Pneumatic tire

Abstract

An object is to enhance traction performance and handling stability performance, these being related to braking performance and acceleration performance on snowy road surfaces. A tread (12) of a pneumatic tire (10) includes: two circumferential direction main grooves (14) that are formed further to the tire width direction inside from the tread (12) ground contact edge T than positions at ⅓ of the ground contact width W and that extend along the tire circumferential direction; a central land portion row (16) formed between the two circumferential direction main grooves (14); edge land portion rows (18) respectively formed at tire width direction outsides of the two circumferential direction main grooves (14; and main lug grooves (20) extending in the edge land portion rows (18) from the circumferential direction main grooves (14) towards the ground contact edges T. The edge land portion rows (18) are not formed with main grooves that place tire circumferential direction neighboring main lug grooves (20) in communication with each other.

Claims

1. A pneumatic tire with a tread, the tread comprising: two circumferential direction main grooves that are formed further to a tire width direction inside, from a tread ground contact edge, than positions at ⅓ of a ground contact width, and that extend along a tire circumferential direction; a central land portion row formed between the two circumferential direction main grooves; edge land portion rows respectively formed at tire width direction outsides of the two circumferential direction main grooves; main lug grooves extending in the edge land portion rows from the circumferential direction main grooves towards the ground contact edges, opening onto the circumferential direction main grooves in an inclined state with respect to the tire width direction; first auxiliary grooves that, at opening positions of the main lug grooves onto the circumferential direction main grooves, are inclined in an opposite direction to the main lug grooves with respect to the tire circumferential direction, so as to intersect with the direction of the main lug grooves, are formed from the edge land portion rows into the central land portion row so as to extend across the circumferential direction main grooves, and do not open onto the main lug grooves, tire width direction central side end portions are positioned in the vicinity of the tire equatorial plane, and tire width direction outside end portions terminate in the edge land portion rows; second auxiliary grooves that are inclined with respect to the tire circumferential direction, each with one end that opens onto the neighboring main lug groove and another end that terminates inside the corresponding edge land portion row, wherein the edge land portion rows are not formed with main grooves that place tire circumferential direction neighboring main lug grooves in communication with each other.

2. The pneumatic tire of claim 1, wherein the angle of inclination of the main lug grooves with respect to the tire circumferential direction is from 85 degrees to 30 degrees.

Description

BRIEF DESCRIPTION OF DRAWINGS

(1) FIG. 1 is a plan view illustrating a tread pattern of a pneumatic tire according to a present exemplary embodiment.

(2) FIG. 2 is a plan view illustrating a tread pattern of a pneumatic tire according to a conventional example.

DESCRIPTION OF EMBODIMENTS

(3) Explanation follows regarding an exemplary embodiment of the present invention, with reference to the drawings. FIG. 1 illustrates a pneumatic tire 10 of the present exemplary embodiment with a tread 12 that is a tread face portion including plural circumferential direction main grooves 14, a central land portion row 16, edge land portion rows 18, and main lug grooves 20.

(4) Two of the circumferential direction main grooves 14 are formed extending along the tire circumferential direction further to the tire width direction inside, from tread ground contact edges T of the tread 12, than positions at ⅓ of the ground contact width W. Note that the “ground contact edges T” are the tire width direction outermost edge portions of a ground contact region when the pneumatic tire 10 is mounted to a standard rim, as defined in the JATMA YEAR BOOK (2010 edition, Japan Automobile Tire Manufacturers Association standards), inflated to an internal pressure (maximum pressure) of 100% pressure corresponding to the maximum load (load shown in bold in the internal pressure-load correspondence table) for the internal pressure for the applicable JATMA YEAR BOOK size/ply rating, when the maximum load is applied thereto. Where the location of use or manufacturing location use TRA standards or ETRTO standards, then these respective standards are adhered to.

(5) The central land portion row 16 is for example formed at a tire width direction central portion including a tire equatorial plane CL between the two circumferential direction main grooves 14. The central land portion row 16 is formed with fine grooves 22 and auxiliary grooves 30, described later. The fine grooves 22 are for example formed running along the extension directions of the auxiliary grooves 30 from terminal portions of the auxiliary grooves 30 inside the central land portion row 16 to the circumferential direction main grooves 14.

(6) The edge land portion rows 18 are respectively formed to the tire width direction outsides of the two circumferential direction main grooves 14. The edge land portion rows 18 are formed with auxiliary grooves 24 that are slightly inclined with respect to the tire circumferential direction, with one ends 24A that open onto the neighboring main lug grooves 20 and other ends 24B that terminate inside the corresponding edge land portion rows 18. The groove width of the auxiliary grooves 24 is set smaller than that of the circumferential direction main grooves 14, and is for example configured so as to be widest at the one ends 24A, gradually decreasing on progression towards the other ends 24B.

