WO2017082408A1 - タイヤ - Google Patents
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- Publication number
- WO2017082408A1 WO2017082408A1 PCT/JP2016/083578 JP2016083578W WO2017082408A1 WO 2017082408 A1 WO2017082408 A1 WO 2017082408A1 JP 2016083578 W JP2016083578 W JP 2016083578W WO 2017082408 A1 WO2017082408 A1 WO 2017082408A1
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- WIPO (PCT)
- Prior art keywords
- sipe
- tire
- block
- circumferential
- land
- Prior art date
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B60—VEHICLES IN GENERAL
- B60C—VEHICLE TYRES; TYRE INFLATION; TYRE CHANGING; CONNECTING VALVES TO INFLATABLE ELASTIC BODIES IN GENERAL; DEVICES OR ARRANGEMENTS RELATED TO TYRES
- B60C11/00—Tyre tread bands; Tread patterns; Anti-skid inserts
- B60C11/03—Tread patterns
- B60C11/11—Tread patterns in which the raised area of the pattern consists only of isolated elements, e.g. blocks
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B60—VEHICLES IN GENERAL
- B60C—VEHICLE TYRES; TYRE INFLATION; TYRE CHANGING; CONNECTING VALVES TO INFLATABLE ELASTIC BODIES IN GENERAL; DEVICES OR ARRANGEMENTS RELATED TO TYRES
- B60C11/00—Tyre tread bands; Tread patterns; Anti-skid inserts
- B60C11/03—Tread patterns
- B60C11/0304—Asymmetric patterns
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B60—VEHICLES IN GENERAL
- B60C—VEHICLE TYRES; TYRE INFLATION; TYRE CHANGING; CONNECTING VALVES TO INFLATABLE ELASTIC BODIES IN GENERAL; DEVICES OR ARRANGEMENTS RELATED TO TYRES
- B60C11/00—Tyre tread bands; Tread patterns; Anti-skid inserts
- B60C11/03—Tread patterns
- B60C11/0327—Tread patterns characterised by special properties of the tread pattern
- B60C11/033—Tread patterns characterised by special properties of the tread pattern by the void or net-to-gross ratios of the patterns
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B60—VEHICLES IN GENERAL
- B60C—VEHICLE TYRES; TYRE INFLATION; TYRE CHANGING; CONNECTING VALVES TO INFLATABLE ELASTIC BODIES IN GENERAL; DEVICES OR ARRANGEMENTS RELATED TO TYRES
- B60C11/00—Tyre tread bands; Tread patterns; Anti-skid inserts
- B60C11/03—Tread patterns
- B60C11/12—Tread patterns characterised by the use of narrow slits or incisions, e.g. sipes
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B60—VEHICLES IN GENERAL
- B60C—VEHICLE TYRES; TYRE INFLATION; TYRE CHANGING; CONNECTING VALVES TO INFLATABLE ELASTIC BODIES IN GENERAL; DEVICES OR ARRANGEMENTS RELATED TO TYRES
- B60C11/00—Tyre tread bands; Tread patterns; Anti-skid inserts
- B60C11/03—Tread patterns
- B60C11/12—Tread patterns characterised by the use of narrow slits or incisions, e.g. sipes
- B60C11/1236—Tread patterns characterised by the use of narrow slits or incisions, e.g. sipes with special arrangements in the tread pattern
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B60—VEHICLES IN GENERAL
- B60C—VEHICLE TYRES; TYRE INFLATION; TYRE CHANGING; CONNECTING VALVES TO INFLATABLE ELASTIC BODIES IN GENERAL; DEVICES OR ARRANGEMENTS RELATED TO TYRES
- B60C11/00—Tyre tread bands; Tread patterns; Anti-skid inserts
- B60C11/03—Tread patterns
- B60C11/0327—Tread patterns characterised by special properties of the tread pattern
- B60C2011/0334—Stiffness
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B60—VEHICLES IN GENERAL
- B60C—VEHICLE TYRES; TYRE INFLATION; TYRE CHANGING; CONNECTING VALVES TO INFLATABLE ELASTIC BODIES IN GENERAL; DEVICES OR ARRANGEMENTS RELATED TO TYRES
- B60C11/00—Tyre tread bands; Tread patterns; Anti-skid inserts
- B60C11/03—Tread patterns
- B60C2011/0337—Tread patterns characterised by particular design features of the pattern
- B60C2011/0339—Grooves
- B60C2011/0358—Lateral grooves, i.e. having an angle of 45 to 90 degees to the equatorial plane
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B60—VEHICLES IN GENERAL
- B60C—VEHICLE TYRES; TYRE INFLATION; TYRE CHANGING; CONNECTING VALVES TO INFLATABLE ELASTIC BODIES IN GENERAL; DEVICES OR ARRANGEMENTS RELATED TO TYRES
- B60C11/00—Tyre tread bands; Tread patterns; Anti-skid inserts
- B60C11/03—Tread patterns
- B60C2011/0337—Tread patterns characterised by particular design features of the pattern
- B60C2011/0339—Grooves
- B60C2011/0358—Lateral grooves, i.e. having an angle of 45 to 90 degees to the equatorial plane
- B60C2011/0372—Lateral grooves, i.e. having an angle of 45 to 90 degees to the equatorial plane with particular inclination angles
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B60—VEHICLES IN GENERAL
- B60C—VEHICLE TYRES; TYRE INFLATION; TYRE CHANGING; CONNECTING VALVES TO INFLATABLE ELASTIC BODIES IN GENERAL; DEVICES OR ARRANGEMENTS RELATED TO TYRES
- B60C11/00—Tyre tread bands; Tread patterns; Anti-skid inserts
- B60C11/03—Tread patterns
- B60C2011/0337—Tread patterns characterised by particular design features of the pattern
- B60C2011/0339—Grooves
- B60C2011/0381—Blind or isolated grooves
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B60—VEHICLES IN GENERAL
