风的噪音从a柱和侧视镜的现实通用汽车模型，司机

Q4 Engineering

International Journal of Vehicle Noise and Vibration Pub Date : 2018-07-09 DOI:10.1504/IJVNV.2018.10014188

Mohamed Sukri Mat Ali, J. Jalasabri, A. M. Sood, S. Mansor, Haziqah Shaharuddin, Sallehuddin Muhamad

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引用次数: 4

摘要

生产汽车的内部噪音主要来自发动机、轮胎和空气动力学。在高速行驶时，风噪声会主导整个内部噪声。风噪声与气流的不稳定性有关。对于大多数生产汽车来说，A柱和侧视镜是观察到高度分离和湍流的区域。本研究量化了A柱和侧视镜的风噪声对通用逼真模型DrivAer内部噪声的贡献。噪声源是基于非定常雷诺平均Navier-stokes（URNS）从流-结构相互作用中获得的，而噪声传播是使用Lighthill声学类比的Curle方程估计的。内部噪声的声压频谱是通过使用传输损耗的质量定律来考虑来自侧玻璃的声音传输损耗而获得的。研究发现，在整个频率范围内，A柱发出的噪音高于侧视镜发出的噪音。A柱部件末端附近的辐射噪声水平最高，比A柱前部的辐射噪声高出20 dB。

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Wind noise from A-pillar and side view mirror of a realistic generic car model, DriAver

Interior noise of a production car is a total contribution mainly from engine, tyres and aerodynamics. At high speed, wind noise can dominate the total interior noise. Wind noise is associated with the unsteadiness of the flow. For most production cars, A-pillar and side view mirror are the regions where the highly separated and turbulent flows are observed. This study quantifies the wind noise contribution from A-pillar and side view mirror with respect to the interior noise of a generic realistic model, DrivAer. The noise sources are obtained numerically from the flow-structure interactions based on the unsteady Reynolds averaged Navier stokes (URANS) while the noise propagation is estimated using Curle's equation of Lighthill acoustic analogy. The sound pressure frequency spectrum of the interior noise is obtained by considering the sound transmission loss from the side glass by using the mass law for transmission loss. The study found that the noise from the A-pillar is higher than the noise from the side view mirror in the whole frequency range. Near the end of the A-pillar component contributes the highest radiated noise level with up to 20 dB louder than that at the front part of the A-pillar.

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来源期刊

International Journal of Vehicle Noise and Vibration Engineering-Automotive Engineering

CiteScore

0.90

自引率

0.00%

发文量

期刊介绍： The IJVNV has been established as an international authoritative reference in the field. It publishes refereed papers that address vehicle noise and vibration from the perspectives of customers, engineers and manufacturing.