Issue 11, 2022

A scalable twin surface dielectric barrier discharge system for pollution remediation at high gas flow rates

Abstract

In this work, a modular, multi-electrode surface dielectric barrier discharge system for the decomposition of polluted air streams at high volumetric flows, necessary for industrial applications, is designed and constructed. The system is demonstrated for the decomposition of butoxyethanol and n-butane in ambient air flows of up to almost 500 slm (standard litres per minute) (≙ 30 m3 h−1) at concentrations between 50 ppm and 1000 ppm. With an energy density of (78.3 ± 3.6) J L−1 a maximum relative conversion of about 27% of butoxyethanol is achieved. n-Butane was used to enable comparison with previous studies. Here it could be demonstrated that the scaled-up source achieved higher conversion at lower energy densities in comparison to the original design used at lower volumetric flow rates. Additionally, the density of ozone, which is a toxic by-product of the overall process, was measured in the exhaust gas under different operating conditions and its degradation with activated carbon filters was studied. At an energy density of 79.6 J L−1 a maximum ozone molecule flow of (9.02 ± 0.19) × 1018 s−1 was measured which decreases with increasing energy density, because among other possible effects the rising temperature accelerates its decay. One of the activated carbon filters was able to reduce the concentration of toxic ozone by 100% under conditions where a preheated airstream is used.

Graphical abstract: A scalable twin surface dielectric barrier discharge system for pollution remediation at high gas flow rates

Associated articles

Article information

Article type
Paper
Submitted
25 Apr 2022
Accepted
01 Aug 2022
First published
01 Aug 2022

React. Chem. Eng., 2022,7, 2348-2358

A scalable twin surface dielectric barrier discharge system for pollution remediation at high gas flow rates

A. Böddecker, A. Bodnar, L. Schücke, J. Giesekus, K. Wenselau, R. T. Nguyen-Smith, T. Oppotsch, C. Oberste-Beulmann, M. Muhler, A. R. Gibson and P. Awakowicz, React. Chem. Eng., 2022, 7, 2348 DOI: 10.1039/D2RE00167E

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