SE506671C2 - Pneumatic tire - Google Patents

Abstract

The pneumatic tyre main running surface has two or more main peripheral grooves (G01,G02) and axial ones defining heel sections (SB) at opposite edges. Peripheral ribs (ES,S) at the edges divide the heel sections into two or more axial parts.The rib width is between 0.2 and 1.5 mm.

Description

506 671 in '2 are quite large, the shoulder of the tread has deteriorated laterally, thereby effectively preventing the vehicle from moving. However, since the narrow lugs (b) are easily moved and this movement is very large due to the width of the large grooves, the edges of the narrow lugs can not have an effective grip. Furthermore, the narrow heels (b) will wear out quickly and give an uneven wear. In addition, there is a risk that the narrow lugs (b) will be torn off. It is therefore an object of the present invention to provide a pneumatic tire in which, by utilizing circumferentially extending channels and then specifically defining their positions and dimensions, for example width, depth and the like, the resistance to lateral slip on snowy / icy roads are improved without sacrificing resistance to uneven wear, tread life or resistance to tearing.

In accordance with one aspect of the present invention, a pneumatic tire comprises a tread portion provided with at least two main circumferential grooves and axial grooves for defining tread lugs, which are arranged in at least two circumferentially extending rows, each of the tread lugs in said at least two circumferentially extending rows are provided with at least one siphon extending in the circumference of the tire to divide the lug into at least two axial portions, the siphon having a width of 0.2 to 1.5 mm.

An embodiment of the present invention will now be described in detail in connection with the accompanying drawings, in which: Figure 1 is a developed plan view of the tread portion of a double truck tire / bus tire, in accordance with the present invention; Figure 2 is a cross-section through the tire; 10 15 20 25 30 35 * sne 671 3 Figure 3 is an enlarged perspective view showing a shoulder portion of the tire tread; Figure 4 is a plan view showing a modification of the tread pattern: Figures 5-9 are curves showing test results; and Figure 10 is a perspective view showing a shoulder portion of the tread, in accordance with the prior art.

In Figures 1-3, a pneumatic tire 1 comprises a tread portion 12 with a tread surface 2 having a pair of edges E, a pair of axially spaced tire foot portions 14, a pair of tire side portions 13 extending between the tread edges E and the tire foot portions 14, a tire foot core 15 disposed in each tire foot portion 14, a toroidal cord 16 extending between the tire foot portions 14 and folded around the tire foot cores 15 and a belt 19, 16 and within the tread portion 12 disposed radially outside the cord. 16 comprises at least one belt bearing of a radial or semi-radial construction. In this embodiment, the cord layers of the cords are arranged radially at 70 to 90 degrees with respect to the tire's equator C.

For the cord layers of the cords, steel cords and cords of organic fibers, for example nylon, polyester, rayon, aromatic polyamide and the like, can be used.

The belt 19 comprises 2 or more layers, belt cords are inserted parallel to each other but in crosses in which against the cords in the next layer. In this embodiment, the belt 19 consists of three crossed layers.

For belt cords, steel cords, cords of organic fibers, for example nylon, polyester, rayon, aromatic polyamide and the like can be used.

The above-mentioned tread portion 12 is provided in the tread surface 2 with wide main circumferential grooves GO, which extend continuously around the tire. In this example, the main circumferential groove G0 comprises a central, zigzag-shaped groove 6, which is arranged at the tire equator C, two axially oriented, outermost straight grooves G02, which are arranged one on each 506 671 10 15 20 25 30 35 4 and two middle, straight grooves G01, each of which is arranged between the grooves 6 and the grooves side of the tire equator, G02, whereby the tread portion is divided into six axially extending portions. The six axial portions are circumferentially divided by means of axial grooves (g), which extend from the edges E of the tread to the outermost axial main circumferential grooves G02, and axial grooves extend between the adjacent, wide main circumferential grooves G0.

Thus, the tread pattern in this embodiment is a heel pattern, which consists of heels B, which are arranged in six circumferential rows.

The above-mentioned paired grooves G02 and G02 are located in symmetrical axial positions with respect to the tire equator C, and also the paired grooves G01 and G01 are located in symmetrical axial positions.

Each of the axial grooves, including the outermost grooves (g) in the axial direction, is bent in the middle. The axial grooves are arranged in such a way that, in the radial direction of the tire, the grooves can generally be regarded as extending continuously from one edge E of the tread to the other edge E of the tread in a zigzag shape. All the resulting zig-zag grooves, which extend across the entire width of the tread, are parallel to each other and slope in one direction (in Figure 1 in an upward slope to the left). In this embodiment, however, on both sides of each axially circumferential circumferential groove G02, the axial grooves are reversed slightly in the circumferential direction of the tire, as shown in Figure 1.

