In this paper, a flexible pin-on-disk system is used to simulate how squeal noise can be generated in frictional contact. As the research object, the modeling process and transient simulation method of the flexible pin-on-disk system are introduced. By means of numerical simulation, the time-varying frictional squeal reappears by introducing periodic frictional coefficient generated from rotation. Afterward, the features of time-varying squeal are studied including time-domain features, frequency-domain features, transient deformation features of the disk and the pin on the occurrence of squeal, as well as energy features. Finally, the conception and mathematical expressions of modal contribution factor are defined, and the transient modal contribution factor features of every mode are studied to make clear the function of every mode. The relationship between mode contribution factors and the vibration is revealed. It reveals that modal contribution factors between squeal and not are quite different from each other. On no occurrence of squeal, the modal contribution factors of sine and cosine modes of the disk fluctuate in the way similar to harmonic wave, and the phase difference between the contribution factors of sine and cosine mode with the same nodal circle and the same nodal diameter is 90 deg. During squeal, the coupling mode may play the most important role but not all the time. At any time, the low-frequency modes play the leading role.
Issue Section:
Research Papers
References
1.
Kinkaid
, N. M.
, O'Reilly
, O. M.
, and Papadopoulos
, P.
, 2003
, “Automotive Disc Brake Squeal
,” J. Sound Vib.
, 267
(1
), pp. 105
–166
.2.
Hoffmann
, N.
, Fischer
, M.
, Allgaier
, R.
, and Gaul
, L.
, 2002
, “A Minimal Model for Studying Properties of the Mode-Coupling Type Instability in Friction Induced Oscillations
,” Mech. Res. Commun.
, 29
(4
), pp. 197
–205
.3.
Hoffmann
, N.
, and Gaul
, L.
, 2003
, “Effects of Damping on Mode-Coupling Instability in Friction Induced Oscillations
,” ZAMM: J. Appl. Math. Mech.
, 83
(8
), pp. 524
–534
.4.
Sinou
, J.
, and Jézéquel
, L.
, 2007
, “Mode Coupling Instability in Friction-Induced Vibrations and Its Dependency on System Parameters Including Damping
,” Eur. J. Mech.: A/Solids
, 26
(1
), pp. 106
–122
.5.
Kang
, J.
, 2012
, “Finite Element Modelling for the Investigation of In-Plane Modes and Damping Shims in Disc Brake Squeal
,” J. Sound Vib.
, 331
(9
), pp. 2190
–2202
.6.
Massi
, F.
, and Baillet
, L.
, 2005
, “Numerical Analysis of Squeal Instability
,” International Conference on Emerging Technologies of Noise and Vibration Analysis and Control (NOVEM), St. Raphael, France, Apr. 18–21, pp. 1–10.7.
Ouyang
, H.
, and Mottershead
, J. E.
, 1998
, “Friction-Induced Parametric Resonances in Disc: Effects of a Negative Friction–Velocity Relationship
,” J. Sound Vib.
, 209
(2
), pp. 251
–264
.8.
Ouyang
, H.
, and Mottershead
, J. E.
, 2000
, “A Methodology for the Determination of Dynamic Instabilities in a Car Disc Brake
,” Int. J. Veh. Des.
, 23
(3/4
), pp. 241
–262
.9.
Kang
, J. Y.
, Krousgrill
, C. M.
, and Sadeghi
, F.
, 2008
, “Dynamic Instability of a Thin Circular Plate With Friction Interface and Its Application to Disc Brake Squeal
,” J. Sound Vib.
, 316
(1–5
), pp. 164
–179
.10.
Massi
, F.
, Baillet
, L.
, Giannini
, O.
, and Sestieri
, A.
, 2007
, “Brake Squeal: Linear and Nonlinear Numerical Approaches
,” Mech. Syst. Signal Process.
, 21
(6
), pp. 2374
–2393
.11.
Massi
, F.
, and Giannini
, O.
, 2008
, “Effect of Damping on the Propensity of Squeal Instability: An Experimental Investigation
,” J. Acoust. Soc. Am.
, 123
(4
), pp. 2017
–2023
.12.
Park
, J.
, and Choi
, Y.
, 2007
, “Brake Squeal Noise Due to Disc Run-Out
,” Proc. Inst. Mech. Eng., Part D
, 221
(7
), pp. 811
–821
.13.
Lee
, L.
, and Gesch
, E.
, 2009
, “Discussions on Squeal Triggering Mechanisms—A Look Beyond Structural Stability
,” SAE
Paper No. 2009-01-3012.14.
Renaud
, F.
, Chevallier
, G.
, Dion
, J. L.
, and Taudiere
, G.
, 2012
, “Motion Capture of a Pad Measured With Accelerometers During Squeal Noise in a Real Brake System
,” Mech. Syst. Signal Process.
, 33
(2
), pp. 155
–166
.15.
Butlin
, T.
, and Woodhouse
, J.
, 2010
, “Friction-Induced Vibration: Quantifying Sensitivity and Uncertainty
,” J. Sound Vib.
, 329
(5
), pp. 509
–526
.16.
