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Computational modeling of a low-cost fluidic oscillator for use in an educational respiratory simulator

Computational modeling of a low-cost fluidic oscillator for use in an educational respiratory simulator
Computational modeling of a low-cost fluidic oscillator for use in an educational respiratory simulator

Herein, the computational modeling of a fluidic oscillator for use in an educational respiratory simulator apparatus is presented. The design provides realistic visualization and tuning of respiratory biomechanics using a part that is (i) inexpensive, (ii) easily manufactured without the need for specialized equipment, (iii) simple to assemble and maintain, (iv) does not require any electronics, and (v) has no moving components that could be prone to failure. A computational fluid dynamics (CFD) model is used to assess flow characteristics of the system, and a prototype is developed and tested with a commercial benchtop respiratory simulator. The simulations show clinically relevant periodic oscillation with outlet pressures in the range of 8–20 cmH2O and end-user-tunable frequencies in the range of 3–6 s (respiratory rate [RR] of 10–20 breaths per minute). The fluidic oscillator presented here functions at physiologically relevant pressures and frequencies, demonstrating potential as a low cost, hands-on, and pedagogical tool. The model will serve as a realistic model for educating Science, Technology, Engineering, and Mathematics (STEM) students on the relationship between flow, pressure, compliance, and volume in respiratory biomechanics while simultaneously exposing them to basic manufacturing techniques.

computational fluid dynamics, education, fluidic oscillators, mechanical ventilation, respiratory
Dillon, Tom
814a1bdc-2889-4870-a7d9-e8043a6595a6
Ozturk, Caglar
70bbd3bd-fc56-48e8-8b5e-00d5270c1526
Mendez, Keegan
5bd2007a-9db8-4a9c-817c-72d007aa7635
Rosalia, Luca
e3f00c11-aa4f-4454-ba25-cd0fd5cfb20a
Gollob, Samuel Dutra
36cf5aaf-31fc-4316-85b3-324eabca4ba3
Kempf, Katharina
281ceac5-54e4-40d5-ac58-7188cee268bd
Roche, Ellen Tunney
63e632c8-d821-4c2f-a728-aaf331a5c2a1
Dillon, Tom
814a1bdc-2889-4870-a7d9-e8043a6595a6
Ozturk, Caglar
70bbd3bd-fc56-48e8-8b5e-00d5270c1526
Mendez, Keegan
5bd2007a-9db8-4a9c-817c-72d007aa7635
Rosalia, Luca
e3f00c11-aa4f-4454-ba25-cd0fd5cfb20a
Gollob, Samuel Dutra
36cf5aaf-31fc-4316-85b3-324eabca4ba3
Kempf, Katharina
281ceac5-54e4-40d5-ac58-7188cee268bd
Roche, Ellen Tunney
63e632c8-d821-4c2f-a728-aaf331a5c2a1

Dillon, Tom, Ozturk, Caglar, Mendez, Keegan, Rosalia, Luca, Gollob, Samuel Dutra, Kempf, Katharina and Roche, Ellen Tunney (2021) Computational modeling of a low-cost fluidic oscillator for use in an educational respiratory simulator. Advanced NanoBiomed Research, 1 (12), [2000112]. (doi:10.1002/anbr.202000112).

Record type: Article

Abstract

Herein, the computational modeling of a fluidic oscillator for use in an educational respiratory simulator apparatus is presented. The design provides realistic visualization and tuning of respiratory biomechanics using a part that is (i) inexpensive, (ii) easily manufactured without the need for specialized equipment, (iii) simple to assemble and maintain, (iv) does not require any electronics, and (v) has no moving components that could be prone to failure. A computational fluid dynamics (CFD) model is used to assess flow characteristics of the system, and a prototype is developed and tested with a commercial benchtop respiratory simulator. The simulations show clinically relevant periodic oscillation with outlet pressures in the range of 8–20 cmH2O and end-user-tunable frequencies in the range of 3–6 s (respiratory rate [RR] of 10–20 breaths per minute). The fluidic oscillator presented here functions at physiologically relevant pressures and frequencies, demonstrating potential as a low cost, hands-on, and pedagogical tool. The model will serve as a realistic model for educating Science, Technology, Engineering, and Mathematics (STEM) students on the relationship between flow, pressure, compliance, and volume in respiratory biomechanics while simultaneously exposing them to basic manufacturing techniques.

Text
Advanced NanoBiomed Research - 2021 - Dillon - Computational Modeling of a Low‐Cost Fluidic Oscillator for Use in an - Version of Record
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More information

e-pub ahead of print date: 23 January 2021
Published date: 14 November 2021
Keywords: computational fluid dynamics, education, fluidic oscillators, mechanical ventilation, respiratory

Identifiers

Local EPrints ID: 490855
URI: http://eprints.soton.ac.uk/id/eprint/490855
DOI: doi:10.1002/anbr.202000112
PURE UUID: bb0f5f32-d0ed-4802-a29d-674c8226823c
ORCID for Caglar Ozturk: ORCID iD orcid.org/0000-0002-3688-0148

Catalogue record

Date deposited: 07 Jun 2024 16:34
Last modified: 08 Jun 2024 02:11

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Contributors

Author: Tom Dillon
Author: Caglar Ozturk ORCID iD
Author: Keegan Mendez
Author: Luca Rosalia
Author: Samuel Dutra Gollob
Author: Katharina Kempf
Author: Ellen Tunney Roche

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