Thus, between each outermost circumferential groove G02 and the adjacent edge E of the tread, a row SBA of shoulder heels SB is formed.

Furthermore, a row SA of centrally arranged tread lugs 5 is formed between each central circumferential groove G01 and the adjacent, extreme circumferential groove G02.

Furthermore, a row 4A of centrally arranged tread lugs 4 is formed on each side of the tire equator C between the centrally arranged circumferential grooves G01 and G01. Since the shoulder lugs SB are delimited by the straight circumferential groove G02, the tread edge E and the bent, axial grooves (g), each shoulder lug SB in this embodiment has two straight side edges and two bent front edges. / rear edges.

The circumferential distribution of the axial grooves (g) is such that the circumferential length L of the shoulder lug, measured along the axially inner side edges, is 3.0 to 20.0 times the groove width GW for the adjacent main circumferential groove G or for the outermost main circumferential groove G02.

The groove depth gH of the axial grooves is preferably more than 0.40 times and not more than 1.0 times the groove depth GH of the wide main circumferential grooves G0.

Each shoulder lug SB is axially divided by a narrow shoulder circumferential groove GB into an axial outer shoulder lug portion SBI and an axial inner shoulder heel portion SB2.

The narrow circumferential narrow shoulder groove GB is a straight groove extending parallel to the edge E of the tread from the leading edge of the shoulder lug SB to its trailing edge and arranged so that the axial width WSB1 of the outer shoulder lug portion SB1 in the axial direction is 0, 06 to 0.25 times the half width TW of the tread between the equator C of the tire and one edge E of the tread

In this embodiment, the width WSB1 is constant in the circumferential direction of the tire, but it can be varied.

If the width WSBI is less than 0.06 times the half width TW of the tread, the axial stiffness of the axially outer shoulder heel portion SB1 decreases and there is a risk of uneven wear occurring. If the width WSBI is more than 0.25 times TW, the stiffness increases, which reduces the effect of the sipping edge on the axially outer shoulder heel portion.

As a result, there is a risk of slipping sideways and hiking.

The narrow groove width of the narrow, circumferentially extending shoulder groove of the shoulder groove is in the range 1.5 to 2.5 mm. In this example, the width is constant in the circumferential direction of the tire and in its direction in the depth direction. 506 671 * 10 15 20 25 30 35 6 The average circumferential depth BH of the narrow, circumferentially extending shoulder groove GB is 0.3 to 1.10 times the groove depth GH of the wide main circumferential grooves G0, preferably 0.4 to 0.7 times GH. If the depth BH is less than 0.3 times the depth GH of the main groove, the stiffness of the axially outer shoulder heel portion SBI will not be lowered, and the resistance to lateral slipping and the resistance to hiking will be lowered. If, in contrast, the depth BH is more than 1.10 times the depth GH of the main groove, the rigidity of the axially outer shoulder heel portion SB1 will be excessively lowered and there is a risk of uneven wear.

The axially outer shoulder lug portion SB1 is provided with at least one edge taping ES, which extends circumferentially parallel to the edge E. of the tread. In this embodiment, two edge tapings ES and ES are evenly arranged in the width direction of the axially outer shoulder lug portion SB1 to divide this section into three axial areas, which have essentially the same width.

The width of the edge tape's ES is smaller than the narrow, circumferentially extending shoulder groove GB and is in the range 0.2 to 1.5 mm, preferably less than 0.7 mm.

The average depth EH of the edge taping EH is 0.25 to 1.25 times the narrow, circumferentially extending shoulder groove GB average depth BH. In this example, EH is approximately 0.8 times BH. If the depth EH is less than 0.25 times the depth BH, the axial stiffness of the axial outer shoulder heel portion SB1 will increase to lower the lateral slip resistance and the travel resistance. If the depth EH is more than 1.25 times the depth of the bra, the stiffness will decrease and there is a risk that cracks will appear at the bottom of the sap, which results in tearing of the tread rubber and thereby a reduction in the life of the tread. .

In this embodiment, the depth of the edge of the edge tapping and the depth of the narrow, circumferentially extending shoulder groove GB are constant in their longitudinal directions. But the depth can be varied.

