The characteristics and design of a high-bandwidth flow sensor that uses an AC glow discharge (plasma) as the sensing element is presented. The plasma forms in the air gap between two protruding low profile electrodes attached to a probe body. The output from the anemometer is an amplitude modulated version of the AC voltage input that contains information about the mean and uctuating velocity components. The anemometer circuitry includes resistance and capacitance elements that simulate a dielectric-barrier to maintain a diffuse plasma, and a constant-current feedback control that maintains operation within the desired glow discharge regime over an extended range of air velocities. Mean velocity calibrations are demonstrated over a range from 0 to 140 m/s. Over this velocity range, the mean output voltage varied linearly with air velocity, providing a constant static sensitivity. The effect of the electrode gap and input AC carrier frequency on the anemometer static sensitivity and dynamic response are investigated. Experiments are performed to compare measurements obtained with a plasma sensor operating at two AC carrier frequencies against that of a constant-temperature hot-wire. All three sensors were calibrated against the same known velocity reference. An uncertainty based on the standard deviation of the velocity calibration fit was applied to the mean and fluctuating velocity measurements of the three sensors. The motivation is not to replace hot-wires as a general measurement tool, but rather as an alternative to hot-wires in harsh environments or at high Mach numbers where they either have di&;The characteristics and design of a high-bandwidth pressure sensor that uses an AC glow discharge (plasma) as the sensing element is also presented. A dielectric barrier was utilized between two electrodes with plasma forming at its surface. As with the plasma anemometer, the output from the plasma pressure sensor is an am- plitude modulated version of the AC voltage input that contains information about the mean and uctuating pressure components. Static pressure calibration was performed to approximately 4 bar. The static calibration followed a power-law relation. AC carrier frequency and electrode length are investigated with respect to their effect on static sensitivity. The static sensitivity increased with increasing electrode length which produced a larger volume of plasma. The power-law exponent increased with increasing AC frequency, thereby, becoming more nonlinear. Shock tube exper- iments were conducted to determine the factors involved in frequency response of the plasma sensor. The dielectric thickness, electrode length, and AC carrier frequency were varied. The frequency response was maximized with the thinnest dielectric layer, moderate electrode (plasma) length, and the highest AC carrier frequency. Under these conditions the plasma pressure sensor performed as well as a high frequency response commercial pressure transducer.
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机译:介绍了使用交流辉光放电(等离子)作为传感元件的高带宽流量传感器的特性和设计。等离子体在连接到探头主体的两个突出的薄型电极之间的气隙中形成。风速表的输出是交流电压输入的调幅形式,其中包含有关平均值和驱动速度分量的信息。风速仪电路包括模拟介电势垒以维持扩散等离子体的电阻和电容元件,以及在扩展的风速范围内将操作保持在所需辉光放电范围内的恒定电流反馈控制。在0至140 m / s的范围内证明了平均速度校准。在此速度范围内,平均输出电压随空气速度线性变化,从而提供恒定的静态灵敏度。研究了电极间隙和输入交流载波频率对风速仪静态灵敏度和动态响应的影响。进行实验以将在两个交流载波频率下工作的等离子传感器的测量结果与恒温热线的测量结果进行比较。所有三个传感器都针对相同的已知速度基准进行了校准。将基于速度校准拟合的标准偏差的不确定性应用于三个传感器的平均值和脉动速度测量值。其动机不是要取代热线作为一般的测量工具,而是要在恶劣的环境中或马赫数高,热电势差的情况下替代热线;高带宽压力传感器的特性和设计可以还介绍了使用AC辉光放电(等离子)作为传感元件。在两个电极之间利用电介质阻挡层,并在其表面形成等离子体。与等离子风速计一样,等离子压力传感器的输出是交流电压输入的幅度调制版本,其中包含有关平均值和工作压力分量的信息。进行静压校准至大约4 bar。静态校准遵循幂律关系。研究了交流载频和电极长度对静态灵敏度的影响。静电灵敏度随电极长度的增加而增加,从而产生更大的等离子体体积。幂律指数随交流频率的增加而增加,从而变得更加非线性。进行了激波管实验,以确定涉及等离子体传感器频率响应的因素。电介质厚度,电极长度和AC载频变化。通过最薄的介电层,适中的电极(等离子)长度和最高的AC载波频率,可以使频率响应最大化。在这些条件下,等离子压力传感器的性能与高频响应商用压力传感器相同。
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