NZ214683A - Tyre tread:spacing of varying sized blocks in adjacent lines staggered - Google Patents

Description

2 1468 Priority Date(s) Complete Specification Filed:"^.

Class- 0<(/ IL i^iaodi r» 1 < 1 • 1 1 Mi » »/• Publication Date: .......^.I.tVl?.!*???:. ;P.O. Journal, No: • ;n ;PATENTS FORM NO. 5 ;NEW ZEALAND PATENTS ACT 1953 COMPLETE SPECIFICATION ;LOW NOISE TIRE ;X, WE SUMITOMO RUBBER INDUSTRIES, LTD. of No. 1-1, Tsutsuicho 1-chome, Chuo-ku, Kobe-shi, Hyogo, Japan, ;v a Japanese company ;'O ;hereby declare the invention, for which i/we pray that a patent may be granted to mo/us, and the method by which it ^ is to be performed, to be particularly described in and by the following statement ;-1- ;v'C.*," VJ-; '■ 'M y1 i i <J 2 146 The present Invention relates to tires for motorcycles, passenger I cars, trucks, and buses which, as compared with conventional ones, | generate less noi3e when they come into contact with the road, j (Prior Art) The tread of conventional tires has a pattern consisting of design elements or unit blocks which continuously repeat in the circumferential direction of the tire. This tread pattern causes air in the groove of the tread to be compressed and relieved as the tire turns. The repeated compression and relieve of air form the compressional wave of air which is audible pattern noise or impacting noise. This noise becomes amplified when it resonates with some parts of the vehicle. It is known that this kind of noise can be reduced when the noise frequency is distributed over a broad range and the resonance is prevented. And this is j accomplished by changing the tread design such that the repeating constituent units are arranged at varied pitches. This is known as the variable pitch method. According to this method, the design elements are arranged in the circumferential direction of the tire at several different pitches, so that the time interval of pulse noise or vibration is changed and noise of specific frequency is not generated when the \i -J ij tire comes into contact with the road and leaves the road. However, the variable pitch method is not necessarily satisfactory. Even though the variable pitches for the design elements are properly dispersed according to the frequency modulation theory, they do not reduce the sound pressure energy per se. Moreover, if the difference between the longest pitch and the shortest pitch is excessively great, the individual design elements differ in stiffness. This, in turn, adversely affects the 214583 vibration characteristics of the tire revolutions and causes uneven wear and abrasion. It is known that if the variable pitches are arranged regularly in a specific manner, the tire generates noise offensive' to the ear.

(Problems to be solved) It is an object of the present invention to provide a low-noise tire which has a decreased low noise level, solving the above-mentioned problems and without sacrificing the fundamental characteristics of the tire tread such as resistance to uneven wear and abrasion.

(Technical Means to Solve the Problems) According to one aspect of the present invention there is provided a low-noise tire which comprises a plurality of block lines which run in the circumferential direction of the tire, said block lines including a primary block line made up of discrete blocks arranged at a uniform pitch in the circumferential direction of the tire and phase-difference secondary block lines each made up of discrete blocks arranged such that the phase in the circumferential direction is shifted with respect to that of the discrete blocks in said primary block line, the phase difference varying from one discrete block to the adjacent one in the circumferential direction, the length of each discrete block in said primary block line being smaller than that of each discrete block in said phase-difference block lines.

The invention is now described with reference to the drawing illustrating one example of the invention.

Fig. 1 shows a tread pattern composed of a primary or basic block line (A) and secondary phase-difference block lines (B and C) placed on both sides of the basic - 3 - l'y i: ~9FEL1?C7 t a, 2 14623 block line. The basic block line is made up of unit blocks (A1, A2, A3, >- t- ; ...) which are arranged at a uniform pitch along the equator of the | i tire. Each of the phase-difference block lines is made up of unit blocks which are shifted in the circumferential direction with respect to the individual unit blocks in the basic block line. The unit block (B1) in the phase-difference block line (B) is shifted by S in the circumferential direction with respect to the unit block A1 in the adjacent basic block line (A). The unit block (B2) is shifted by M in the circumferential direction with respect to the unit block (A2) in the J C_y adjacent basic block line (A). Furthermore, the unit block (B3) is shifted by L in the circumferential direction with respect to the unit block (A3) in the basic line (A) in the same manner as mentioned above. , i | A relationship of S<M<L is established among the shifts, and these three I different shifts are repeated regularly or randomly in the circumferen- i tial direction. On the other hand, the unit block (C1) constituting the i1 phase-difference block line (C) is shifted by m with respect to the unit V; block (A1) in the basic block line; and the unit block (C2) is shifted -J by n with respect to the unit block (A3), m and n should not be the -C same, and it is also possible to arrange unit blocks having a phase ' ^ difference which is different from m and n.

