Experimental analysis of sound field in the tire cavity arising from the acoustic cavity resonance

As we all know, the tire acoustic cavity resonance noise (TACRN) can cause irritating noise in a vehicle, but it is evidently difficult to be weakened. To obtain accurately the characteristics of TACRN is a key step of attenuating TACRN. In this paper, a simulation method, in which a simplified finite element model of automobile tire with acoustic cavity introducing the rotation of automobile tire is established, is proposed to gain the sound field in the cavity of a rotating automobile tire. And the test of sound pressure in a rotating tire is also performed to validate the proposed simulation method. The comparisons between the simulation and experimental consequences show a satisfying conclusion. Furthermore, the influence factors of the rotating speed, the inflation pressure of the tire and the load on the sound field of automobile tire acoustic cavity are calculated and analyzed.

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Analysis of Tire Acoustic Cavity Resonance Energy Transmission Characteristics in Wheels Based on Power Flow Method

Applied Sciences ◽

10.3390/app11093979 ◽

2021 ◽

Vol 11 (9) ◽

pp. 3979

Author(s):

Wei Zhao ◽

Yuting Liu ◽

Xiandong Liu ◽

Yingchun Shan ◽

Xiaojun Hu

Keyword(s):

Power Flow ◽

Resonance Energy ◽

Cavity Resonance ◽

Propagation Path ◽

Material Structure ◽

Transmission Characteristics ◽

Energy Transmission ◽

Flow Method ◽

Acoustic Cavity ◽

Power Flow Method

As a kind of low-frequency vehicle interior noise, tire acoustic cavity resonance noise plays an important role, since the other noise (e.g., engine noise, wind noise and friction noise) has been largely suppressed. For the suspension system, wheels stand first in the propagation path of this energy. Therefore, it is of great significance to study the influence of wheel design on the transmission characteristics of this vibration energy. However, currently the related research has not received enough attention. In this paper, two sizes of aluminum alloy wheel finite element models are constructed, and their modal characteristics are analyzed and verified by experimental tests simultaneously. A mathematically fitting sound pressure load model arising from the tire acoustic cavity resonance acting on the rim is first put forward. Then, the power flow method is applied to investigate the resonance energy distribution and transmission characteristics in the wheels. The structure intensity distribution and energy transmission efficiency can be described and analyzed clearly. Furthermore, the effects of material structure damping and the wheel spoke number on the energy transmission are also discussed.

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Asynchronous control of vortex-induced acoustic cavity resonance using imbedded piezo-electric actuators

The Journal of the Acoustical Society of America ◽

10.1121/1.3143784 ◽

2009 ◽

Vol 126 (1) ◽

pp. 36-45 ◽

Cited By ~ 9

Author(s):

M. M. Zhang ◽

L. Cheng ◽

Y. Zhou

Keyword(s):

Cavity Resonance ◽

Acoustic Cavity ◽

Asynchronous Control ◽

Piezo Electric

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Design and simulation of Helmholtz resonator assembly used to attenuate tire acoustic cavity resonance noise

INTER-NOISE and NOISE-CON Congress and Conference Proceedings ◽

10.3397/in-2021-1706 ◽

2021 ◽

Vol 263 (6) ◽

pp. 942-953

Author(s):

Wei Zhao ◽

Xiandong Liu ◽

Yingchun Shan ◽

Tian He

Keyword(s):

Natural Frequencies ◽

Helmholtz Resonator ◽

Operating Conditions ◽

Cavity Resonance ◽

Frequency Range ◽

Sound Fields ◽

Acoustic Cavity ◽

The Poor ◽

Alloy Wheel ◽

Reduction Effect

Tire acoustic cavity resonance noise (TACRN) is a typical annoying lower-frequency interior noise of a passenger car. The widely used attenuating method of attaching the porous sound absorption material in tire cavity can reduce TACRN effectively, but causes the increase of tire-wheel assembly weight and cost, also the poor durability. Additionally, the Helmholtz resonator (HR) is also used in the wheel of some cars although having only narrow effective band. The existing investigation shows that the frequency of TACRN varies with the car speed and load and also has the split characteristics. The change of TACRN frequency causes a certain difficulty to suppress TACRN effectively. Aiming at this problem, in this paper, TACRN frequency range of a specific tire cavity under different operating conditions is first calculated and analyzed. Then, for a specific aluminum alloy wheel, a HR assembly including several HRs is designed to make the natural frequencies of HR assembly cover the TACRN frequencies. Finally, the reduction effect of TACRN is simulated and evaluated by comparing the sound fields in tire cavity with/without HR assembly under same volume velocity sound source. This work is helpful for attenuating TACRN effectively under the changing operating conditions.

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Synthetic Jet Actuator Cavity Acoustics: Helmholtz Versus Quarter-Wave Resonance

Journal of Vibration and Acoustics ◽

10.1115/1.4030216 ◽

2015 ◽

Vol 137 (5) ◽

Cited By ~ 4

Author(s):

Tyler Van Buren ◽

Edward Whalen ◽

Michael Amitay

Keyword(s):

Acoustic Resonance ◽

Synthetic Jet ◽

Cavity Resonance ◽

Synthetic Jet Actuator ◽

Acoustic Cavity ◽

Wave Resonance ◽

Cavity Resonances ◽

Quarter Wave ◽

Cavity Acoustics ◽

The Impact

The impact of cavity geometry on the source of acoustic resonance (Helmholtz or quarter-wave) for synthetic jet type cavities is presented. The cavity resonance was measured through externally excited microphone measurements. It was found that, for pancake-shaped cavities, the Helmholtz resonance equation was inadequate (off by more than 130%) at predicting the acoustic cavity resonances associated with synthetic jet actuation, whereas a two-dimensional quarter-wave resonance was accurate to 15%. The changes in the geometry (cavity diameter, cavity height, and orifice length) could alter the cavity resonance by up to 50%, and a finite element solver was accurate at predicting this resonance in all cases. With better knowledge of the phenomena governing the acoustic resonance, prediction of the cavity resonance can become more accurate and improvements to current prediction tools can be made.

