Journal of Jilin University(Engineering and Technology Edition) ›› 2021, Vol. 51 ›› Issue (4): 1198-1203.doi: 10.13229/j.cnki.jdxbgxb20200505

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Noise reduction mechanism of truck radial tire based on modified carcass string contour design

Jian YANG(),Qi XIA,Hai-chao ZHOU,Guo-lin WANG   

  1. School of Automotive and Traffic Engineering,Jiangsu University,Zhenjiang 212013,China
  • Received:2020-07-06 Online:2021-07-01 Published:2021-07-14

Abstract:

Taking the truck radial tire 295/80R22.5 as the research object, the characteristics of vibration noise were analyzed using modal acoustic transfer vector technique and the acoustic boundary element theory. By means of modal acoustic contribution analysis method, the contribution of each modal shape to tire vibration noise was studied. Based on the this, the carcass chord contour design theory was used to redesign the radial tire. Then, the mechanism of reducing tire vibration noise was analyzed through acoustic contribution analysis. Compared to original designed tire, the redesigned tire reduces 7.48% sidewall mass and 1.98 dB tire vibration noise respectively. This is due to that the adoption of the modified carcass string contour design theory significantly reduces the vibration acceleration response of the tread and sidewall, especially at the peak of 440 and 488 Hz. Furthermore, the redesigned tire reduces noise pressure of positive acoustic contribution (tire tread and sidewall, respectively) and increases the numbers of the negative panels.

Key words: vehicle engineering, truck radial tire, vibration noise, modified carcass string contour, noise reduction method

CLC Number: 

  • U463.3

Fig.1

Field sound pressure spectral curve"

Fig.2

Key design parameters of carcass contour"

Table 1

Key point cord of 295/80R22.5 contour"

关键点坐标值
X/mmY/mm
A496.8500
B494.61862.359
C492.49281.248
D392.296140.817
E300.55483.380

Fig.3

Comparison of new design and original design contour"

Fig.4

Material distribution map of new design contour"

Fig.5

Comparison of tire vibration noise curve"

Fig.6

Measure points on tire tread and sidewall surface"

Fig.7

Acceleration response of two design tires"

Fig.8

Tire outer contour parts schematic"

Fig.9

Comparison of outer contour acoustic contribution"

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