The arrangement of the phase-difference block lines on both sides of the basic block line permits the blocks to come into contact with the . road rather randomly. Three kinds of shifts are used in the phase-difference block line (B) as mentioned above; but two kinds of shifts or more than three kinds of shifts may be used as required. The length - U - ~ . . - '■ ''ILL j I I I i | 2 1468 (Ac) of the individual blocks (CI, C2) in the phase-difference line (C) may be greater than the length (4a) in the circumferential direction of the unit block (An) in the basic block line. In this case, the tread will be improved in wear resistance. Table 1 below shows the actual dimensions employed for a 4.60-18 tire.

Table 1 Basic block line A la. mm Groove distance D mm Phase-difference -block line B Jtb 28 mm S mm M mm L mm Phase-difference block line C Jlc 33 mm m mm n mm Fig. 2 shows another example of this invention.

The tread pattern is composed of a basic block line (A) and phase-difference block lines (F and G) arranged on both sides of the basic block line (A). The basic block line (A) is made up of unit blocks (El, E2, E3, •••) arranged at a uniform pitch in the circumferential direction. Each of the phase-difference block lines is made up of unit blocks which are shifted in the opposite direction with respect to the individual unit blocks in the basic block line. The unit blocks (F1 , F2,. and F3) in the phase-difference block line (F) are shifted downward by S1, M1, and L1, respectively, with respect to the unit blocks (El, E2, and E3) in the basic block line (E), whereas the unit blocks (G1, -214683 G2, and G3) in the phase-difference block line (G) are shifted upward. The unit blocks should be constructed such that S1 « S2, M1 = M2, and L1 » L2 and that the length £e in the circumferential direction of the unit blocks (E1, E2, and E3) in the basic block line is smaller than the length in the circumferential direction of the unit blocks (FT, F2, F3, ...) and the unit blocks (G1, G2, G3( ...) in the respective phase-difference block lines (F and G). Table 2 below shows the actual dimensions employed for a 4.60-18 tire for motorcycles.

Table 2 Basic block line E £.e : 25 mm width Wl: 20 mm Phase-difference block lines F and G If, Zg : 28 mm width W2, W3 : 20 mm Blocks F SMLMSMLMSMLM Blocks G -S -M -1 -M -S -M -L -M -S -M -L -M Phase difference 5 10 15 10 5 10 15 10 5 10 15 10 Number of blocks 62565441 45 6 3 Eft /X 3 0 '~ \ V I - 9 FEB 1987r' 214383 Example A 4.60-18 tire for motorcycles having the tread pattern as specified in Table 1 was made for trial, and for comparison, a tire of 'the same size having the tread pattern as shown in Fig. 3 was made for trial. Noise test was conducted according to the tire noise test method provided in JAS0.C606 under the conditions of air pressure 1.75 kgf/cm2 and load 100 kgf. A sound collecting microphone was placed just beside the tire 50 cm away from the center of the tire width and 25 cm above the contacting surface. The test tire was turned on the drum installed in an anechoic r_oom. Incidentally, the tires used in the example and comparative example are the same in tread pattern except the phase difference.

It was found that the tire of this invention has a lower noise level than that used in the comparative example, as shown in Fig. 4.

(Effect of the Invention) In the case of a tire having the tread pattern composed of a plurality of block lines, the sound resulting from the road contacting of blocks is made to have different frequencies if the arrangement of unit blocks are shifted from one another. This leads to a decrease in absolute value of noise level and a dispersion of noise frequencies. 4. Brief Description of the Drawings: Figs. 1 and 2 are partial plan views of the tread of the tire of this invention. Fig. 3 is a partial plan view of the tread of a conventional tire. Fig. 4 is a graph showing the relationship between the speed and the noise level. 214083

Claims (1)

1. WHAT WE CLAIM IS: (1) A low-noise tire which comprises a plurality of block lines which run in the circumferential direction of the tire, said block lines including a primary block line made up of discrete blocks arranged at a uniform pitch in the circumferential direction of the tire and phase-difference secondary block lines each made up of discrete blocks arranged such that the phase in the circumferential direction is shifted with respect to that of the discrete blocks in said primary block line, the phase difference varying from one discrete block to the adjacent one in the circumferential direction, the length of each discrete block in said primary block line being smaller than that of each discrete block in said phase-difference block lines. (2) A low-noise tire as set forth in claim 1, wherein the pitch of the primary block line is greater than the length of each block in the phase-difference block lines. (3) A low-noise tire as set forth in claim 1, wherein three phase differences are provided in at least one of said phase-difference block lines. (4) A low-noise tire arranged, constructed and adapted to operate substantially as hereinbefore described with reference to either of the embodiments defined in Table 1 or Table 2 and/or shown in Figure 1 or Figure 2 of the accompanying drawings. CALDlViN, S0!\| & CAREY ATTORNEYS FOR THE APPLICANTS