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¿ ƒ ½ ¨ 7 Hë H À Sae Mulli (The Korean Physical Society), Volume 59, Number 4, 2009¸ 10 Z 4, pp. 343∼348

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Fig. 1. Wind speed measurement system (wind tunnel).

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Fig. 2. Microphone set-up methods to wind direction.

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Fig. 4. 1/3-octave band sound pressure level difference between the sound pressure level with and without wind- screen for perpendicular wind direction to the micro- phone.

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Fig. 6. Background sound pressure level with and with-

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Fig. 7. Sound pressure level with and without wind- screens: (a) perpendicular wind direction to the micro- phone and (b) parallel wind direction to the microphone.

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Fig. 9. Sound pressure level difference between sound pressure level with and without windscreen by varying wind speeds for the perpendicular wind direction to the microphone.

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[1] R. N. Hosier and P. R. Donavan, Nat. Bur. Stand.

Rep. NBSIR 79, 1599 (1979).

[2] H. Imaizumi and Y. Takahashi, Proceedings of low frequency noise 2008 (Tokyo, Japan, 2008) 343 [3] R. J. Peppin, Canadian Acoustics 31, 25 (2003).

[4] V. Bruel, Technical Review No. 2 (1960).

(6)

Evaluation of the Acoustical Characteristics of a Windscreen for Various Wind Speeds

Sung Soo Jung,

Byeong-Su Jeon, Jae Gap Seo and Sejong Chun

Center for Fluid Flow and Acoustics, Korea Research Institute of Standards and Science, Daejeon 305-340 (Received 27 July 2009, in final form 4 September 2009)

The acoustical characteristics of a windscreen which has been used to reduce unwanted wind noise have been measured and analyzed by varying the wind speed in a wind tunnel and a reverberation room. The results show that the wind tunnel method is rarely applicable because of the many duct resonance modes whereas the reverberation room method is stable. The effects of wind noise are mainly observed in the low frequency range( i.e, <1000 Hz) rather than in the high frequency range.

A windscreen having a diameter of 9 cm was shown to effectively reduce the wind noise for a wind speeds up to 6.6 m/s.

PACS numbers: 43.20.Mv, 43.28.Vd

Keywords: Windscreen, Wind tunnel, Reverberation room, Sound pressure level difference

E-mail: [email protected]

수치

Fig. 1. Wind speed measurement system (wind tunnel).
Fig. 3. Sound pressure level spectrun measured in the wind tunnel: (a) with windscreen and (b) without wind-screen
Fig. 4. 1/3-octave band sound pressure level difference between the sound pressure level with and without wind-screen for perpendicular wind direction to the micro-phone
Fig. 7. Sound pressure level with and without wind- wind-screens: (a) perpendicular wind direction to the micro-phone and (b) parallel wind direction to the micromicro-phone.
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