JP Journal of Heat and Mass Transfer

The JP Journal of Heat and Mass Transfer is indexed in Scopus® and specializes in publishing articles related to heat and mass transfer. The journal covers both theoretical and experimental aspects and emphasizes their applications in engineering, electronics, environmental sciences, and nanoscale heat transfer. Additionally, the journal welcomes articles that explore transport-property data, energy engineering, and environmental applications.

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THE EFFECT OF INLET VELOCITIES ON THE DROPLET SIZE IN T-JUNCTION MICROFLUIDIC DEVICES

Authors

  • Trong-Hy Tran
  • Thanh-Long Le
  • Duc-Thong Hong
  • Tran-Phu Nguyen

DOI:

https://doi.org/10.17654/0973576322030

Abstract

Droplet formation in microfluidics involves the flow of an immiscible liquid to form single droplets dispersed in a microfluidic channel. The control of the microfluidic droplet size produced in a microfluidic junction is far-reaching in several mechanical, biomedical and optical applications. This paper presents a numerical computation to study a droplet evolution in a T-junction microfluidic device. The normal flow velocity of the inlet is given for oil and water flows. The effect of inlet velocity on droplet size and droplet generation frequency is observed using COMSOL Multiphysics software. To observe the variation in droplet size and generation frequency, the inlet velocities for water and oil phases are varied from 30mm/s to 70mm/s and 80mm/s to 120mm/s, respectively. The numerical results show that the droplet volume decreases and the production frequency increases as the continuous phase inlet velocity is increased, consistent with conservation laws. The control of inlet velocities consequently manipulates the droplet size.

Received: May 4, 2022
Accepted: June 7, 2022

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Published

2022-07-15

Issue

Vol. 28 (2022)

Section

Articles

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How to Cite

THE EFFECT OF INLET VELOCITIES ON THE DROPLET SIZE IN T-JUNCTION MICROFLUIDIC DEVICES. (2022). JP Journal of Heat and Mass Transfer, 28, 1-14. https://doi.org/10.17654/0973576322030

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