声波干预下微液滴群微物理变化及其与雷达反射率因子关系研究

doi:10.12118/j.issn.1000-6060.2023.414

Abstract

Abstract:

Through laboratory experiments, the characteristics of microphysical changes of microdroplet clusters under acoustic wave intervention were explored, the relationship between the characteristic particle size of droplet clusters and the radar reflectivity factor was established, and the quantitative relationship between the increment of particle size and the macroscopic rain intensity increment was discussed. The results reveal the following: (1) Optimal acoustic frequencies and critical sound pressure levels are observed. The experiments focused on clusters of drops with 120 Hz acoustic frequencies and exceeding the critical sound pressure level. The acoustic intervention causes the characteristic particle size of the microdroplets to increase, the right shift of the particle size spectrum to widen, the particle number concentration to decrease, and the radar reflectivity factor to increase. This conclusion is also applicable to the 30-280 Hz acoustic wave range. (2) The correlation coefficient of D₉₀-Z is above 0.9, indicating that large particle sizes considerably contribute to the radar reflectivity factor. The fitting parameters a and b are in the ranges of [2.84×10^-8, 1.104] and [0.6713, 9.2000], respectively. (3) The characteristic particle size increment of the droplets is linearly positively correlated with the macroscopic rain intensity increment, with correlation coefficients all above 0.98. In addition, as the sound pressure level increases, the linear slope of the fitting decreases. This study provides a substantial reference and guiding value for evaluating field test effects.

Key words: sound wave, microdroplets, critical sound pressure level, particle size spectrum, radar reflectivity factor

LI Yan, BAI Wenwen. Microphysical changes of droplets and their relationship with radar reflectivity factor under acoustic interference[J].Arid Land Geography, 2024, 47(8): 1388-1398.

Figures/Tables 12

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References 25

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工况	声波情况	粒径谱宽/μm	D₁₀增量 /%	D₅₀增量 /%	D₉₀增量 /%
75 dB	闭	8.424	-0.637	-0.829	-0.959
75 dB	开	8.317	-0.637	-0.829	-0.959
80 dB	闭	8.187	0.049	0.428	0.731
80 dB	开	8.302	0.049	0.428	0.731
85 dB	闭	8.560	0.541	0.708	0.743
85 dB	开	8.640	0.541	0.708	0.743
90 dB	闭	8.342	-0.049	0.497	0.844
90 dB	开	8.485	-0.049	0.497	0.844
95 dB	闭	7.785	0.186	0.049	-0.044
95 dB	开	7.763	0.186	0.049	-0.044
100 dB	闭	7.463	-0.200	-0.411	-0.472
100 dB	开	7.406	-0.200	-0.411	-0.472
105 dB	闭	7.474	1.083	3.082	4.243
105 dB	开	8.045	1.083	3.082	4.243
110 dB	闭	7.596	0.429	7.334	12.406
110 dB	开	9.515	0.429	7.334	12.406
115 dB	闭	8.108	7.605	30.960	48.166
115 dB	开	15.304	7.605	30.960	48.166
120 dB	闭	10.862	34.482	140.696	248.656
120 dB	开	56.213	34.482	140.696	248.656
125 dB	闭	13.079	142.906	217.121	276.333
125 dB	开	61.333	142.906	217.121	276.333

研究变量	函数表达式	相关系数	样本数量
D₁₀-SPL	D₁₀=6.676×10^-12SPL^5.933	0.6938	6
D₅₀-SPL	D₅₀=1.055×10^-15SPL^7.912	0.9105	6
D₉₀-SPL	D₉₀=1.354×10^-17SPL^8.905	0.9550	6
谱宽-SPL	D_谱=3.329×10^-20SPL^10.08	0.9429	6

Microphysical changes of droplets and their relationship with radar reflectivity factor under acoustic interference

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References 25

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