Butlin
, T.
, and Woodhouse
, J.
, 2011
, “A Systematic Experimental Study of Squeal Initiation
,” J. Sound Vib.
, 330
(21
), pp. 5077
–5095
.17.
Abdelounis
, H. B.
, Bot
, A. L.
, Perret-Liaudet
, J.
, and Zahouani
, H.
, 2010
, “An Experimental Study on Roughness Noise of Dry Rough Flat Surfaces
,” Wear
, 268
(1
), pp. 335
–345
.18.
Giannini
, O.
, Akay
, A.
, and Massi
, F.
, 2006
, “Experimental Analysis of Brake Squeal Noise on a Laboratory Brake Setup
,” J. Sound Vib.
, 292
(1–2
), pp. 1
–20
.19.
Hochlenert
, D.
, Korspeter
, G. S.
, and Hagedorn
, P.
, 2007
, “Friction Induced Vibrations in Moving Continua and Their Application to Brake Squeal
,” ASME J. Appl. Mech.
, 74
(3
), pp. 542
–549
.20.
Flint
, J.
, and Hulten
, J.
, 2002
, “Lining-Deformation-Induced Modal Coupling as Squeal Generator in a Distributed Parameter Disc Brake Model
,” J. Sound Vib.
, 254
(1
), pp. 1
–21
.21.
Ouyang
, H.
, and Mottershead
, J. E.
, 2004
, “Dynamic Instability of an Elastic Disk Under the Action of a Rotating Friction Couple
,” ASME J. Appl. Mech.
, 71
(6
), pp. 753
–758
.22.
Massi
, F.
, Giannini
, O.
, and Baillet
, L.
, 2006
, “Brake Squeal as Dynamic Instability: An Experimental Investigation
,” J. Acoust. Soc. Am.
, 120
(3
), pp. 1388
–1398
.23.
Massi
, F.
, Baillet
, L.
, and Giannini
, O.
, 2006
, “Experimental Analysis on Squeal Modal Instability
,” International Modal Analysis Conference
(IMAC-XXIV
), St. Louis, MO, Jan. 30–Feb. 2.https://hal-insu.archives-ouvertes.fr/insu-0035549124.
Ostermeyer
, G. P.
, and Graf
, M.
, 2010
, “Mode Coupling Instabilities Induced by a Periodic Coefficient of Friction
,” SAE Int. J. Passenger Cars Mech. Syst.
, 3
(2
), pp. 31
–37
.25.
Ostermeyer
, G. P.
, 2003
, “On the Dynamics of the Friction Coefficient
,” Wear
, 254
(9
), pp. 852
–858
.26.
Ostermeyer
, G. P.
, and Müller
, M.
, 2006
, “Dynamic Interaction of Friction and Surface Topography in Brake Systems
,” Tribol. Int.
, 39
(5
), pp. 370
–380
.27.
Zhang
, L.
, Wu
, J.
, and Meng
, D.
, 2015
, “A Reduced-Order Model for Complex Modes of Brake Squeal Model and Its Application to a Flexible Pin-on-Disc System
,” Math. Probl. Eng.
, 2015
, p. 103809
.28.
Beloiu
, D. M.
, and Ibrahim
, R. A.
, 2004
, “Disc–Pad Interaction Related to Brake Squeal
,” SAE
Paper No. 2004-01-0826.29.
Diao
, K.
, Zhang
, L.
, and Meng
, D.
, 2014
, “Mechanism Study on Time-Varying Characteristics of Frictional Squeal in Pin-on-Disc System
,” SAE
Paper No. 2014-01-2517.30.
Zhang
, L.
, Diao
, K.
, Meng
, D.
, and Yu
, Z.
, 2013
, “Time-Varying Characteristics of Frictional Squeal in Pin-on-Disc System: Generation Mechanism and Key Impact Factors
,” Chin. J. Mech. Eng.
, 49
(14
), pp. 99
–105
(in Chinese).31.
Guan
, D.
, and Huang
, J.
, 2003
, “The Method of Feed-In Energy on Disc Brake Squeal
,” J. Sound Vib.
, 261
(2
), pp. 297
–307
.32.
Tuchinda
, A.
, Hoffmann
, N. P.
, Ewins
, D. J.
, and Keiper
, W.
, 2001
, “Mode Lock-In Characteristics and Instability Study of the Pin-on-Disc System
,” IMAC-XIX: A Conference on Structural Dynamics
, Kissimmee, FL, Feb. 5–8, Vol. 1
, pp. 71
–77
.https://sem.org/wp-content/uploads/2016/02/sem.org-IMAC-XIX-190303-Mode-Lock-Characteristics-Instability-Study-Pin-disc-System.pdf33.
Zhang
, L.
, Wu
, J.
, and Meng
, D.
, 2015
, “Relationship Between Two Friction-Induced Squeal Mechanisms of Mode Coupling and Energy Feed-In Theories
,” J. Tongji Univ.: Nat. Sci.
, 43
(10
), pp. 1562
–1569
(in Chinese).Copyright © 2018 by ASME
You do not currently have access to this content.
