Sage Journals: Discover world-class research

Abstract

An analysis of the energy dissipation sources acting in a vibrating aluminum plate is presented in this paper. In the first step, the contact-free modal analysis of a suspended plate is conducted using a laser vibrometer and an acoustic excitation to obtain reference data. The thin nylon suspension set-up guarantees a low boundary damping, which is assumed to be negligible. In the second step, a number of damping sources are modeled. Acoustic damping due to the noise radiation of the nonbaffled plate is computed using the boundary integral method and a light fluid approximation to express the vibroacoustic coupling in analytical terms. The damping due to the sheared air flow along the free-plate borders is determined on the basis of a simple two-dimensional boundary layer model. Thermoelastic damping is assessed using a Fourier series expression for the temperature field along with a perturbation technique to take thermoelastic coupling into account. Since no robust model is available so far to quantify viscoelastic material damping in aluminum, it is determined in a last step by subtracting measured values of damping from those previously computed. Aluminum viscoelastic damping turns out to be very small and almost independent of frequency.

Keywords

Damping thermoelastic damping viscoelastic damping material damping acoustic radiation damping

Get full access to this article

View all access options for this article.

References

Adhikari

(2011) An iterative approach for non proportionally damped systems. Mechanics Research Communications 38(3): 226–230.

Atalla

Nicolas

Gauthier

(1996) Acoustic radiation of an unbaffled vibrating plate with general elastic boundary conditions. Journal of the Acoustical Society of America 99(3): 1484–1494.

Cha

(2005) Approximate eigensolutions for arbitrarily damped nearly proportional systems. Journal of Sound and Vibration 288(4–5): 813–827.

Chaigne

Lambourg

(2001) Time-domain simulation of damped impacted plates. I: Theory and experiments. Journal of the Acoustical Society of America 109(4): 1422–1432.

Cortés

Elejabarrieta

(2006) An approximate numerical method for the complex eigenproblem in systems characterised by a structural damping matrix. Journal of Sound and Vibration 296(1–2): 166–182.

Côté

Atalla

Guyader

(1998) Vibroacoustic analysis of an unbaffled rotating disk. Journal of the Acoustical Society of America 103(3): 1483–1492.

Cousteix

(1988) Couche limite laminaire, Toulouse, France: Cépaduès.

Cremer

Heckl

Ungar

(1988) Structure-Borne Sound, Berlin: Springer.

Cuesta

Valette

(1993) Mécanique de la corde vibrante, Paris: Hermès.

10.

Filippi

PJT

Habault

Lefebvre

J-P

Bergassoli

(1999) Acoustics, San Diego, CA: Academic Press.

11.

Filippi

PJT

Habault

Mattei

Maury

(2001) The role of the resonance modes in the response of a fluid-loaded structure. Journal of Sound and Vibration 239(4): 639–663.

12.

Granato

Lücke

(1956) Theory of mechanical damping due to dislocations. Journal of Applied Physics 27(6): 583–593.

13.

Lambourg

Chaigne

Matignon

(2001) Time-domain simulation of damped impacted plates. II: Numerical model and results. Journal of the Acoustical Society of America 109(4): 1433–1447.

14.

Landau

Lifschitz

(1986) Fluid Mechanics, Oxford: Pergamon Press.

15.

Laulagnet

(1998) Sound radiation by a simply supported unbaffled plate. Journal of the Acoustical Society of America 103(5): 2451–2462.

16.

Fang

(2012) Thermoelastic damping in rectangular and circular microplate resonators. Journal of Sound and Vibration 331(3): 721–733.

17.

Lifshitz

Roukes

(1999) Thermoelastic damping in micro- and nanomechanical systems. Physical Review B 61(8): 5600–5609.

18.

Nashif

Jones

Henderson

(1985) Vibration Damping, New York: John Wiley & Sons.

19.

Norris

(2006) Dynamics of thermoelastic thin plates: A comparison of four theories. Journal of Thermal Stresses 29(2): 169–195.

20.

Nowacki

(1975) Dynamical Problems of Thermoelasticity, Warsaw: Polish Scientific Publishers.

21.

Prabhakar

Païdoussis

Vengallatore

(2009) Analysis of frequency shifts due to thermoelastic coupling in flexural-mode micromechanical and nanomechanical resonators. Journal of Sound and Vibration 323(1–2): 385–396.

22.

Rivière

(2004) Analysis of the low frequency damping observed at medium and high temperatures. Materials Science and Engineering A 370(1–2): 204–208.

23.

Rao

(2010) Mechanical Vibrations, Fifth edition. Upper Saddle River, NJ: Prentice Hall.

24.

Wang

Zhang

Yang

(2000) The dependence of damping capacity of PMMCs on strain amplitude. Computational Materials Science 18(2): 205–211.

25.

Wei

Gong

Cheng

Zhou

Shui

Han

(2002) Low-frequency damping behavior of foamed commercially pure aluminum. Materials Science and Engineering A 332(1–2): 375–381.

26.

Woodhouse

(1988) Linear damping models for structural vibration. Journal of Sound and Vibration 215(3): 547–569.

27.

Zener

(1948) Elasticity and Anelasticity of Metals, Chicago, IL: The University of Chicago Press.

Damping analysis of a free aluminum plate

Abstract

Keywords

Get full access to this article

References