Non-Newtonian fluids analysis in microdevices is challenging both in biological and chemical applications. In this context, the flow velocity evaluation is crucial. This work presents a portable and disposable micro-optofluidic detector ( mu OFD), in which microoptical and microfluidic components are integrated and used for the real-time characterization of a sequenced flow generated by two immiscible fluids, called slug flow. The 3D-printed approach was chosen for the device fabrication, being simple, flexible, fast, and low-cost, and for the possibility of exploring wider channel geometries as compared to soft lithography. In the micro optofluidic detector, the light interacts with the flow in two observation points, 1 mm apart from each other, placed along the microchannel at 26 mm far from the T-junction. The optical signal variations, correlated with the fluids' optical properties, were used for real-time tracking of slug frequency passage, velocity, and length by an ad hoc signal processing procedure. Two mu OFD prototypes were presented. One prototype was entirely made in poly-dimethyl-siloxane (PDMS), while in the second, the microoptical component was made of VeroClear and the microfluidic part in PDMS. Both prototypes were successfully characterized in different hydrodynamic conditions as proof of concept of their validity as flow velocity detectors. The advantage of realizing, by using a low-cost and easy-to-use fabrication process, a micro-optofluidic device that embeds the optical monitoring elements and the microchannels, without constraints on the localization of the observation point and microchannel height, opens the way to the design of a great variety of lab-on-a-chip (LOC) microdevices for complex fluids investigation.

3D-Printed Micro-Optofluidic Slug Flow Detector

Stella, Giovanna;Saitta, Lorena;Moscato, Samuele;Cicala, Gianluca;Bucolo, Maide
2024-01-01

Abstract

Non-Newtonian fluids analysis in microdevices is challenging both in biological and chemical applications. In this context, the flow velocity evaluation is crucial. This work presents a portable and disposable micro-optofluidic detector ( mu OFD), in which microoptical and microfluidic components are integrated and used for the real-time characterization of a sequenced flow generated by two immiscible fluids, called slug flow. The 3D-printed approach was chosen for the device fabrication, being simple, flexible, fast, and low-cost, and for the possibility of exploring wider channel geometries as compared to soft lithography. In the micro optofluidic detector, the light interacts with the flow in two observation points, 1 mm apart from each other, placed along the microchannel at 26 mm far from the T-junction. The optical signal variations, correlated with the fluids' optical properties, were used for real-time tracking of slug frequency passage, velocity, and length by an ad hoc signal processing procedure. Two mu OFD prototypes were presented. One prototype was entirely made in poly-dimethyl-siloxane (PDMS), while in the second, the microoptical component was made of VeroClear and the microfluidic part in PDMS. Both prototypes were successfully characterized in different hydrodynamic conditions as proof of concept of their validity as flow velocity detectors. The advantage of realizing, by using a low-cost and easy-to-use fabrication process, a micro-optofluidic device that embeds the optical monitoring elements and the microchannels, without constraints on the localization of the observation point and microchannel height, opens the way to the design of a great variety of lab-on-a-chip (LOC) microdevices for complex fluids investigation.
2024
Fluids
Microfluidics
Optical device fabrication
Detectors
Biomedical optical imaging
Optical devices
Optical fibers
Flow velocity
microfluidics
microoptics
non-Newtonian fluids
two-phase flow
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/20.500.11769/636629
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