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2018 Vol.50, Issue 4 Preview Page
Sound Absorption and Sound Transmission Loss of Perforated Corrugated Board

타공골판지의 흡음율과 음향투과손실

Chun-Won Kang
,
Yung-Bum Seo1
강춘원
,
서영범 1
1Dept. of Housing Environmental Design, and Research Institute of Human Ecology, Chonbuk National University, Jeonju
Dept. of Bio-based materials, Chungnam National University, Daejeon
Corresponding author: E-Mail: ybseo@cnu.ac.kr
30 August 2018. pp. 32-39
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Abstract

Sound absorption capability and sound transmission loss of non-perforated and perforated triple A tri-wall corrugated board were estimated by a sound transfer function method. It was found that the cavity which had been formed by perforation behaved as a Helmholtz resonator, single frequency resonator. Mean sound absorption coefficients of non-perforated, and 1.01%, 1.77%, 3.78% and 7.48% of surface area perforated, corrugated board specimens were 0.36, 0.41, 0.41, 0.41 and 0.40, respectively. Especially, in case of 7.48% perforation area of three liner boards (surface and two inner liner boards) perforated all together, sound absorption value reached 100% in the frequency of 1.4 kHz. Mean of sound transmission loss of non-perforated, surface liner layer perforated, and three liner layers perforated board were 17.08 dB, 11.84 dB and 7.55 dB, respectively. The sound transmission loss of the perforated boards were lower than that of non-perforated one. The NRC (noise reduction coefficient) of the perforated corrugated board was about 0.35, which was higher than the NRC (0.3) of 1.1 cm thick commercial gypsum board, and therefore, this board could be used as a sound absorbing board.

Keywords
Corrugated board
sound absorption coefficient
sound transmission loss
sound transfer function method
Helmholtz resonator
perforation
References

Literature Cited

1
C. W. Kang, S. W. Oh, T. B. Lee, W. Kang and J. Matsumura, Journal of Wood Science, Sound absorption capability and mechanical properties of a composite rice hull and sawdust board, 58; 273-278 (2012)

Kang, C. W., Oh, S. W., Lee, T. B., Kang, W., and Matsumura, J., Sound absorption capability and mechanical properties of a composite rice hull and sawdust board, Journal of Wood Science 58:273-278 (2012).

10.1007/s10086-011-1243-5
2
J. S. Kim, International Journal of Air-Conditioning and Refrigeration, Characteristics of sound from construction equipment machinery room, 36(1); 19-25 (2007)

Kim, J. S., Characteristics of sound from construction equipment machinery room, International Journal of Air-Conditioning and Refrigeration 36(1):19-25 (2007).

3
H. Meng, M. A. Galland, M. Ichchou, O. Bareille, F. X. Xin and T. J. Lu, Composite Structures, Small perforations in corrugated sandwich panel significantly enhance low frequency sound absorption and transmission loss, 182; 1-11 (2017)

Meng, H., Galland, M. A., Ichchou, M., Bareille, O., Xin, F. X., and Lu, T. J., Small perforations in corrugated sandwich panel significantly enhance low frequency sound absorption and transmission loss, Composite Structures 182:1-11 (2017).

10.1016/j.compstruct.2017.08.103
4
R. Boonen and P. Sas, Calibration of the two microphone transfer function method to measure acoustical impedance in a wide frequency rangeProceedings of ISMA 2004; 325-333 (2004)

Boonen, R. and Sas, P., Calibration of the two microphone transfer function method to measure acoustical impedance in a wide frequency range, Proceedings of ISMA 2004, pp. 325-333 (2004).

5
A. F. Seybert and D. F. Ross, Journal of the Acoustical Society of America, Experimental determination of acoustic properties using a two-microphone random excitation technique, 61; 1362-1370 (1977)

Seybert, A. F. and Ross, D. F., Experimental determination of acoustic properties using a two-microphone random excitation technique, Journal of the Acoustical Society of America 61:1362-1370 (1977).

