L-shaped flexible body on the flow pattern transition and the heat and mass transfer performance, including the pressure loss, the Nusselt number, and the outlet mixing efficiency. It is found that by means of an asymmetric structure of the L-shaped flexible body connecting to the cylinder, the flow pattern transitions from laminar flow to vortex flow at a low Reynolds number based on the diameter of the cylinder of Red = 25. The transition of the flow patterns induced by an asymmetric L-shaped flexible body enhances the thermal and mixing performance of the fluid flow within the microchannel. Both the Nusselt number and the outlet mixing efficiency significantly increase under the influence of the L-shaped flexible body compared to the case with a single cylinder, and they increase with the increasing length of the vertical part of the L-shaped flexible body. The findings in the present work provide a new strategy to enhance the heat and mass transfer performance of low-Reynolds-number fluid flow within a microchannel by using the interaction of an asymmetric flexible body with the fluid flow behind a bluff body.

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Heat and mass transfer performance of low Reynolds number flow behind a cylinder connecting with an L-shaped flexible body within a microchannel

Hu,

Li,

Chen

et al. 2024

Physics of Fluids

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Flow around triangular prisms with varying vertex angle at low Reynolds numbers

Khan,

Khan

2024

Physics of Fluids

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The present work investigates the unsteady flow around triangular prisms with vertex angles of 30°,45°,60°, and 90° for shedding Reynolds number between 50 and 150. The numerical simulations of flow around triangular prisms at different vertex angles and Reynolds number has been carried out using the open-source code OpenFOAM. The wake of the prisms in different cases has been examined using instantaneous and time-averaged velocity and vorticity fields. The energy dynamics in the wake are demonstrated using enstrophy. The paper explains the shedding around a prism and reports the differences in the wake due to the different vertex angles of the prisms employed in the present work. Strouhal number and force coefficients have been obtained and compared for different prisms. The coefficient of lift and drag phase plot indicates a higher spread for prisms with larger vertex angles at higher Reynolds number. The shedding frequency has a linear variation with Reynolds numbers for the prisms. The obtained results were compared with earlier works on square cylinders and 45° oriented square cylinder.

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Numerical Study on the Hydraulic and Mixing Performance of Fluid Flow within a Channel with Different Numbers of Sector Bodies

Xiao,

Jing

2024

Water

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This study numerically analyzes and compares the outlet mixing efficiency (Mout), the pressure loss (ΔP), and the comprehensive performance parameter η, defined as the ratio between Mout and dimensionless pressure drop, of fluid flow in mixing channels with a single sector body (CSSB), dual sector bodies (CDSB), and triple sector bodies (CTSB). This analysis is conducted under a Reynolds number based on the dimension of the sector body Red = 100. The analysis reveals that both for the CDSB and CTSB, when the spacing distance between the sector bodies is small, the downstream sector body blocks the vortex shedding, resulting in a low mixing degree. Increasing the spacing distance between the sector bodies can significantly improve the mixing performance. When comparing the performance of three configurations, it is found that only when the spacing distances between the sector bodies in CDSB and CTSB are large enough, their outlet mixing efficiencies converge to a closed value, surpassing that of CSSB, but at the expense of a substantial pressure loss. Moreover, the CSSB consistently outperforms the CDSB and CTSB in terms of comprehensive performance. This study provides insights into the selection and spacing of bluff bodies in channels to achieve desirable hydraulic and mixing performance.

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Fluid flow and mixing in a channel with dual bluff bodies

Cited by 3 publications

References 41 publications

Heat and mass transfer performance of low Reynolds number flow behind a cylinder connecting with an L-shaped flexible body within a microchannel

Heat and mass transfer performance of low Reynolds number flow behind a cylinder connecting with an L-shaped flexible body within a microchannel

Flow around triangular prisms with varying vertex angle at low Reynolds numbers

Numerical Study on the Hydraulic and Mixing Performance of Fluid Flow within a Channel with Different Numbers of Sector Bodies

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