The effects of actuation frequency and actuation voltage generated by nanosecond pulse dielectric barrier discharge plasma on the flow control effects of a delta wing are investigated with different wind speeds by means of force-balance tests in the wind tunnel, the plasma actuator is installed on the delta wing. The force test results show that, actuation frequency and actuation voltage determines flow control effectivity, when the actuation frequency is 200Hz and actuation voltage 13kV, nanosecond pulse dielectric barrier discharge plasma inhibits the leading-edge vortices separation obviously, and the flow control effect may achieves the best . For the case of wind speed of 30m/s, the maximum lift coefficient increases 9.8% from 1.32 to 1.45, the maximum lift-drag ratio increases 2.9%. For wind speed of 45 m/s, the maximum lift coefficient increases up to 11.2% from 1.30 to 1.45, and the maximum lift-drag ratio 0.64%%在不同试验风速下,通过风洞天平测力试验,研究了纳秒脉冲介质阻挡放电等离子体激励频率和激励电压对三角翼模型流动控制效果的影响.研究表明;激励频率和激励电压是等离子体流动控制效果的重要影响因素,在所研究的激励频率和激励电压范围中,当激励频率f=200Hz、激励电压为13kV时,等离子体激励可有效抑制三角翼前缘涡分离,流动控制效果最佳.试验风速30m/s时,最大升力系数由1.32增大到1.45,增大9.8%,最大升阻比提高2.9%;试验风速45m/s时,最大升力系数由1.33增大到1.45,增大9.0%,最大升阻比提高0.64%.
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