Analysis of friction excited vibration of drum brake squeal

被引:16
作者
Teoh, Choe-Yung [1 ]
Ripin, Zaidi Mohd [1 ]
Hamid, Muhammad Najib Abdul [1 ]
机构
[1] Univ Sains Malaysia, Sch Mech Engn, Nibong Tebal 14300, Pulau Pinang, Malaysia
来源
INTERNATIONAL JOURNAL OF MECHANICAL SCIENCES | 2013年 / 67卷
关键词
Minimal model; Self-excited friction induced vibration; Drum brake squeal; Flutter instability; MODE-COUPLING INSTABILITY; INDUCED OSCILLATIONS; LABORATORY BRAKE; FOLLOWER LOADS; NOISE; SYSTEM; DESTABILIZATION; CRITERION; BEHAVIOR; DISCS;
D O I
10.1016/j.ijmecsci.2012.12.007
中图分类号
TH [机械、仪表工业];
学科分类号
0802 ;
摘要
Drum brake squeal is modelled as friction excited vibration based on the binary flutter mechanism which requires the convergence of two modes experimentally identified using Modal Assurance Criterion. Transient analysis is carried out to determine the brake drum response under braking condition and the model produces squeal mode at 2026 Hz comparable to the measured squeal frequency of 1950 Hz. There are limited combinations of the location of centre of pressure of the shoes that cause squeal. The amplitude of the limit cycle of the drum brake squeal can be reduced by increasing damping, mode frequency separation and reducing the contact stiffness. (C) 2012 Elsevier Ltd. All rights reserved.
引用
收藏
页码:59 / 69
页数:11
相关论文
共 50 条
[21]   TIME - FREQUENCY ANALYSIS OF DISC BRAKE SQUEAL IN A BRAKE EXPERIMENT [J].
Liu, X. D. ;
Wang, H. X. ;
Wan, Z. S. ;
Shan, Y. C. .
PROCEEDINGS OF THE ASME INTERNATIONAL MECHANICAL ENGINEERING CONGRESS AND EXPOSITION, 2013, VOL 14, 2014,
[22]   Impact analysis of contact symmetrical caliper structure on brake squeal [J].
Pan, Gongyu ;
Zhang, Xiaoman ;
Liu, Peng ;
Chen, Lin .
JOURNAL OF VIBRATION AND CONTROL, 2021, 27 (19-20) :2180-2191
[23]   Experimental studies of friction-induced brake squeal: Influence of environmental sand particles in the interface brake pad-disc [J].
Kchaou, M. ;
Lazim, A. R. Mat ;
Hamid, M. K. Abdul ;
Abu Bakar, A. R. .
TRIBOLOGY INTERNATIONAL, 2017, 110 :307-317
[24]   Structure analysis and optimization of brake pad for disk brake squeal suppression [J].
Liu, Shaona ;
Li, Longting ;
Lv, Hongming ;
Hu, Xiangwen ;
Li, Yunping ;
Chen, Yuansheng .
AIP ADVANCES, 2025, 15 (03)
[25]   Brake squeal finite element performance comparison between commercial and coconut shell-reinforced material drum brake linings [J].
Maciel, Mateus Holanda Cardoso ;
Rodrigues, Romulo do Nascimento ;
Costa, Camilo Augusto Santos ;
Bezerra, Roberto de Araujo ;
Goncalves, Vanessa Vieira ;
de Freitas, Thiago Victor Albuquerque .
PROCEEDINGS OF THE INSTITUTION OF MECHANICAL ENGINEERS PART L-JOURNAL OF MATERIALS-DESIGN AND APPLICATIONS, 2025, 239 (01) :100-110
[26]   Squeal analysis of thin-walled lattice brake disc structure [J].
Karamoozian, Aminreza ;
Tan, Chin An ;
Wang, Liangmo .
MATERIALS & DESIGN, 2018, 149 :1-14
[27]   Stabilization Device for a Rigid Disc Excited by Friction [J].
Miyasato, Hugo Heidy ;
Segala Simionatto, Vinicius Gabriel ;
Dias, Milton, Jr. .
JOURNAL OF VIBRATION AND ACOUSTICS-TRANSACTIONS OF THE ASME, 2021, 143 (04)
[28]   Deep learning for brake squeal: Brake noise detection, characterization and prediction [J].
Stender, Merten ;
Tiedemann, Merten ;
Spieler, David ;
Schoepflin, Daniel ;
Hoffmann, Norbert ;
Oberst, Sebastian .
MECHANICAL SYSTEMS AND SIGNAL PROCESSING, 2021, 149
[29]   Parameter Determination of a Minimal Model for Brake Squeal [J].
Chu, Zhigang ;
Zheng, Fei ;
Liang, Lei ;
Yan, Hui ;
Kang, Runcheng .
APPLIED SCIENCES-BASEL, 2018, 8 (01)
[30]   Nepenthes-Inspired Squeal Noise Reducing Elastomer with Stabilized Friction-Induced Self-Excited Vibration [J].
Zhang, Bowen ;
Yang, Kang ;
Yu, Xinping ;
Zhang, Jiayan ;
Dong, Zhichao ;
Fang, Ruochen ;
Jiang, Lei .
ADVANCED FUNCTIONAL MATERIALS, 2025,
12345