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2024 Vol.43, Issue 5 Preview Page

Research Article

Low-frequency noise reduction in a built-in refrigerator utilizing perforated plate system

다공판 시스템을 이용한 빌트인 냉장고 저주파 소음 저감

HyoungJin Kim1
,
JeongHyun Shin1
,
KyungJun Song1*
,
Tae-Hoon Kim2
,
JunHyo Koo2
김 형진1
,
신 정현1
,
송 경준1*
,
김 태훈2
,
구 준효2
1부산대학교
2LG전자
*Corresponding Author
30 September 2024. pp. 584-591
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Abstract

This paper investigates the reduction of low-frequency noise emitted from the machine room of a built-in refrigerator using perforated plate system composed of perforated panels and sound-absorbing materials. The study employs theoretical methods, Finite Element Analysis (FEA), and impedance tube experiments to compare and analyze absorption characteristics across different shapes of perforated panels, aiming to propose an optimal configuration. Simulation of radiated sound power levels demonstrates a decrease in the low-frequency band of the Sound Power Level (PWL) upon implementing perforated plate system. Experimental noise tests conducted in a semi-anechoic chamber validate the effectiveness of the perforated plate system.

Keywords
Perforated plate system
Acoustic impedance
2-microphone transfer-function method
Radiated acoustic power level

본 논문은 빌트인 냉장고의 기계실에서 발생하는 저주파 소음을 감소하기 위해 다공판과 흡음재를 이용한 다공판 시스템을 제작 및 설치하여 소음을 개선하는 연구이다. 다공판의 형상 변화를 통해 다공판 시스템의 흡음 대역을 이론적 방법, Finite Element Analysis(FEA), 임피던스 튜브 실험적 방법을 통해 비교 분석하여 최적 형상을 제시하였다. 방사음향파워레벨 시뮬레이션을 통해 다공판 시스템의 설치에 따른 저주파 대역의 Sound Power Level(PWL)이 감소함을 볼 수 있었으며, 반무향실에서의 소음 실험을 통해 다공판 시스템의 효과를 검증하였다.

키워드
다공판 시스템
음향 임피던스
2-microphone transfer-function method
방사음향파워레벨
References
1

J. E. Oh, C. H. Lee, M. R. Lee, and S. H. Yum, "A study on the noise source identification of refrigerator compressor" (in Korean), J. Acoust. Soc. Kr. 6, 48-57 (1987).

2

C. B. Neto, C. Melo, A. Lenzi, and ALG Caetano, "Noise generation in household refrigerators," Proc. 15th IRCC, 1371 (2014).

3

Y. G. Lee and W. J. Kim, "An experimental investigation into the mechanism of the refrigerator contraction -expansion noise" (in Korean), J. Acoust. Soc. Kr. 41, 389-396 (2022).

4

S. S. Son, J. Y. Seo, B. Y. Lee, and W. J. Kim, "A study on the structure-borne noise reduction of refrigerators using taguchi method" (in Korean), Trans. Korean Soc. Noise Vib. Eng. 20, 470-476 (2010).

10.5050/KSNVE.2010.20.5.470
5

Y. Birari and M. Nadgouda, "Noise reduction of a reciprocating compressor by adding a resonator in suction path of refrigerant," Proc. 14th ICSV, 641-648 (2007)

6

K. Y. An, H. J. Kwon, J. Y. Jang, and K. J. Song, "Acoustic metamaterial design for noise reduction in vacuum cleaner," J. Mech. Sci. Technol. 36, 5353-5362 (2022).

10.1007/s12206-022-1002-0
7

D.-Y. Maa, "Microperforated-panel wideband absorbers," Noise Control Eng. J. 29, 77-84 (1987).

10.3397/1.2827694
8

D.-Y. Maa, "Potential of microperforated panel absorber," J. Acoust. Soc. Am. 104, 2861-2866 (1998).

10.1121/1.423870
9

B. K. Hong, H. Y. Song, S. W. Seo, and D. H. Lee, "A study on the sound absorptive characteristics and performance of parallel perforated plate systems" (in Korean), Trans. Korean Soc. Noise Vib. Eng. 15, 1003-1008 (2005).

10.5050/KSNVN.2005.15.9.1003
10

S. H. Park and S. H. Seo, "Absorption characteristics of micro-perforated panel absorber according to incident pressure magnitude and its geometric parameters" (in Korean), Proc. Trans. Korean Soc. Noise Vib. Eng. 178-185 (2011).

11

R. Tayong, "Effects of unevenly distributed holes on the perforated plate sound absorption coefficient," Noise Control Eng. J. 61, 547-552 (2013).

10.3397/1/3761048
12

Lord Rayleigh, Theory of Sound II (MacMillan, New York, 1929), pp. 327.

13

I. B. Crandall, Theory of Vibration System and Sound (Van Nostrand, New York, 1926), pp. 229.

14

C. Zwikker and C. W. Kosten, Sound Absorbing Materials (Elsevier Publishing, New York, 1949), pp. 25.

15

K. Attenborough, "On the acoustic slow wave in air filled granular media," J. Acoust. Soc. Am. 81, 93-102 (1987).

10.1121/1.394938
16

K. Wilson, "Relaxation-matched modeling of propagation through porous media, including fractal pore structure," J. Acoust. Soc. Am. 94, 1136-1145 (1993).

10.1121/1.406961
17

D. L. Johnson, J. Koplik, and R. Dashen, "Theory of dynamic permeability and tortuosity in fluid-saturated porous media," J. Fluid Mech. 176, 379-402 (1987).

10.1017/S0022112087000727
18

ISO 10534-2, Acoustics - Determination of Acoustic Properties in Impedance Tubes - Part 2: Two- MicroPhone Technique of Normal Sound Absorption CoeffiCient and Normal Surface Impedance, 2023.

19

ASTM E1050-19, Standard Test Method for Impedance and Absorption of Acoustical Materials using a Tube, Two Microphones and a Digital Frequency Analysis System, 2019.

Information
  • Publisher :The Acoustical Society of Korea
  • Publisher(Ko) :한국음향학회
  • Journal Title :The Journal of the Acoustical Society of Korea
  • Journal Title(Ko) :한국음향학회지
  • Volume : 43
  • No :5
  • Pages :584-591
  • Received Date : 2024-07-30
  • Revised Date : 2024-09-05
  • Accepted Date : 2024-09-21
  • DOI :https://doi.org/10.7776/ASK.2024.43.5.584
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