(7) The edge land portion rows 18 are not formed with main grooves that place the tire circumferential direction neighboring main lug grooves 20 in communication with each other. Since the auxiliary grooves 24 do not open onto neighboring main lug grooves 20 around the tire circumferential direction, the rigidity of the land portions is not degraded, thereby enabling a drop in braking performance and acceleration performance to be prevented. Moreover, since the auxiliary grooves 24 do not open onto neighboring main lug grooves 20 around the tire circumferential direction, edges are formed from the circumferential direction main grooves 14 as far as the ground contact edges T of the tread 12, giving good traction over snow.

(8) Note that sipes 26 may be provided between the other ends 24B of the auxiliary grooves 24 and the neighboring main lug grooves 20 on the side of the other ends 24B, as shown by the double-dotted dashed lines. The sipes 26 are for example configured with a groove width that is a zero groove width when the tread 12 makes ground contact, or may be configured in slit shapes that do not have a groove width. The sipes 26 enable water discharge performance to be raised. Note that configuration is made such that when running over snowy road surfaces, snow inside the auxiliary grooves 24 is not able to escape through the sipes 26 into the main lug grooves 20, so there is no drop in traction performance.

(9) The main lug grooves 20 extend from the circumferential direction main grooves 14 towards the ground contact edges T in the edge land portion rows 18, and for example open onto the circumferential direction main grooves 14 in a state inclined with respect to the tire width direction. An angle of inclination θ of the main lug grooves 20 with respect to the tire circumferential direction is for example from 85 degrees to 30 degrees. Note that the maximum value for the angle of inclination of the main lug grooves 20 with respect to tire circumferential direction is set at 85 degrees since above this value, a water discharging effect of the main lug grooves 20 obtained due to rotating in a single direction only is degraded. The minimum value for the angle of inclination is set at 30 degrees since below this value, an edge effect with respect to input along the tire equatorial plane direction arising during acceleration and braking becomes insufficient.

(10) Step portions 28 are formed to the main lug grooves 20 at positions opposing to the one ends 24A of the auxiliary grooves 24. The step portions 28 suppress movement of snow inside the main lug grooves 20 when running on snowy road surfaces, and also enable snow to be compacted between the step portions 28 and the auxiliary grooves 24.

(11) The auxiliary grooves 30 are formed at the opening portions of the main lug grooves 20 onto the circumferential direction main grooves 14. The auxiliary grooves 30 are inclined in an opposite direction to the main lug grooves 20 with respect to the tire circumferential direction so as to intersect with the direction of the main lug grooves 20. The auxiliary grooves 30 are formed from the edge land portion rows 18 into the central land portion row 16 in for example a straight line shape so as to extend across the circumferential direction main grooves 14.

(12) Tire width direction central side end portions of the auxiliary grooves 30 are for example positioned in the vicinity of the tire equatorial plane CL. The width direction outside end portions of the auxiliary grooves 30 are for example positioned extending towards the step portions 28 of the main lug grooves 20, however the auxiliary grooves 30 do not open onto the main lug grooves 20 or the auxiliary grooves 24, but terminate in the edge land portion rows 18. The rigidity of the land portions is accordingly not degraded, enabling a drop in braking performance and acceleration performance to be prevented.

(13) Note that sipes 32 may be formed to the central land portion row 16 and the edge land portion rows 18 as appropriate. The shape and number of the sipes 32 is not limited to the example illustrated in the drawings, and may be set as desired.

(14) Note that in the above configuration, the main lug grooves 20 open onto the circumferential direction main grooves 14 in an inclined state with respect to the tire width direction, however there is no limitation thereto, the main lug grooves 20 may be formed along the tire width direction. Configuration may also be made wherein the auxiliary grooves 30 are not provided. The angle of inclination θ of the main lug grooves 20 with respect to the tire circumferential direction is illustrated within the value range described above, however configuration outside of this value range is also possible.

Operation

(15) Explanation follows regarding operation of the present exemplary embodiment configured as described above. In FIG. 1, in the pneumatic tire 10 of the present exemplary embodiment the two circumferential direction main grooves 14 formed further to the tire width direction inside than positions ⅓ of the ground contact width W from the ground contact edges T of the tread 12 increase water discharge performance and snow discharge performance, enabling handling stability performance to be enhanced on snowy road surfaces. The circumferential direction main grooves 14 also enable a reduction in noise to be achieved.

(16) In addition, in the edge land portion rows 18, the edges of the main lug grooves 20 that extend from the circumferential direction main grooves 14 to the ground contact edges T of the tread 12 enable traction performance to be enhanced, this being related to braking performance and acceleration performance on snowy road surfaces. In particular, since the edge land portion rows 18 are not formed with main grooves that place tire circumferential direction neighboring main lug grooves 20 in communication with each other, the main lug grooves 20 are formed continuously with a long length, enabling a large edge effect to be obtained, this being related to braking performance and acceleration performance.

