Two-phase flow structures in a helically coiled microchannel: An experimental investigation

Saisorn, Sira; Benjawun, Phakkhanan; Suriyawong, Adirek; Asirvatham, Lazarus Godson; Mondal, Pranab Kumar; Wongwises, Somchai

doi:10.1063/5.0171004

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Physics of Fluids

2023

DOI: 10.1063/5.0171004

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Two-phase flow structures in a helically coiled microchannel: An experimental investigation

Sira Saisorn,

Phakkhanan Benjawun,

Adirek Suriyawong

et al.

Abstract: At the microfluidic scale, the utilization of helically coiled channels (HCCs), also known as a spiral channel, for two-phase flow offers numerous advantages in various applications. Existing articles mainly focus on the macro-scale transport, examining secondary flows induced in curved channels. The increasing demand, however, for innovative miniature equipment for thermal energy management emphasizes the importance of comprehending gas–liquid micro-scale flow in curved channels. Unfortunately, despite a vast… Show more

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2024

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Cited by 2 publications

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Lattice Boltzmann study of the effect of metal foam on bubble behavior and heat transfer performance in flow boiling

Cai,

Liu,

Zheng

et al. 2024

Applied Thermal Engineering

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Lattice Boltzmann study of the effect of metal foam on bubble behavior and heat transfer performance in flow boiling

Cai,

Liu,

Zheng

et al. 2024

Applied Thermal Engineering

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Machining technologies and structural models of microfluidic devices

Gou,

Meng,

Yan

et al. 2024

Proceedings of the Institution of Mechanical Engineers, Part C:

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In the past decades, microfluidic chips have been one of the hottest research topics in the “lab-on-a-chip” field. However, it is still a challenge for design the perfect microchannels with high functional integration, complex geometry, and high production efficiency. This review paper provides a comprehensive overview of microfluidic structural models and designs, manufacturing techniques, and bonding methods. The effect of three types of microfluidic channel structure models and their configuration parameters on the fluid behaviors of microfluidics was investigated. Surface-to-volume ratio of the flow channel is a critical parameter for determining the mixing and diffusion capabilities of the microfluidic devices (MDs). Thereafter, the main manufacturing techniques for microstructures were discussed, including etching, photolithography, soft lithography, molding, mechanical micro-machining, laser beam micromachining, printing, and 3D printing. We performed a statistical analysis to discuss the relative advantages and disadvantages of these manufacturing methods. In addition, the current bonding methods for MDs were also summarized, including thermal bonding, solution adhesive bonding, dry adhesive bonding, plasma bonding, and anodic bonding. a comparison of different bonding methods was presented to provide a reference to select a suitable bonding method for the assembly of microfluidic device. Finally, the tendencies and challenges of microchannel manufacturing were discussed, and the prospects were also provided.

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Two-phase flow structures in a helically coiled microchannel: An experimental investigation

Cited by 2 publications

References 54 publications

Lattice Boltzmann study of the effect of metal foam on bubble behavior and heat transfer performance in flow boiling

Lattice Boltzmann study of the effect of metal foam on bubble behavior and heat transfer performance in flow boiling

Machining technologies and structural models of microfluidic devices

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