DE3042350C2 - Pneumatic vehicle tires - Google Patents

Description

The automotive industry is making great efforts to further reduce noise emissions from moving vehicles, which represents a major problem, particularly for residents of busy roads, and which cannot be solved by road construction measures alone (choice of suitable road surfaces, construction of noise barriers and fences).

Previous attempts to reduce noise in motor vehicles have largely been limited to reducing drive noise. However, the driving noise of a motor vehicle is only predominantly determined by drive noise in very few operating conditions. The essential and usually predominant noise component is the rolling noise of the vehicle; this is the noise of a vehicle rolling with the engine turned off. This is illustrated by the following measurements taken from the specialist literature for the respective shares of rolling and drive noise in the peak level of a car in three different operating conditions. The measurements were taken in each case at a distance of 7.5 m from the center of the vehicle and at a height of 1.7 m above road level: &udf53;np100&udf54;&udf53;vu10&udf54;&udf53;vz9&udf54;&udf53;vu10&udf54;

It follows that reducing rolling noise is of particular importance, and a reduction of around 5 dB(A) would already result in a considerable reduction in the environmental impact. This value is therefore used by the automotive and tire industries as a target in their development work.

• 1. "Air pumping" durch das Profil und
• 2. luftschallabstrahlende Reifenschwingungen,

wobei der ersten Hypothese weit mehr Bedeutung zugemessen wurde, was aber aufgrund der neueren Erkenntnisse unzutreffend sein könnte. Hierfür sprechen auch die praktischen Erfahrungen mit Änderungen der Reifenprofile, welche nur zu sehr geringen Geräuschpegelminderungen geführt haben, obgleich auf diesem Gebiet bis in die neueste Zeit erhebliche Anstrengungen unternommen worden sind (vergl. DE-OS 29 03 670, 29 03 671, 29 03 846 und 29 05 051).There have been some recent scientific studies on the causes of rolling noise caused by vehicle tires, see e.g. BD Denker in "Automobil-Industrie" 3/78, 17-23. This shows that two hypotheses are currently being discussed for the causes of the noise:

• 1. "Air pumping" through the profile and
• 2. airborne sound radiating tire vibrations,

The first hypothesis was given far greater importance, but this could be incorrect in view of the more recent findings. This is also supported by practical experience with changes in tyre profiles, which have only led to very slight reductions in noise levels, although considerable efforts have been made in this area up to the present time (cf. DE-OS 29 03 670, 29 03 671, 29 03 846 and 29 05 051).

From DE-OS 20 40 898 it is known to equip the inner surface of pneumatic vehicle tires or air tubes entirely or partially with a sound-absorbing coating, which is an (open-cell) foam or textile fiber coating. The drawing shows that this coating is about 5 mm thick. It is intended to counteract the balloon reverberation effect inside the tire by making the sound-reflecting inner walls sound-absorbing due to the coating. However, studies have shown that no noticeable reduction in tire rolling noise can be achieved in this way, which is probably due to the fact that balloon reverberation effects do not play a significant role.

DE-AS 10 10 398 proposes incorporating thin plates or strips made of rubber or plastic with a high plasticizer content of up to 300% into tires to reduce noise. However, due to their low modulus of elasticity, their thin thickness of just a few millimeters and the lack of air permeability of the inserts, which may be porous but are in any case closed-cell due to the manufacturing process, the noise-reducing effect is minimal. According to DE-PS 15 05 877, a vibration-damping intermediate layer made of a homogeneous or cellular material should be installed between the tread and the carcass of a pneumatic vehicle tire. This results in extremely complicated tire production, without the desired vibration damping simultaneously leading to a corresponding reduction in noise.

The invention is based on the task of finding suitable means for effectively dampening structure-borne noise in pneumatic vehicle tires in order to reduce rolling noise and thus the overall noise level of moving motor vehicles. The measures must not be too complex and must not impair the other running and driving properties of the tires. In this sense, it was primarily a matter of finding means that would allow effective dampening of structure-borne noise in the physiologically particularly important frequency range of about 300 to 5000, in particular 500 to 2500 Hz, without noticeably affecting the vibrations at lower frequencies that are important for driving behavior. Finally, it was essential to avoid a noticeable increase in the weight of vehicle tires because the general trend in motor vehicle construction is to save weight in order to improve economy in terms of fuel consumption.

The invention relates to a pneumatic vehicle tire in which a structure-borne sound-damping, cross-linked polyurethane foam material which has an E-modulus of less than 5 × 10 ⁵ N/m ² (measured dynamically on the foam), a density of 35 to 300 kg/m ³ and an air flow resistance of 80 to 150 Rayl/cm (8 × 10 ⁴ to 15 × 10 ⁵ Ns/m ⁴ ) in the temperature range from -20 to +80 ° C is applied to the inside of the tread and/or the inside of the side walls of the tire in a layer thickness of 15 to 50 mm.