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An experimental analysis method for the incident sound field using propagation mode expansion: Study on the incident sound field in the insulation performance measurement for partition walls. part 1

Japan Architectural Review ◽

10.1002/2475-8876.12170 ◽

2020 ◽

Vol 3 (4) ◽

pp. 615-628

Author(s):

Yu Aida ◽

Naohisa Inoue ◽

Tetsuya Sakuma

Keyword(s):

Performance Measurement ◽

Experimental Analysis ◽

Sound Field ◽

Propagation Mode ◽

Analysis Method ◽

Mode Expansion ◽

Partition Walls ◽

Insulation Performance

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Global Active Control of Transmitted Sound Into Acoustic Cavity With Speakers and Piezoelectric Patch Actuators

Volume 10: Mechanical Systems and Control, Parts A and B ◽

10.1115/imece2009-11169 ◽

2009 ◽

Author(s):

Masih Hanifzadegan ◽

Abdolreza Ohadi

Keyword(s):

Active Control ◽

Plane Waves ◽

Sound Field ◽

Coupled System ◽

Mode Shapes ◽

Flexible Plate ◽

Acoustic System ◽

Acoustic Cavity ◽

Piezoelectric Patch ◽

Rigid Walls

In this work modeling of a vibro-acoustic system and global sound field control with both acoustic and structural actuators have been studied. The model of the system consists of a 3D rectangular cavity with five acoustically rigid walls and a flexible plate on the top of cavity. First, modeling of the vibro-acoustic system has been acquired and subsequently the mode shapes and natural frequencies of the coupled system have been calculated. Plane waves on the plate surface are the main sources of disturbances in this system. Undesired sound (noise) which is propagated into the enclosure is controlled by mounted piezoelectric patch actuators on the plate and acoustic piston sources (speakers) inside cavity. The global active control is designed to minimize the acoustic potential energy inside the cavity. The control performance has been investigated by acoustic and structural actuators separately and simultaneously.

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Interior Acoustic Field Analysis of Hydraulic Excavator’s Cabin Based on Bem

Applied Mechanics and Materials ◽

10.4028/www.scientific.net/amm.141.323 ◽

2011 ◽

Vol 141 ◽

pp. 323-327 ◽

Cited By ~ 1

Author(s):

Yuan Wang ◽

Jian Run Zhang ◽

Xiao Bo Liu ◽

Vanquynh Le

Keyword(s):

Boundary Element ◽

Acoustic Field ◽

Sound Pressure ◽

Sound Field ◽

Element Model ◽

Forced Response ◽

Field Analysis ◽

Acoustic Cavity ◽

Acoustic Boundary Element ◽

Force Excitation

Structure finite element model of excavator’s cabin is built, and the displacement response of cabin under the external force excitation is analyzed between 20Hz and 200Hz. In the analysis of acoustic characteristic of cabin, the boundary element model of the cabin internal acoustic cavity including the seat is created firstly. Where the result of forced response of the cabin’s structure is mapped to the boundary element model of the sound field inside the cavity as boundary condition, and the distribution of internal acoustic field is calculated and sound pressure response at the driver’s right ear is obtained. And then, acoustic boundary element grids is divided into different sections according to the corresponding structure section of the cabin to evaluate the contribution of sound pressure level at diver’s right ear from each part of cabin.

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Analytical Model of Tire Cavity Resonance and Coupled Tire/Cavity Modal Model

Tire Science and Technology ◽

10.2346/1.2135990 ◽

2000 ◽

Vol 28 (1) ◽

pp. 33-49 ◽

Cited By ~ 18

Author(s):

R. Gunda ◽

S. Gau ◽

C. Dohrmann

Keyword(s):

Plane Wave ◽

Analytical Model ◽

Interior Noise ◽

Analytical Models ◽

Cavity Resonance ◽

Coupling Matrix ◽

Acoustic Cavity ◽

Resonance Frequencies ◽

Cavity Structure ◽

Modal Model

Abstract The acoustic resonance of the air cavity in the tire/wheel assembly may be a contributor to vehicle interior noise through the structure-borne noise transmission path. This problem has been examined in the past using approximate closed form solutions (based on plane wave theory for a two-tube model) and numerically, using FEA. The coupling between the cavity resonance and structural resonance of the wheel may result in higher levels of interior noise as noted previously. The two primary goals of this paper are (1) to develop simple analytical models to gain fundamental understanding of some observed phenomena and for a quick estimation of cavity resonance frequency to assist in the design process, and (2) to develop tire modal models incorporating the acoustic cavity to predict coupled system natural frequencies and response. An improved analytical model for accurate calculation of acoustic cavity resonance frequencies of a static, unloaded tire is developed using variational principles. The sensitivities of the cavity resonance frequencies to tire width and aspect ratio are examined. For the case of a loaded tire, an improved analytical formulation based on plane wave propagation (for linearly varying cross-sectional area) is developed. Deformed structure geometry from FEA is used as input to the analytical model. The FEA-based methodology used in the tire/cavity coupling analysis is as follows: The tire structural modes are calculated, ignoring the effect of the acoustic cavity. The tire cavity modes are calculated using deformed cavity geometry only. Next, the structural/acoustic coupling matrix is calculated. Finally, a coupled cavity-structure modal model is generated from modal mass and stiffness of the tire/wheel assembly, the cavity modal matrices, and the coupling matrix. This process is an improvement over conventional tire modal models, which only include structural modes.

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