Mitigating of Low Frequency Squeal Noise by Optimize the Pressure Pattern with Shim Geometry in Noise Dynamometer and Corelating to FEA-Reference-Cited by-同舟云学术

Mitigating of Low Frequency Squeal Noise by Optimize the Pressure Pattern with Shim Geometry in Noise Dynamometer and Corelating to FEA

Published:2023-11-05 Issue: Volume: Page:
ISSN:0148-7191
Container-title:SAE Technical Paper Series
language:
Short-container-title:

Author:

Anand Ramamoorthy¹,Rakesh Sadhasivam¹,Kitchana Venkatesh¹

Affiliation:

1. Brakes India Pvt, Ltd.

Abstract

<div class="section abstract"><div class="htmlview paragraph">Despite efforts to reduce disc brake noise occurrence, it remains a significant concern in the automotive industry, particularly in the current era of electric vehicles, where it can be an intermittent issue. There is no standard solution available for every noise frequency, as it depends on various conditions and parameters that need to be experimentally identified and addressed. This paper specifically focuses on addressing low-frequency noise. During dynamic conditions, the contact pressure becomes uneven, leading to uneven pad wear and making the disc brake system susceptible to noise. In noise rigs, the paper selects the most suitable shim and pad geometry based on trials that analyze the interaction between the shim and pad. In conventional practice, shim modification was performed using computer-aided engineering, but obtaining accurate pressure patterns in dynamic conditions with CAE is challenging due to certain assumptions. Through dynamometer trials, the paper identifies that the critical frequency is caused by the coupling of the disc and pad mode shapes. Wear analysis reveals greater wear on the leading side of the piston, which can contribute to noise at critical frequencies.</div><div class="htmlview paragraph">Pressure patterns were examined using Tekscan™ across different pressure ranges from 10 bar to 50 bar to understand the cause of uneven wear, confirming the bias in the caliper loading pattern.</div><div class="htmlview paragraph">Consequently, the details of piston contact pressure were investigated, indicating higher pressure distribution on the leading end of the piston compared to the trialing side. Further analysis using finite element analysis (FEA) confirms a similar bias towards the caliper on the leading side. To modify the pressure pattern and reduce noise, a half-moon cut profile was introduced in the shim, resulting in the elimination of occurrences at 3.9 kHz.</div></div>

Publisher

SAE International

Reference8 articles.

1. Zhang , L. , Pang , M. , Meng , D. , and Diao , K. Impact of Contact Pressure Distribution on Break Squeal of Drum Brake SAE Technical Paper 2012-01-1838 2012 https://doi.org/10.4271/2012-01-1838

2. Kinkaid , N.M. , O’Reilly , O.M. , and Papadopoulos , P. Automotive Disc Brake Squeal Journal of Sound and Vibration 267 1 2003 105 166

3. Zhu , Q. , Xie , J. , Zhang , W. , Chen , G. et al. Effect of the Braking Parameter on Disc Brake Squeal of a Railway Vehicle Wear 522 2023 204884

4. Khuntiptong , A. , Tangchaichit , K. , Polnumtiang , S. , Ladbut , N. et al. Study of Brake Pad Shim Modification to Improve Stability Against High Frequency Squeal Noise by Finite Element Analysis Engineering Journal 26 9 2022 25 34

5. Massi , F. , Giannini , O. , and Baillet , L. Brake Squeal as Dynamic Instability: An Experimental Investigation The Journal of the Acoustical Society of America 120 3 2006 1388 1398