Open-hardware design and characterization of an electrostatic aerosol precipitator

[Display omitted] Electrostatic precipitators are devices that remove charged particles from an air stream. We present the design and characterization of an electrostatic precipitator that is intended to be incorporated into aerosol sampling equipment. Hardware and software components of the design...

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Bibliographic Details
Published in:HardwareX 2022-04, Vol.11 (C), p.e00266-e00266, Article e00266
Main Authors: Kasparoglu, Sabin, Wright, Timothy P., Petters, Markus D.
Format: Article
Language:English
Subjects:
Aerosol science
Aerosol technology
Dual tandem differential mobility analyzer
Electrostatic precipitator
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Summary:[Display omitted] Electrostatic precipitators are devices that remove charged particles from an air stream. We present the design and characterization of an electrostatic precipitator that is intended to be incorporated into aerosol sampling equipment. Hardware and software components of the design are open, all components can be directly purchased from vendors, and the device can be assembled with standard tools. Generic components are used to allow the repurposing of parts for other uses. The computer-controlled high-voltage power supply box associated with the project can be used for other common high-voltage applications in Aerosol Science and Technology, such as data acquisition and control systems for scanning mobility particle sizers. Computational fluid dynamics simulations are used to quantify the 3D flow field. The transfer function associated with the partial transmission is characterized through modeling and experiments. The observed transfer function is unique but deviates from the ideal transfer function due to the distortion of the flow near the inlet and the outlet of the device. Singly charged particles up to 624 nm and 253 nm can be completely removed for 0.5 L min−1 and 1 L min−1, respectively. We anticipate that our device will increase the accessibility of the technique to a broader audience.
ISSN:2468-0672
2468-0672
DOI:10.1016/j.ohx.2022.e00266