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Design Optimization of the Resonance Frequency of a High Sound Pressure Resonant Coupled Tube
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摘要: 谐振耦合管法产生的声压源具有高声压级、低失真的特点,通常用于高声压传声器在固定频率下的线性度校准。基于声学有限元模型,分析了谐振耦合管的特征频率和频率响应,优化了谐振耦合管的设计,其共振基频的实验值与计算值相差0.8 Hz,500 Hz谐振耦合管实现的声压级可到174 dB,总谐波失真为0.5%。Abstract: The sound pressure source generated by the resonant coupled tube method has a high sound pressure level with a low distortion. It is usually used for the calibration of level linearity and distortion of high sound pressure microphones at a fixed frequency. Based on the acoustic finite element model, this paper analyzes the characteristic frequency and frequency response of a resonant coupled tube, and optimizes the design of the tube. The experimental value of the resonant fundamental frequency differed from the calculated value by 0.8 Hz. The resonant coupled tube at 500 Hz generated a sound pressure level of 174 dB with a total harmonic distortion of 0.5%.
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Key words:
- high sound pressure /
- resonant coupled tube /
- finite element analysis /
- frequency design
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图 6 优化设计后谐振耦合管的频率响应
Figure 6. Frequency response of the optimized resonant coupled tube
图 7 基于谐振耦合管法的高声压源系统实物图
Figure 7. Photo of the system of the high sound pressure source based on the resonant coupled tube method
图 8 500 Hz耦合管管末端声压的频率响应曲线
Figure 8. Frequency response curve obtained at the end of the 500 Hz coupled tube
表 1 谐振耦合管的特征频率
Table 1. Characteristic frequency of the resonant coupled tube
Hz 一阶 二阶 三阶 四阶 五阶 500.8 624.9 1140.1 1622.5 1752.1 
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表 2 谐振频率实验值和计算值的对照
Table 2. Comparison of experimental and calculated resonant frequencies
Hz 一阶 二阶 三阶 计算 500.8 624.9 1140.1 实验 500.0 625.0 1165.0 $\left| \varDelta \right|$ 0.8 0.1 24.9
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表 3 T2管顶部在不同声压级下的测试结果
Table 3. Test results at different sound pressure levels at the top end of the tube T2
声压级/dB THD/% 声压级/dB THD/% 114 0.21 167 0.20 124 0.06 168 0.25 134 0.02 169 0.41 144 0.01 170 0.39 154 0.04 171 0.37 164 0.14 172 0.37 165 0.15 173 0.39 166 0.17 174 0.45
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