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Theoretical analysis of underwater sound absorption of 0-3 type piezoelectric composite coatings

Yu Li-Gang Li Zhao-Hui Ma Li-Li

Theoretical analysis of underwater sound absorption of 0-3 type piezoelectric composite coatings

Yu Li-Gang, Li Zhao-Hui, Ma Li-Li
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  • Recently piezoelectric shunt damping has attracted a lot of attention in vibration and noise control. In this article, piezoelectric shunt damping is used in underwater sound absorption in order to enhance the sound absorption of the coating. A one-dimensional electro-acoustic model is established for the calculation by combining the equivalent circuit of thickness mode of a piezoelectric composite coating with the transfer matrix of plane wave propagation. This model can be used to calculate the sound absorption of multiple layers of piezoelectric and non-piezoelectric mediums. Underwater sound absorption of the 0-3 type piezoelectric composite coatings is theoretically analyzed. Elastic, piezoelectric and dielectric constants of the 0-3 type piezoelectric composites are calculated by Furukawa's model. Results show that the negative capacitance circuit can adjust the surface acoustic impedance of the piezoelectric composite coating at broadband frequencies. Suitable shunt resistances can make it match the characteristic acoustic impedance of water better. Therefore, the sound absorption can be greatly promoted.
    [1]

    Moheimani S O R, Fleming A J,Behrens S 2003 Smart Mater. Struct. 12 49

    [2]

    Hagood H W, Flotow A van 1994 Journal of Sound and Vibration 146 243

    [3]

    Wu S Y 1996 Proc. SPIE 2720 259

    [4]

    Niederberger D, Fleming A J, Moheimani S O R, Morari M 2004 Smart Mater. Struct. 13 1025

    [5]

    Moheimani S O R 2004 IEEE Transactions on Control Systems Technology 12 484

    [6]

    Guyomar D, Richard T, Richard C 2008 Journal of Intelligent Material Systems and Structure 19 791

    [7]

    Ciminello M, Calabro A, Ameduri S, Concilio A 2008 Journal of Intelligent Material Systems and Structures 19 1089

    [8]

    Neubauer M, Wallaschek J 2008 Smart Mater. Struct. 17 035003

    [9]

    Kim J, Jung Y C 2006 Journal of Acoustical Society of America 120 2017

    [10]

    Marneffe B de, Preumont A 2008 Smart Mater. Struct. 17 035015

    [11]

    Neubauer M, Wallaschek J 2009 IEEE/ASME International Conference on Advanced Intelligent Mechatronics 1100

    [12]

    Xu X R, Chen W, Zhou J 2006 Acta Phys. Sin. 55 4292 (in Chinese) [徐任信, 陈文, 周静 2006 物理学报 55 4292]

    [13]

    Zhang J M, Chang W, Varadan V K, Varadan V V 2001 Smart Mater. Struct. 10 414

    [14]

    Kim J, Lee J 2002 J. Acoust. Soc. Am. 112 990

    [15]

    Kim J, Choi J Y 2005 Smart Mater. Struct. 14 587

    [16]

    Chang D Q, Liu. B L, Li X D 2010 J. Acoust. Soc. Am. 128 639

    [17]

    Furukawa T, Ishida K, Fukada E 1979 J. Appl. Phys. 50 4904

    [18]

    Mason W P 1964 Physical acoustics principles and methods, vol. 1, Part A, Academic Press New York and London 238–239

    [19]

    Luan G D, Zhang J D, Wang R Q 2005 Piezoelectric transducers and arrays (revised edition) (Peking University Press) 114—118 (in Chinese) [栾桂冬, 张金铎, 王仁乾 2005 压电换能器和换能器阵(修订版) (北京大学出版社) 第114-118页]

    [20]

    He Z Y,Wang M 1996 Applied Acoustics 9 12 (in Chinese) [何祚镛, 王曼 1996 应用声学 9 12]

    [21]

    Ma L L, Wang R Q 2006 Technical Acoustics 25(3) 175 (in Chinese) [马黎黎, 王仁乾 2006 声学技术 25(3) 175]

