Validation of Velocity in Microchannels with a Retention System due to Unevenness Manufactured by 3D Printing (SLA)

Samia A. Ramos-Ocaña; Víctor H. Cabrera-Moreta

doi:10.4028/p-5TTke0

Validation of Velocity in Microchannels with a Retention System due to Unevenness Manufactured by 3D Printing (SLA)

Samia A. Ramos-Ocaña
, Víctor H. Cabrera-Moreta

Research Group in Renewable Energies and Mechanical Implementation of SMEs (GIERIMP)

Research output: Contribution to journal › Article › peer-review

Abstract

Microfluidics is an efficient technology for controlling fluid movement in microchannels at extremely low speeds. The main advantage lies in the significant reduction of samples and reagents, thereby reducing costs and analysis times. Three devices with retention systems are introduced that are manufactured through 3D printing (SLA) incorporating microchannels with variations in levels and dimensions. Fluid velocity is studied, considering factors such as channel width, length, rounding, height, and shape. The analysis of velocity along the channel reveals liquid retention at the devices' maximum point, ensuring more precise results in microdevices.

Original language	English
Pages (from-to)	243-260
Number of pages	18
Journal	Defect and Diffusion Forum
Volume	439
DOIs	https://doi.org/10.4028/p-5TTke0
State	Published - 2025

Bibliographical note

Publisher Copyright:
© 2025 Trans Tech Publications Ltd, All Rights Reserved.

Keywords

Microfluidics
retention
SLA
slope
speed

CACES Knowledge Areas

8315A Biomedicine

Access to Document

10.4028/p-5TTke0

Cite this

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abstract = "Microfluidics is an efficient technology for controlling fluid movement in microchannels at extremely low speeds. The main advantage lies in the significant reduction of samples and reagents, thereby reducing costs and analysis times. Three devices with retention systems are introduced that are manufactured through 3D printing (SLA) incorporating microchannels with variations in levels and dimensions. Fluid velocity is studied, considering factors such as channel width, length, rounding, height, and shape. The analysis of velocity along the channel reveals liquid retention at the devices' maximum point, ensuring more precise results in microdevices.",

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Y1 - 2025

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AB - Microfluidics is an efficient technology for controlling fluid movement in microchannels at extremely low speeds. The main advantage lies in the significant reduction of samples and reagents, thereby reducing costs and analysis times. Three devices with retention systems are introduced that are manufactured through 3D printing (SLA) incorporating microchannels with variations in levels and dimensions. Fluid velocity is studied, considering factors such as channel width, length, rounding, height, and shape. The analysis of velocity along the channel reveals liquid retention at the devices' maximum point, ensuring more precise results in microdevices.

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KW - retention

KW - SLA

KW - slope

KW - speed

UR - https://www.scopus.com/pages/publications/105000275324

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EP - 260

JO - Defect and Diffusion Forum

JF - Defect and Diffusion Forum

ER -

Validation of Velocity in Microchannels with a Retention System due to Unevenness Manufactured by 3D Printing (SLA)

Abstract

Bibliographical note

Keywords

CACES Knowledge Areas

Access to Document

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