Furthermore, the tread portion 12 is provided with a plurality of groove side grooves S on at least one side of each of the main circumferential grooves G0 arranged symmetrically and in pairs.

Each groove side groove S is separated from the main circumferential groove by an axial distance (l) of 0.06 to 0.25 times the half width TW of the tread.

The groove side tapping S extends parallel to the main circumferential groove G0 or slopes at a small angle of not more than 5 degrees with respect to the main circumferential groove G0.

In this embodiment, thereby, on both sides of each of the axially outermost grooves G02, uninterrupted and straight cuts are arranged as groove side grooves S in the shoulder lugs SB and the middle tread lugs 5. The groove side groove S in the shoulder heel SB is located shoulderwise in the shoulder to further divide this portion SB2 into a wide main area B2 and a narrow side area Bl. The width Sw and depth of the groove side s are constant along its length, but they can be varied within the respective areas.

The width SW of the track siding is in the range 0.2 to 1.5 mm, preferably less than 0.7 mm.

The mean depth SH of the groove side tapping S is 0.25 to 1.0 times the groove depth GH of the main circumferential grooves G0. In this example, SH is approximately 0.5 times GH. If the depth SH is less than 0.25 times the depth GH, the lateral slip resistance will be greatly reduced. If the depth SH is more than 1.0 times the depth GH, the stiffness of the narrow lateral area B1 in the axial direction will decrease to lower the resistance to lateral slippage, and there is a risk that tearing of the tread pattern will occur to reduce tread life.

The length of the narrow side area B1 in circumferential direction L is, as explained above, 3.0 to 20.0 times the groove width GW of the adjacent main circumferential grooves G02. If the length L is less than 3.0 times the width GW, the resistance to lateral slippage will be greatly reduced. If the length L is more than 20.0 times the width GW, when the pitch circumference of the axial grooves g is increased, the tensile force, braking force and drainage will deteriorate.

Since the central tread blocks 5 are also provided with groove side grooves S in this embodiment, each central tread lug is axially divided into a wide main area B2 and a narrow side area B1 adjacent to the main groove G02 similar to the shoulder heels SB.

Furthermore, each shoulder lug SB in only the wide main area B2 is provided with circumferentially spaced sutures LS. The axial grooves LS in each main circumferential region B2 extend from the narrow, circumferentially extending shoulder groove GB to the groove side groove S, parallel to each other and parallel to the front / rear heel edges or the axial grooves (g). Thus, the axial grooves LS are bent in the same way as the axial grooves (g).

It is preferred that no axial suture be formed in the axially outer shoulder lug portion SB1 and the narrow side region B1 to maintain its rigidity. However, if the pitch of the axial grooves were large and thus the length of the narrow side area, a pitch of two or more could meet the above condition, an axial sizing could be provided, for example as shown in Figure 4. In Figure 4, only the narrow side area B1 is provided at its center with an axial sizing RS.

In the embodiment shown in Figures 1-3, each of the central tread lugs 4 and the middle tread lugs 5, with the exception of their respective narrow axial side areas B1, are provided with similar and bent, sutures LS, which extend over the heels parallel to each other and parallel to the axial grooves.

In the present invention, the groove side grooves may be formed on one side or both sides of each main circumferential groove G01 so as to define a narrow side region B1 in the adjacent tread lug.

Test tires of dimension 10,00R20 with the tread pattern and tire construction shown in Figures 1-3, and have been prepared as an example by changing only the following parameters: the width WSB1 of the axially outer shoulder lug portion SB1; the deep bra of the narrow, circumferentially extending shoulder groove GB; the depth EH of the circumferentially extending edge seam ES; the track depth SH of the track side tapping S; the depth gH of the axial grooves (9): the groove width Sw of the groove side tapping S; and the circumferential length L of the narrow side region B1, and the tires were tested for lateral slip.

When driving a test vehicle on an icy test track, the slip performance of each test tire was evaluated by a test driver. The test tires were mounted on their standard rims with the size 7.00T and inflated to an internal pressure of 8.0 kg / cmz. The tire load was 2700 kg.

The test results have been indicated in Figures 5-9, in which the results have been indicated by an index. The larger the index, the better the lateral resistance.

