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Main Authors: Tang, Anthony, Mamishev, Alexander, Novosselov, Igor
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2411.17677
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author Tang, Anthony
Mamishev, Alexander
Novosselov, Igor
author_facet Tang, Anthony
Mamishev, Alexander
Novosselov, Igor
contents Dielectric barrier discharge (DBD) plasma actuators generate an electrohydrodynamic (EHD) force through the ionization and acceleration of charged species. Most active flow control DBD applications are only practical at lower Reynolds numbers, and increasing the momentum injection can extend the practical uses of the technology. Here, we experimentally demonstrate improvement in the performance of a planar DBD actuator by utilizing an AC-augmented electrical field in a three-electrode geometry. Time-resolved electrical and optical measurements, velocity profiles, and direct thrust measurements were used to characterize the EHD augmentation. Varying phase shift and E-field strength between the two air-exposed DBD electrodes can accelerate EHD flow and increase EHD forcing by up to ~ 40%. At the most favorable conditions, the maximum thrust was 54 mN/m when the air-exposed electrodes were out of phase. In-phase operation of the exposed electrodes at high E-field conditions can induce adverse effects and sliding discharge. Mechanistically, the performance improvements in the AC-augmented DBD actuator primarily come from the additional charge pull action by the third electrode. The insight into the AC-augmented DBD mechanism allows for developing multi-stage arrays capable of further increasing EHD forces.
format Preprint
id arxiv_https___arxiv_org_abs_2411_17677
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle AC-Augmented Dielectric Barrier Discharge
Tang, Anthony
Mamishev, Alexander
Novosselov, Igor
Plasma Physics
Dielectric barrier discharge (DBD) plasma actuators generate an electrohydrodynamic (EHD) force through the ionization and acceleration of charged species. Most active flow control DBD applications are only practical at lower Reynolds numbers, and increasing the momentum injection can extend the practical uses of the technology. Here, we experimentally demonstrate improvement in the performance of a planar DBD actuator by utilizing an AC-augmented electrical field in a three-electrode geometry. Time-resolved electrical and optical measurements, velocity profiles, and direct thrust measurements were used to characterize the EHD augmentation. Varying phase shift and E-field strength between the two air-exposed DBD electrodes can accelerate EHD flow and increase EHD forcing by up to ~ 40%. At the most favorable conditions, the maximum thrust was 54 mN/m when the air-exposed electrodes were out of phase. In-phase operation of the exposed electrodes at high E-field conditions can induce adverse effects and sliding discharge. Mechanistically, the performance improvements in the AC-augmented DBD actuator primarily come from the additional charge pull action by the third electrode. The insight into the AC-augmented DBD mechanism allows for developing multi-stage arrays capable of further increasing EHD forces.
title AC-Augmented Dielectric Barrier Discharge
topic Plasma Physics
url https://arxiv.org/abs/2411.17677