  • [1]

    Moheimani S O R, Fleming A J,Behrens S 2003 Smart Mater. Struct. 12 49

    [2]

    Hagood H W, Flotow A van 1994 Journal of Sound and Vibration 146 243

    [3]

    Wu S Y 1996 Proc. SPIE 2720 259

    [4]

    Niederberger D, Fleming A J, Moheimani S O R, Morari M 2004 Smart Mater. Struct. 13 1025

    [5]

    Moheimani S O R 2004 IEEE Transactions on Control Systems Technology 12 484

    [6]

    Guyomar D, Richard T, Richard C 2008 Journal of Intelligent Material Systems and Structure 19 791

    [7]

    Ciminello M, Calabro A, Ameduri S, Concilio A 2008 Journal of Intelligent Material Systems and Structures 19 1089

    [8]

    Neubauer M, Wallaschek J 2008 Smart Mater. Struct. 17 035003

    [9]

    Kim J, Jung Y C 2006 Journal of Acoustical Society of America 120 2017

    [10]

    Marneffe B de, Preumont A 2008 Smart Mater. Struct. 17 035015

    [11]

    Neubauer M, Wallaschek J 2009 IEEE/ASME International Conference on Advanced Intelligent Mechatronics 1100

    [12]

    Xu X R, Chen W, Zhou J 2006 Acta Phys. Sin. 55 4292 (in Chinese) [徐任信, 陈文, 周静 2006 物理学报 55 4292]

    [13]

    Zhang J M, Chang W, Varadan V K, Varadan V V 2001 Smart Mater. Struct. 10 414

    [14]

    Kim J, Lee J 2002 J. Acoust. Soc. Am. 112 990

    [15]

    Kim J, Choi J Y 2005 Smart Mater. Struct. 14 587

    [16]

    Chang D Q, Liu. B L, Li X D 2010 J. Acoust. Soc. Am. 128 639

    [17]

    Furukawa T, Ishida K, Fukada E 1979 J. Appl. Phys. 50 4904

    [18]

    Mason W P 1964 Physical acoustics principles and methods, vol. 1, Part A, Academic Press New York and London 238–239

    [19]

    Luan G D, Zhang J D, Wang R Q 2005 Piezoelectric transducers and arrays (revised edition) (Peking University Press) 114—118 (in Chinese) [栾桂冬, 张金铎, 王仁乾 2005 压电换能器和换能器阵(修订版) (北京大学出版社) 第114-118页]

    [20]

    He Z Y,Wang M 1996 Applied Acoustics 9 12 (in Chinese) [何祚镛, 王曼 1996 应用声学 9 12]

    [21]

    Ma L L, Wang R Q 2006 Technical Acoustics 25(3) 175 (in Chinese) [马黎黎, 王仁乾 2006 声学技术 25(3) 175]

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Publishing process
  • Received Date:  09 December 2010
  • Accepted Date:  09 May 2011
  • Published Online:  20 January 2012

Theoretical analysis of underwater sound absorption of 0-3 type piezoelectric composite coatings

  • 1. School of Electronic Engineering and Computer Science, Peking University, Beijing 100871, China

Abstract: Recently piezoelectric shunt damping has attracted a lot of attention in vibration and noise control. In this article, piezoelectric shunt damping is used in underwater sound absorption in order to enhance the sound absorption of the coating. A one-dimensional electro-acoustic model is established for the calculation by combining the equivalent circuit of thickness mode of a piezoelectric composite coating with the transfer matrix of plane wave propagation. This model can be used to calculate the sound absorption of multiple layers of piezoelectric and non-piezoelectric mediums. Underwater sound absorption of the 0-3 type piezoelectric composite coatings is theoretically analyzed. Elastic, piezoelectric and dielectric constants of the 0-3 type piezoelectric composites are calculated by Furukawa's model. Results show that the negative capacitance circuit can adjust the surface acoustic impedance of the piezoelectric composite coating at broadband frequencies. Suitable shunt resistances can make it match the characteristic acoustic impedance of water better. Therefore, the sound absorption can be greatly promoted.

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