Figure 5 is a graph showing the lateral slip as a function of the ratio WSB1 / TW for the width WSBI of the axially outer shoulder lug portion SBI divided by the half width TW of the tread. (BH / GH = 0.8 and EH / BH = 1.0.) Figure 6 is a graph showing lateral slip as a function of the quotas BH / GH and EH / BH; the ratio BH / GH for the groove depth BH of the narrow circumferentially extending heel groove GB divided by the groove depth GH of the wide main circumferential groove G, and the ratio EH / BH for the groove depth EH of the circumferentially extending edge tapping ES divided by the groove depth BH circumferentially extending shoulder track GB. 10 15 20 25 30 35 671 10 Figure 7 is a graph showing the lateral slip as a function of the ratio SH / GH for the groove depth SH of the groove side sap divided by the groove depth GH of the wide main circumferential grooves GO. (gH / GH = 0.8, SW = 0.6 mm and 1 / GW = 1.0.) Figure 8 is a graph showing lateral slip as a function of the ratio gH / GH for the groove depth gH of the the grooves (g) divided by the groove depth GH of the wide main circumferential grooves G0. (SH / GH = 0.8, SW = 0.6 mm and 1 / GW = 1.0.) Figure 9 is a graph showing the lateral slip as a function of the width Sw of the groove side sap S and the ratio L / GW for the length in circumferential direction L of the narrow side area B1 divided by the track width GW of the wide main circumferential grooves G0.

These tests confirmed that the tires of the present invention were superior in lateral slip resistance.

As explained above, the lateral slip resistance while driving on snowy and icy roads has been improved with the tires of the present invention, while maintaining the driving force and braking force.

Furthermore, the migration phenomenon has been improved by lowering the stiffness of the tread shoulder laterally. In addition, the movement of the axial ends of the circumferential portions of the shoulder heels, which are divided by the axial sutures, has been limited by a direct support of the adjacent circumferentially extending heel portion and an indirect support through their existence, whereby uneven wear and tear of rubber in the tread has been reduced and thus the service life has been improved.

Claims (3)

10 15 20 25 30 35 01 CD O \ O \ \ J ... à ll PATENTKRAV A pneumatic tire comprising a tread portion with a pair of tread edges (E), said tread portion being provided with at least two main circumferential grooves (G01, G02) and axial grooves for defining tread lugs, which are arranged in at least two circumferential rows, each tread lacquer said at least two circumferential rows are provided with at least one sap (ES, S) extending in the circumferential direction of the tire to divide the lug into at least two axial portions, each sap (ES, S) having a width of 0.2 to 1.5 mm, said tread lugs are shoulder lugs (SB), characterized in that: which are arranged between each axially articulated outer circumference groove (G02) and each tread edge (E), each shoulder lug (SB) is provided with a narrow, in circumferentially extending shoulder grooves (GB) to axially divide the heel (SB) into an axial outer shoulder heel portion (SB1) and an axial inner shoulder heel portion (SB2), the axial width (WSB1) of the axial The outer shoulder heel portion (SB1), measured from the tread edge (E) to said narrow shoulder groove (GB), is 0.06 to 0.25 times the width of the tread (TW), between the outer tread edge (E) and circumferentially the equator (C) of the tire extending, the mean groove depth (BH) of the narrow circumferentially extending shoulder groove (GB) is 0.3 to 1.10 times the groove depth (GH) of the main circumferential grooves, the at least one grouting (ES) being arranged in the axially outer shoulder lug portion (SB1), the average depth (EH) of each of said at least one groove (ES) is 0.25 to 1.25 times the average groove depth (BH) of the narrow circumferentially extending shoulder groove (GB); ). 596 10 15 20 25 30 35 671 12 Pneumatic tire according to claim 1, characterized in that: said main circumferential grooves are two main circumferential grooves (G02), which are arranged in symmetrical axial positions with respect to the tire equator (C), each of said two main circumferential grooves (G02) defining a circumferential row of tread lugs (SB), which are arranged next to the groove (G02) and on one side of the groove (G02), each of the tread lugs (SB) is provided with a sawing (S), which extends uninterrupted substantially parallel to the main circumferential groove (G02) to divide the lug (SB) into a wide main area (B2) and a narrow side area (B1) on the side of the main circumferential groove, the circumferential length (L) of the narrow side area (B1) is more than 3.0 times and less than 20.0 times the groove width (GW) of the main circumferential grooves (G02), the mean depth (SH) of each of the grooves (S) is 0.25 to 1.0 times the groove depth (GH) of the main circumferential grooves, groove depth (gH) of the axial grooves (g) is more than 0.40 and not more than 1.0 times the groove the depth (GH) of the main circumferential grooves. Pneumatic tire according to claim 3, in that the wide main area is circumferentially separated and characterized (B2) is provided with a plurality of, axially extending, axial seals (LS).