The Effect of Tire Design Parameters on the Force Transmissibility

Abstract: A finite element modeling technique is employed in this paper to predict the force transmissibility of tire-cavity-wheel assembly under a free-fixed condition. The tire and wheel force transmissibility is factor in structure borne road noise performance. In order to improve structure borne noise, it is required to lower the 1 st peak frequency of force transmissibility. This paper presents an application of finite element analysis modeling along with experimental verification to predict the force transmissibil… Show more

“…Based on the inflation analysis simulation results as tabulated in Table 5 and 6, it can be deduced that as the camber angle increases for each tire, the maximum total deformation also gradually increases, while the maximum equivalent stress does not show any fixed trend. The maximum total deformation under smooth road condition ranges from 9.4360 ×10 -3 m to 1.9487 ×10 -2 m for all three tires, while the maximum equivalent stress ranges from 4.8968 ×10 5 Pa to 1.9914 ×10 6 Pa. The highest value for maximum total deformation for all three tire models in the two different road conditions can be observed when the tire is cambered to 15°.…”

“…The structure of a tire is extremely complex, and a general radial tire is mainly manufactured from approximately ten to fifteen components such as beads, belt piles, grooves, and sidewalls, and each of the components possess its own properties [5]. While the exact material properties for each component is always almost confidential, most tires have the material composition of mostly synthetic rubber or fiber-reinforced rubber, and pure rubber for the remaining [6]. The tread of the tire is generally composed of the combination of both natural rubber and polybutadiene rubber [7].…”

Impact of camber angle on the tire tread behaviour in different road conditions

“…Based on the inflation analysis simulation results as tabulated in Table 5 and 6, it can be deduced that as the camber angle increases for each tire, the maximum total deformation also gradually increases, while the maximum equivalent stress does not show any fixed trend. The maximum total deformation under smooth road condition ranges from 9.4360 ×10 -3 m to 1.9487 ×10 -2 m for all three tires, while the maximum equivalent stress ranges from 4.8968 ×10 5 Pa to 1.9914 ×10 6 Pa. The highest value for maximum total deformation for all three tire models in the two different road conditions can be observed when the tire is cambered to 15°.…”

“…The structure of a tire is extremely complex, and a general radial tire is mainly manufactured from approximately ten to fifteen components such as beads, belt piles, grooves, and sidewalls, and each of the components possess its own properties [5]. While the exact material properties for each component is always almost confidential, most tires have the material composition of mostly synthetic rubber or fiber-reinforced rubber, and pure rubber for the remaining [6]. The tread of the tire is generally composed of the combination of both natural rubber and polybutadiene rubber [7].…”

Impact of camber angle on the tire tread behaviour in different road conditions