微穿孔板几何参数估算及其对吸声性能的影响
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摘要
不规则孔微穿孔板几何参数无法直接获知,造成吸声性能计算困难,故提出一种微穿孔板几何参数估算方法。将不规则孔等效处理为圆孔,利用马氏理论关于圆孔微穿孔板的基本理论,建立了微穿孔板几何参数估算模型;将参数估算结果用于吸声性能预测,理论计算与实验结果吻合。根据微穿孔板几何参数对高吸声性能区域的影响,探讨了马氏理论适用极限与微穿孔板几何参数的关系,以及微穿孔板受粉尘污染后吸声性能演变规律。将微穿孔板参数点取在面积较大的高吸声性能区域中间部位,可获得较大的马氏理论适用极限;微穿孔板参数点位于高吸声性能区域右上部位时,一定程度的粉尘污染不会降低吸声性能.
The geometric parameters of micro-perforated panels with irregular holes cannot be directly known, making it difficult to calculate the sound absorption performance. Therefore, a method of estimating the geometric parameters of micro-perforated panels is proposed. The irregular holes are treated as equivalent circular ones, and the model of estimating the geometric parameters is established by using Maa's theory about the panel with circular holes. The result of the parameter estimation of a type of micro-perforated panel is used to predict the absorption performance,resulting in good agreement with experiments. According to the influence of the geometric parameters of the panel on the high absorption area, the relationship between the application limit of Maa's theory and the geometric parameters is discussed, and the evolution law of the sound absorption performance of the panel polluted by dust is investigated. When the parameters of the panel are designed near the center of the high absorption region, large value of the application limit of Maa's theory can be obtained; and if the parameters are located in the upper right part of the high absorption area, a certain degree of dust pollution of the panel does not reduce the sound absorption performance.
The geometric parameters of micro-perforated panels with irregular holes cannot be directly known, making it difficult to calculate the sound absorption performance. Therefore, a method of estimating the geometric parameters of micro-perforated panels is proposed. The irregular holes are treated as equivalent circular ones, and the model of estimating the geometric parameters is established by using Maa's theory about the panel with circular holes. The result of the parameter estimation of a type of micro-perforated panel is used to predict the absorption performance,resulting in good agreement with experiments. According to the influence of the geometric parameters of the panel on the high absorption area, the relationship between the application limit of Maa's theory and the geometric parameters is discussed, and the evolution law of the sound absorption performance of the panel polluted by dust is investigated. When the parameters of the panel are designed near the center of the high absorption region, large value of the application limit of Maa's theory can be obtained; and if the parameters are located in the upper right part of the high absorption area, a certain degree of dust pollution of the panel does not reduce the sound absorption performance.
引文
1马大猷.微穿孔板吸声结构的理论和设计.中国科学,1975;18(1):38-50
2马大猷.微穿孔板吸声体的准确理论和设计.声学学报,1997;22(5):385-393
3 Maa D Y. Microperforated-panel wideband absorbers.Noise Control Eng. J. 1997; 29(3):77-84
4 Maa D Y. Potential of microperforated panel absorbers. J.Acoust. Soc. Am., 1998; 104(5):2861-2866
5马大猷.微穿孔板的实际极限.声学学报,2006; 31(6):481-484
6 Fuchs H V, Zha X. Acrylic-Glass sound absorbers in the plenum of the Deutscher Bundestag. Appl. Acoust., 1997;51:211-217
7查雪琴,康健,张婷,周晓儒,Fuchs H.微穿孔板的运用技术.声学学报,1994; 19(4):258-265
8彭玉才,王兴革,魏吉明.变腔深双层微穿孔板消声器的研究.哈尔滨工业大学学报,1990; 12:89-93
9闵鹤群,郭文成.具有并联不等深度子背腔序列的微穿孔板吸声体吸声性能.东南大学学报(自然科学版),2017; 47(1):177-183
10赵晓丹,李晓,丁瑞.机械阻抗与声阻抗结合提高微穿孔板低频吸声性能.声学学报,2014; 39(3):360-364
11赵晓丹,丁瑞,胡鹏.运用弹性支撑背板提高微穿孔板低频吸声性能.江苏大学学报(自然科学版),2012; 33(5):567-570
12 Herrin D W, Liu J, Seybert A F. Properties and applications of microperforated panels. Sound Vib., 2011; 45(7):6-9
13 Liu J, Hua X, Herrin D W. Estimation of effective parameters for microperforated panel absorbers and applications.Appl. Acoust., 2014; 75:86-93
14 Rayleigh L. Theory of sound. New York:Macmillan, 1929:327
15 Crandall I B. Theory of vibrating systems and sound. New York:D. Van Nostrand&Co. Inc., 1926:229-241
16 ASTM Standard E 1050-98. Standard test method for impedance and absorption of acoustical materials using a tube, two microphones and a digital frequency analysis system. American Society for Testing and Materials. West Conshohocken, 1998
17钱玉洁,崔珂,刘淑梅,刘友江,孙少明.加工误差对马氏理论关于超微孔微穿孔板吸声结构适用性的影响.声学学报,2014;39(2):235-242
2马大猷.微穿孔板吸声体的准确理论和设计.声学学报,1997;22(5):385-393
3 Maa D Y. Microperforated-panel wideband absorbers.Noise Control Eng. J. 1997; 29(3):77-84
4 Maa D Y. Potential of microperforated panel absorbers. J.Acoust. Soc. Am., 1998; 104(5):2861-2866
5马大猷.微穿孔板的实际极限.声学学报,2006; 31(6):481-484
6 Fuchs H V, Zha X. Acrylic-Glass sound absorbers in the plenum of the Deutscher Bundestag. Appl. Acoust., 1997;51:211-217
7查雪琴,康健,张婷,周晓儒,Fuchs H.微穿孔板的运用技术.声学学报,1994; 19(4):258-265
8彭玉才,王兴革,魏吉明.变腔深双层微穿孔板消声器的研究.哈尔滨工业大学学报,1990; 12:89-93
9闵鹤群,郭文成.具有并联不等深度子背腔序列的微穿孔板吸声体吸声性能.东南大学学报(自然科学版),2017; 47(1):177-183
10赵晓丹,李晓,丁瑞.机械阻抗与声阻抗结合提高微穿孔板低频吸声性能.声学学报,2014; 39(3):360-364
11赵晓丹,丁瑞,胡鹏.运用弹性支撑背板提高微穿孔板低频吸声性能.江苏大学学报(自然科学版),2012; 33(5):567-570
12 Herrin D W, Liu J, Seybert A F. Properties and applications of microperforated panels. Sound Vib., 2011; 45(7):6-9
13 Liu J, Hua X, Herrin D W. Estimation of effective parameters for microperforated panel absorbers and applications.Appl. Acoust., 2014; 75:86-93
14 Rayleigh L. Theory of sound. New York:Macmillan, 1929:327
15 Crandall I B. Theory of vibrating systems and sound. New York:D. Van Nostrand&Co. Inc., 1926:229-241
16 ASTM Standard E 1050-98. Standard test method for impedance and absorption of acoustical materials using a tube, two microphones and a digital frequency analysis system. American Society for Testing and Materials. West Conshohocken, 1998
17钱玉洁,崔珂,刘淑梅,刘友江,孙少明.加工误差对马氏理论关于超微孔微穿孔板吸声结构适用性的影响.声学学报,2014;39(2):235-242
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