(17) Moreover, in the present exemplary embodiment, the main lug grooves 20 open onto the circumferential direction main grooves 14 in an appropriately inclined state with respect to the tire width direction. Due to providing the auxiliary grooves 30 that intersect with the direction of the main lug grooves 20 at the positions where the main lug grooves 20 open onto the circumferential direction main grooves 14, an even larger edge effect can be obtained when running on snowy road surfaces. Shear force from snow columns is increased since snow is compacted inside the auxiliary grooves 24 provided to the edge land portion rows 18. The main lug grooves 20 are able to achieve both a water discharge effect and an edge effect with respect to input along the tire equatorial plane direction arising during braking and during acceleration due to the angle of inclination θ of the main lug grooves 20 being set appropriately with respect to the tire circumferential direction.

(18) The present exemplary embodiment can accordingly greatly enhance traction performance, this being related to braking performance and acceleration performance on snowy road surfaces, as well as handling stability performance.

Test Example

(19) Testing is performed for the various evaluation criteria shown in Table 2 on the pneumatic tire 10 of a Test Example of the tread pattern illustrated in FIG. 1, that includes circumferential direction main grooves, main lug grooves, and auxiliary grooves configured as set out in Table 1, and on a conventional pneumatic tire 100 of the tread pattern illustrated in FIG. 2, that includes auxiliary grooves configured as set out in Table 1. The tire size is 195/65R15 (tread width 162 mm), internal pressure is 220 kPa, and load corresponds to two occupants. Note that in FIG. 2, 102 are central land portion rows, 104 are edge land portion rows, 106 and 108 are circumferential direction main grooves, 110 are main lug grooves, 112 are auxiliary grooves, 114 are sipes, and T indicates the ground contact edges.

(20) Brief explanation follows regarding the evaluation methods employed for each of the evaluation criteria set out in Table 2.

(21) Wet Road Surface

(22) Hydroplaning is evaluated by test driver feeling at a hydroplaning occurrence threshold speed when running on a straight wet road surface with a water depth of 5 mm.

(23) Braking performance is evaluated by the braking distance for the vehicle to come to a standstill when the brakes are fully applied in a state running at 80 km/h on a straight wet road surface with a water depth of 2 mm.

(24) Dry Road Surface

(25) Braking performance is evaluated by the braking distance for the vehicle to come to a standstill when the brakes are fully applied in a state running at 80 km/h on a dry road surface. Handling stability performance is evaluated by test driver feeling for various running modes when sports running on a circuit course in a dry state.

(26) Snowy Road Surface

(27) Traction performance is evaluated by the time required to accelerate from 10 km/h to 45 km/h on a snowy road surface.

(28) Braking performance is evaluated by the braking distance for the vehicle to come to a standstill when the brakes are fully applied in a state running at 40 km/h on a snowy road surface.

(29) Handling stability performance is evaluated by overall test driver feeling for braking performance, start-up performance, straight ahead running performance, and cornering performance on a test course with a compacted snow road surface.

(30) Handling stability performance is evaluated by overall test driver feeling for braking performance, start-up performance, straight ahead running performance, and cornering performance on a test course with a frozen road surface.

(31) The results illustrated in Table 2 are shown employing an index wherein the Conventional Example is given a value of 100 for each of the evaluation criteria, and the higher the value, the better the result. As illustrated in Table 2, the tire of the Test Example outperforms the tire of the Conventional Example for each of the evaluation criteria. It can be confirmed that the tire of the Test Example enhances snow performance whilst maintaining braking performance and handling stability performance on wet road surfaces, and dry road surfaces.

(32) TABLE-US-00001 TABLE 1 Groove Width Groove Angle depth (mm) (°) (mm) Test Example Circumferential 11 0 8 direction groove Main lug 9-5 95-65 8 groove Auxiliary Groove 4.5 80 6 Conventional Auxiliary 2.5-5 81 7 Example Groove

(33) TABLE-US-00002 TABLE 2 Conventional Test Example Example Wet Road Hydroplaning (straight line) 100 100 Surface Braking performance (straight line) 100 100 Handling stability performance 100 100 Dry Road Braking performance (straight line) 100 100 Surface Handling stability performance 100 100 Snowy Traction performance 100 120 Road Braking performance 100 120 Surface Handling stability performance 100 115

EXPLANATION OF THE REFERENCE NUMERALS

(34) 10 pneumatic tire 12 tread 14 circumferential direction main grooves 16 central land portion row 18 edge land portion rows 20 main lug grooves 30 auxiliary grooves θ angle of inclination