The air flow resistance of the foam material is measured according to DIN 52 213. The layer thickness of the foam material is preferably about 20 to 30 mm.

The density of the foam is preferably between 50 and 150, for example 100 kg/m ³ . The desired density can be adjusted in a known manner by adding inorganic fillers such as soot, chalk, slate powder, kaolin, barium sulfate and others.

The elastic modulus of the foam (according to DIN 53 426, measured dynamically on the foamed material) should not exceed 5 · 10 ⁵ N/m ² and should preferably be between about 10 ⁵ and 5 · 10 ⁵ N/m ² .

The foam material can be subsequently applied to the inside of the finished pneumatic vehicle tire. It is essential for the foam to be firmly bonded to the inner surfaces, as a loosely inserted foam material does not provide the desired structure-borne sound insulation. On the other hand, it is also possible to create an integrated foam layer with the required material properties by foaming the inner surfaces of the tire during tire manufacture. This can then be cut to the desired dimensions and at the same time freed from the outer skin in order to achieve the required permeability.

It is known that effective structure-borne sound insulation requires coatings made of viscoelastic materials. However, such materials are unsuitable for the present application because of the strong influence of temperature on their stability. It is completely surprising and not entirely explainable on the basis of the current state of knowledge that effective structure-borne sound insulation can be achieved in pneumatic vehicle tires using a non-viscoelastic foam material, as the measured values in the following examples show. The fact that the observed effect is actually structure-borne sound insulation and not absorption of airborne sound inside the tire is demonstrated by the fact that a foam material loosely inserted into the tire but in contact with the inner surfaces has only a small effect and that a firm connection between the foam and the inner surfaces of the tire (e.g. by gluing) is essential for success.

The invention is particularly suitable for tubeless tires, but tubes can also be inserted under certain circumstances without losing the effect. The following example will serve to explain the invention in more detail, the results of which are shown graphically in the figures.

Example

Flexible foam films of different thicknesses made of cross-linked polyurethane were used, which had the following characteristics: &udf53;np130&udf54;&udf53;vu10&udf54;&udf53;vz12&udf54;

Attempt 1

Fig. 1 shows the loss factors as a function of frequency for the foam sheets A, B, C and D at 20°C and a layer thickness of 30 mm each. It is clear that with the materials A and B to be used according to the invention, a significantly higher loss factor is achieved in the frequency range of primary interest above 500 Hz than with the materials C (with too high an elastic modulus and air flow resistance) and D (with too low a density and too low an air flow resistance).

Attempt 2

The measured values shown in Fig. 2 for the tire covered with foam material B show the extremely low temperature dependence of the damping, which is essential for practical use; the measured values at 20 and 80°C are almost identical.

Attempt 3

The foam material B was used in layer thicknesses of 20, 30 and 40 mm. The measured values shown in Fig. 3 show a certain shift towards lower frequencies as the layer thickness increases, but it is clear that a layer thickness of about 30 mm is sufficient to achieve considerable damping in the particularly important frequency range above 500 Hz. In contrast, with a layer thickness of 4 mm, a loss factor of more than 0.01 is not achieved at any frequency, as a comparative measurement showed.

Attempt 4

The sound insulation achieved on tires was measured on an acoustic test bench at room temperature on a steel roller at 100 km/h. A commercially available untreated tubeless tire (size 155 SR 13 on 5 inch rims) had a noise level of 99.6 dB(A). Covering the inside of the tread with a 40 mm thick foam film B reduced the level to 95.8 dB(A). Covering the entire tread with a 30 mm thick film of material B reduced the level further to 93.6 dB(A). The measurement was taken at a height of 420 mm and a distance of 560 mm from the tire.

Claims (4)

1. Pneumatic vehicle tyre, the inner surfaces of which are completely or partially provided with a noise-reducing coating made of open-cell foam, characterized in that a structure-borne sound-damping cross-linked polyurethane foam material is applied to the inner side of the tread and/or the inner sides of the side walls of the tyre, which in the temperature range between -20 and +80°C has an E-modulus of less than 5 × 10 ⁵ N/m ² (measured dynamically on the foam), a density of 35 to 300 kg/m ³ and an air flow resistance of 80 to 150 Rayl/cm (8 × 10 ⁴ to 15 × 10 ⁵ Ns/m ⁴ ), is applied in a layer thickness of 15 to 50 mm. 2. Pneumatic vehicle tire according to claim 1, characterized in that the foam material has a layer thickness of about 20 to 30 mm. 3. Pneumatic vehicle tire according to one of claims 1 or 2, characterized in that the foam material subsequently applied to the inside of the tire is firmly connected, preferably glued, to the inner surfaces. 4. Pneumatic vehicle tire according to claims 1 or 2, characterized in that the tire inner surfaces are provided with an integrated foam layer produced during tire manufacture.