Plasma Sheet Actuator Driven by Repetitive Nanosecond Pulses with a Negative DC Component 被引量：2

Plasma Sheet Actuator Driven by Repetitive Nanosecond Pulses with a Negative DC Component

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摘要 A type of electrical discharge called sliding discharge was developed to generate plasma aerodynamic actuation for flow control. A three-electrode plasma sheet actuator driven by repetitive nanosecond pulses with a negative DC component was used to generate sliding discharge, which can be called nanosecond-pulse sliding discharge. The phenomenology and behaviour of the plasma sheet actuator were investigated experimentally. Discharge morphology shows that the formation of nanosecond-pulse sliding discharge is dependent on the peak value of the repetitive nanosecond pulses and negative DC component applied on the plasma sheet actuator. Compared to dielectric barrier discharge （DBD）, the extension of plasma in nanosecond-pulse sliding discharge is quasi-diffusive, stable, longer and more intensive. Test results of particle image velocimetry demonstrate that the negative DC component applied to a third electrode could significantly modify the topology of the flow induced by nanosecond-pulse DBD. Body force induced by the nanosecond-pulse sliding discharge can be approximately in the order of mN. Both the maximum velocity and the body force induced by sliding discharge increase significantly as compared to single DBD. Therefore, nanosecond-pulse sliding discharge is a preferable plasma aerodynamic actuation generation mode, which is very promising in the field of aerodynamics. A type of electrical discharge called sliding discharge was developed to generate plasma aerodynamic actuation for flow control. A three-electrode plasma sheet actuator driven by repetitive nanosecond pulses with a negative DC component was used to generate sliding discharge, which can be called nanosecond-pulse sliding discharge. The phenomenology and behaviour of the plasma sheet actuator were investigated experimentally. Discharge morphology shows that the formation of nanosecond-pulse sliding discharge is dependent on the peak value of the repetitive nanosecond pulses and negative DC component applied on the plasma sheet actuator. Compared to dielectric barrier discharge （DBD）, the extension of plasma in nanosecond-pulse sliding discharge is quasi-diffusive, stable, longer and more intensive. Test results of particle image velocimetry demonstrate that the negative DC component applied to a third electrode could significantly modify the topology of the flow induced by nanosecond-pulse DBD. Body force induced by the nanosecond-pulse sliding discharge can be approximately in the order of mN. Both the maximum velocity and the body force induced by sliding discharge increase significantly as compared to single DBD. Therefore, nanosecond-pulse sliding discharge is a preferable plasma aerodynamic actuation generation mode, which is very promising in the field of aerodynamics.

作者宋慧敏张乔根李应红贾敏吴云梁华

机构地区 Science and Technology on Plasma Dynamics Laboratory State Key Laboratory of Electrical Insulation and Power Equipment

出处《Plasma Science and Technology》 SCIE EI CAS CSCD 2012年第4期327-332,共6页 等离子体科学和技术（英文版）

基金 supported by National Natural Science Foundation of China (No. 51007095) the Natural Science Foundation of Shaanxi Province of China (No. 2010JQ1012)

关键词 nanosecond-pulse discharge plasma aerodynamic actuation sliding discharge plasma sheet actuator nanosecond-pulse discharge, plasma aerodynamic actuation, sliding discharge,plasma sheet actuator

分类号 O53 [理学—等离子体物理]

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参考文献21

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Plasma Sheet Actuator Driven by Repetitive Nanosecond Pulses with a Negative DC Component 被引量：2

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