10.1121/1.381403
6
ISO 10534-2, Acoustics-Determination of sound absorption coefficient and impedance in impedance tubes - Part 2: Transfer function method

ISO 10534-2, Acoustics-Determination of sound absorption coefficient and impedance in impedance tubes - Part 2: Transfer function method.

7
Korean Industrial Standards, KS F 2814-2, Acoustics-determination of sound absorption coefficient and impedance in impedance tubes - Part 2: Transfer-function method (2002)

Korean Industrial Standards, KS F 2814-2, Acoustics-determination of sound absorption coefficient and impedance in impedance tubes - Part 2: Transfer-function method (2002).

8
D. R. Kim, T. M. Kim and J. T. Kim, A method of transmission loss measurement of mid-frequency on scaled reverberation chamberProceedings of 2015 Spring Conference of the Korean Society for Railway; 1261-1267 (2015)

Kim, D. R., Kim, T. M., and Kim, J. T., A method of transmission loss measurement of mid-frequency on scaled reverberation chamber, Proceedings of 2015 Spring Conference of the Korean Society for Railway, pp. 1261-1267 (2015).

9
D. R. Kim, T. M. Kim, J. T. Kim, G. H. Park and L. O. Ryu, Transactions of the Korean Society of Noise and Vibration Engineering, A study on sensitivity of transmission loss using scaled reverberation chamber, 2015(4); 937-943 (2015)

Kim, D. R., Kim, T. M., Kim, J. T., Park, G. H., and Ryu, L. O., A study on sensitivity of transmission loss using scaled reverberation chamber, Transactions of the Korean Society of Noise and Vibration Engineering 2015(4): 937-943 (2015).

10
Korean Industrial Standards, KS F ISO 10140-2, Acoustics - Laboratory measurement of sound insulation of building elements - Part 2: Measurement of airborne sound insulation (2010)

Korean Industrial Standards, KS F ISO 10140-2, Acoustics - Laboratory measurement of sound insulation of building elements - Part 2: Measurement of airborne sound insulation (2010).

11
J. H. Kook, C. W. Jung, J. H. Yun and J. S. Kim, Transactions of the Korean Society of Noise and Vibration Engineering, Experimental study on wall sound transmission loss at construction equipment machinery room, 2007(3); 695-699 (2007)

Kook, J. H., Jung, C. W., Yun, J. H., and Kim, J. S., Experimental study on wall sound transmission loss at construction equipment machinery room, Transactions of the Korean Society of Noise and Vibration Engineering 2007(3):695-699 (2007).

12
J. H. Lee, B. S. Kim and K. J. Kim, Transactions of the Korean Society of Noise and Vibration Engineering, Study of sound transmission characteristics of using a scale reverberation chamber and vibro acoustic FEM, 2011(10); 92-95 (2011)

Lee, J. H., Kim, B. S., and Kim, K. J., Study of sound transmission characteristics of using a scale reverberation chamber and vibro acoustic FEM, Transactions of the Korean Society of Noise and Vibration Engineering 2011(10):92-95 (2011).

13
S. M. Hwang, J. D. Kim, H. Kwon and Y. S. Seo, International Journal of Naval Architecture and Ocean Engineering, Sound transmission loss through double walls, 50(2); 64-68 (2013)

Hwang, S. M., Kim, J. D., Kwon, H., and Seo, Y. S., Sound transmission loss through double walls, International Journal of Naval Architecture and Ocean Engineering 50(2):64-68 (2013).

Information
  • Publisher :Korea Technical Association of The Pulp and Paper Industry
  • Publisher(Ko) :한국펄프종이공학회
  • Journal Title :Journal of Korea TAPPI
  • Journal Title(Ko) :펄프종이기술
  • Volume : 50
  • No :4
  • Pages :32-39
  • Received Date : 2018-07-16
  • Revised Date : 2018-08-10
  • Accepted Date : 2018-08-13
  • DOI :https://doi.org/10.7584/JKTAPPI.2018.08.50.4.32
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