汽车后视镜与雨刮的风噪优化*

doi:10.19562/j.chinasae.qcgc.2018.012.014

汽车工程 ›› 2018, Vol. 40 ›› Issue (12): 1475-1479.doi: 10.19562/j.chinasae.qcgc.2018.012.014

汽车后视镜与雨刮的风噪优化^*

侯兆平¹, 付年¹, 黄元毅¹, 徐铁¹, 陈瑞锋², 沈艳涛²

1.上汽通用五菱汽车股份有限公司技术中心,柳州 545007;
2.上海海基盛元信息科技有限公司,上海 200235

收稿日期:2017-08-23 出版日期:2018-12-25 发布日期:2018-12-25
通讯作者: 陈瑞锋,工程师,博士,E-mail:chenrf@hikeytech.com
基金资助:
八桂学者科研项目资助

An Optimization of Vehicle Rear-view Mirror and Wiper Wind Noise

Hou Zhaoping¹, Fu Nian¹, Huang Yuanyi¹, Xu Tie¹, Chen Ruifeng², Shen Yantao²

1. Shanghai General Motors Wuling Technical Design Center, Liuzhou 545007;
2.Shanghai Hikey-Sheenray Information Technology Corp., Ltd., Shanghai 200235

Received:2017-08-23 Online:2018-12-25 Published:2018-12-25

摘要/Abstract

摘要： 为得到某SUV的车内噪声,分别采用计算流体力学法和统计能量法对该车型进行外部流场和乘坐舱内噪声计算,获得驾驶员头部区域的声压级曲线。在原车仿真结果基础上,对后视镜和雨刮进行改进,并采用数值仿真和道路试验对原车和改进后的噪声进行评估和对比。仿真和试验得到的声压级曲线整体趋势一致,表明仿真结果的有效性;后视镜和雨刮改进后,仿真结果显示两种改进方案的噪声,在全频段均有改善,其中声压级最大降幅达5.6dB(A),两种方案的总声压级分别降低1.5和1.8dB(A);路试结果显示在干扰噪声较小的高频段,改进后的声压级有较明显的降低,部分高频段最大降幅达5.1dB(A),两种方案的总声压级分别降低0.2和0.7dB(A),表明了改进的有效性和研究方法的可行性。

关键词: 后视镜, 雨刮, 风噪优化, 数值仿真, 道路试验

Abstract: The external flow field and the interior noise of the passenger compartment of a SUV are calculated by computational fluid dynamics and statistical energy method respectively, and the sound pressure level (SPL) curve at drivers head region is obtained. Based on the simulation results of original vehicle model, rear view mirror and wiper are modified, and the noise evaluation and comparison between before and after modifications are carried out by numerical simulation and road test. The SPL curves obtained by simulation and road test have the same overall tendency, showing the effectiveness of simulation results. The results of simulation indicate that both rear-view mirror and wiper modification schemes have noise reduction effects in full frequency range, in which the maximum reduction amplitude in SPL reaches 5.6dB(A) and the total SPL with both schemes reduce by 1.5 and 1.8dB(A) respectively. The results of road test show that in high frequency segment with relatively low noise, the SPL after modification has apparent fall, with the maximum reduction amplitude reaching 5.1dB(A) in some high-frequency band. And the total SPL with both modification schemes reduce by 0.2 and 0.7dB(A) respectively, demonstrating the effectiveness of modifications and the feasibility of study method.

Key words: rear view mirror, wiper, wind noise optimization, numerical simulation, road test

侯兆平, 付年, 黄元毅, 徐铁, 陈瑞锋, 沈艳涛. 汽车后视镜与雨刮的风噪优化^*[J]. 汽车工程, 2018, 40(12): 1475-1479.

Hou Zhaoping, Fu Nian, Huang Yuanyi, Xu Tie, Chen Ruifeng, Shen Yantao. An Optimization of Vehicle Rear-view Mirror and Wiper Wind Noise[J]. , 2018, 40(12): 1475-1479.

参考文献

[1] 庞剑.汽车车身噪声与振动控制[M].北京:机械工业出版社,2015.
[2] 李启良.汽车后视镜非定常流动与气动噪声研究[D].上海:同济大学,2010.
[3] 洪四华,丁能根,吴阳年.某SUV后视镜气动噪声模拟研究[J].车辆与动力技术,2007(4):39-42.
[4] 王标亮,刘波,桑建兵.汽车后视镜气流噪声的数值计算和实验研究[J].机械强度,2008,30(4):692-695.
[5] RAGHU L A M, SIVAPALAN S, ROBERT P, et al. Computational process for wind noise evaluation of rear-view mirror design in cars[C]. SAE Paper 2014-01-0619.
[6] MORON P, POWELL R, FREED D, et al. A CFD/SEA approach for prediction of vehicle interior noise due to wind noise [C]. SAE Paper 2009-01-2203.
[7] LEPLEY D, GRAF A, SENTHOORAN S, et al. A computational approach to evaluate the vehicle interior noise from greenhouse wind noise sources[C]. SAE Paper 2010-01-0285.
[8] IH K D, SHIN S R, SENTHOORAN S, et al. Activities of digital wind noise testing process for virtual prototype development[C]. 2009 JSAE Annual Congress:203-20095476.
[9] POWELL R, SENTHOORAN S, FREED D. Statistical analysis of correlation between simulation and measurement of interior wind noise[C]. ASME Technical Paper FEDSM-ICNMM 2010-31050,2010.
[10] HARTMANN M, OCKER J, LEMKE T, et al. Wind noise caused by the A-pillar and the side mirror flow of a generic vehicle model[C]. AIAA paper 2012-2205,2012.
[11] CHEN S, DOOLEN G D. Lattice Boltzmann method for fluid flows[J]. Annual Review of Fluid Mechanics,1998,30(1):329-364,1998.
[12] SUCCI S. The Lattice Boltzmann equation for fluid dynamics and beyond, series numerical mathematics and scientific computation[M]. Clarendon Press, Oxford,2001.
[13] HUMIERES D, LALLEMAND P, QIAN Y H. Lattice BGK models for Navier-Stokes equations[J]. Euro Physics Letters,1992,17(6):479-484.
[14] CHEN H, ORSZAG S A, STAROSELSKY I, et al. Expanded analogy between Bolzmann kinetic theory of fluids and turbulence[J]. Journal of Fluid Mechanics,2004,519(519):301-314.
[15] BUCHHEIM R, DOBRZYNSKI W, MANKAU H, et al. Vehicle interior noise related to external aerodynamics[J]. International Journal of Vehicle Design,1982,3(4):398-410.
[16] AHMED S R. A survey of automobile aerodynamic noise activities in Germany[C]. SAE Paper 950623.
[17] DAVID L, SIVAPALAN S, DENA H, et al. Numerical simulation and measurements of mirror-induced wind nosie[C]. SAE Paper 2009-01-2236.

汽车后视镜与雨刮的风噪优化^*

An Optimization of Vehicle Rear-view Mirror and Wiper Wind Noise

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