3D-printed pulsator to enhance mass transfer in electrochemical reactors
3D-printed pulsator to enhance mass transfer in electrochemical reactors
This study presents a cost-effective diaphragm pulsator, constructed for approximately €500, designed to enhance mass transport in laboratory electrochemical reactors. The pulsator allows accurate control of pulsation frequency between 1 Hz and 6 Hz and displacement volume, with simple programmability using an Arduino microcontroller. The design features multiple chambers that effectively isolate corrosive liquids from the mechanical components, ensuring durability and extended operational life. The pulsator's 3D-printed components can be customized with different materials to suit various applications. Engineered to generate a pulsating flow profile that closely resembles a sinusoidal wave, video tracking analysis confirmed the sinusoidal nature of the flow, demonstrating consistent flow profile generation with adjustable frequency and amplitude. The maximum volume displacement achieved was 11.9 mL, which was reduced to 2.0 mL when the electrochemical cell was connected. Limiting current experiments with a ferri/ferrocyanide electrolyte showed that the mass transport coefficient of a typical cell increased from 2.3 × 10
−3 cm/s under constant flow to 4.5 × 10
−3 cm/s under pulsating conditions. These findings validate that the adjustable, Arduino-programmable sinusoidal pulsation generated by the diaphragm pulsator offers a practical and customizable method for enhancing mass transport in small-scale electrochemical reactors.
Diaphragm pulsator, Electrochemical reactor, Mass transport enhancement, Pulsating flow, Sinusoidal flow profile
Teenakul, Kavin
1fdb53c2-c236-4da2-bba1-aa1ccb77ba22
Arenas, Luis Fernando
6e7e3d10-2aab-4fc3-a6d4-63a6614d0403
Hereijgers, Jonas
30f0d757-dbcb-4a69-8c73-716688046b66
2 April 2025
Teenakul, Kavin
1fdb53c2-c236-4da2-bba1-aa1ccb77ba22
Arenas, Luis Fernando
6e7e3d10-2aab-4fc3-a6d4-63a6614d0403
Hereijgers, Jonas
30f0d757-dbcb-4a69-8c73-716688046b66
Teenakul, Kavin, Arenas, Luis Fernando and Hereijgers, Jonas
(2025)
3D-printed pulsator to enhance mass transfer in electrochemical reactors.
HardwareX, 22, [e00645].
(doi:10.1016/j.ohx.2025.e00645).
Abstract
This study presents a cost-effective diaphragm pulsator, constructed for approximately €500, designed to enhance mass transport in laboratory electrochemical reactors. The pulsator allows accurate control of pulsation frequency between 1 Hz and 6 Hz and displacement volume, with simple programmability using an Arduino microcontroller. The design features multiple chambers that effectively isolate corrosive liquids from the mechanical components, ensuring durability and extended operational life. The pulsator's 3D-printed components can be customized with different materials to suit various applications. Engineered to generate a pulsating flow profile that closely resembles a sinusoidal wave, video tracking analysis confirmed the sinusoidal nature of the flow, demonstrating consistent flow profile generation with adjustable frequency and amplitude. The maximum volume displacement achieved was 11.9 mL, which was reduced to 2.0 mL when the electrochemical cell was connected. Limiting current experiments with a ferri/ferrocyanide electrolyte showed that the mass transport coefficient of a typical cell increased from 2.3 × 10
−3 cm/s under constant flow to 4.5 × 10
−3 cm/s under pulsating conditions. These findings validate that the adjustable, Arduino-programmable sinusoidal pulsation generated by the diaphragm pulsator offers a practical and customizable method for enhancing mass transport in small-scale electrochemical reactors.
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More information
Accepted/In Press date: 22 March 2025
Published date: 2 April 2025
Keywords:
Diaphragm pulsator, Electrochemical reactor, Mass transport enhancement, Pulsating flow, Sinusoidal flow profile
Identifiers
Local EPrints ID: 501986
URI: http://eprints.soton.ac.uk/id/eprint/501986
ISSN: 2468-0672
PURE UUID: 5a5b9df9-1078-43f7-a09f-9d84ecb27629
Catalogue record
Date deposited: 12 Jun 2025 17:23
Last modified: 13 Jun 2025 01:55
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Author:
Kavin Teenakul
Author:
Jonas Hereijgers
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