- B60C—VEHICLE TYRES; TYRE INFLATION; TYRE CHANGING; CONNECTING VALVES TO INFLATABLE ELASTIC BODIES IN GENERAL; DEVICES OR ARRANGEMENTS RELATED TO TYRES
- B60C11/00—Tyre tread bands; Tread patterns; Anti-skid inserts
- B60C11/03—Tread patterns
- B60C2011/0337—Tread patterns characterised by particular design features of the pattern
- B60C2011/0339—Grooves
- B60C2011/0381—Blind or isolated grooves
- B60C2011/0383—Blind or isolated grooves at the centre of the tread
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B60—VEHICLES IN GENERAL
- B60C—VEHICLE TYRES; TYRE INFLATION; TYRE CHANGING; CONNECTING VALVES TO INFLATABLE ELASTIC BODIES IN GENERAL; DEVICES OR ARRANGEMENTS RELATED TO TYRES
- B60C11/00—Tyre tread bands; Tread patterns; Anti-skid inserts
- B60C11/03—Tread patterns
- B60C11/12—Tread patterns characterised by the use of narrow slits or incisions, e.g. sipes
- B60C11/1204—Tread patterns characterised by the use of narrow slits or incisions, e.g. sipes with special shape of the sipe
- B60C2011/1209—Tread patterns characterised by the use of narrow slits or incisions, e.g. sipes with special shape of the sipe straight at the tread surface
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B60—VEHICLES IN GENERAL
- B60C—VEHICLE TYRES; TYRE INFLATION; TYRE CHANGING; CONNECTING VALVES TO INFLATABLE ELASTIC BODIES IN GENERAL; DEVICES OR ARRANGEMENTS RELATED TO TYRES
- B60C11/00—Tyre tread bands; Tread patterns; Anti-skid inserts
- B60C11/03—Tread patterns
- B60C11/12—Tread patterns characterised by the use of narrow slits or incisions, e.g. sipes
- B60C11/1204—Tread patterns characterised by the use of narrow slits or incisions, e.g. sipes with special shape of the sipe
- B60C2011/1213—Tread patterns characterised by the use of narrow slits or incisions, e.g. sipes with special shape of the sipe sinusoidal or zigzag at the tread surface
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B60—VEHICLES IN GENERAL
- B60C—VEHICLE TYRES; TYRE INFLATION; TYRE CHANGING; CONNECTING VALVES TO INFLATABLE ELASTIC BODIES IN GENERAL; DEVICES OR ARRANGEMENTS RELATED TO TYRES
- B60C11/00—Tyre tread bands; Tread patterns; Anti-skid inserts
- B60C11/03—Tread patterns
- B60C11/12—Tread patterns characterised by the use of narrow slits or incisions, e.g. sipes
- B60C11/1236—Tread patterns characterised by the use of narrow slits or incisions, e.g. sipes with special arrangements in the tread pattern
- B60C2011/1245—Tread patterns characterised by the use of narrow slits or incisions, e.g. sipes with special arrangements in the tread pattern being arranged in crossing relation, e.g. sipe mesh
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B60—VEHICLES IN GENERAL
- B60C—VEHICLE TYRES; TYRE INFLATION; TYRE CHANGING; CONNECTING VALVES TO INFLATABLE ELASTIC BODIES IN GENERAL; DEVICES OR ARRANGEMENTS RELATED TO TYRES
- B60C11/00—Tyre tread bands; Tread patterns; Anti-skid inserts
- B60C11/03—Tread patterns
- B60C11/12—Tread patterns characterised by the use of narrow slits or incisions, e.g. sipes
- B60C2011/129—Sipe density, i.e. the distance between the sipes within the pattern
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B60—VEHICLES IN GENERAL
- B60C—VEHICLE TYRES; TYRE INFLATION; TYRE CHANGING; CONNECTING VALVES TO INFLATABLE ELASTIC BODIES IN GENERAL; DEVICES OR ARRANGEMENTS RELATED TO TYRES
- B60C11/00—Tyre tread bands; Tread patterns; Anti-skid inserts
- B60C11/03—Tread patterns
- B60C11/12—Tread patterns characterised by the use of narrow slits or incisions, e.g. sipes
- B60C2011/129—Sipe density, i.e. the distance between the sipes within the pattern
- B60C2011/1295—Sipe density, i.e. the distance between the sipes within the pattern variable
Definitions
- the present invention relates to a tire capable of traveling on icy and snowy roads such as a studless tire.
- a studless tire in which a corrugated widthwise sipe extending in the tire width direction and a linear circumferential sipe extending in the tire circumferential direction are formed in a land block (see Patent Document 1).
- the circumferential sipe ends in the land block.
- This circumferential sipe enhances cornering performance on icy and snowy roads.
- the circumferential sipe does not open to the side wall of the land block, the rigidity of the land block is also ensured. Thereby, the fall of the braking performance by the fall of a land block is avoided.
- the rigidity (block stiffness) of the land block decreases, which hinders other performance improvements.
- block rigidity is lowered, there is a reduction in braking performance on the road surface on ice as described above, but in particular, there is a problem that the wear resistance performance on a dry road surface is greatly reduced.
- the block rigidity of the entire land block decreases greatly. This makes it easier for the part to float without touching the road surface. As a result, the wear of the land block proceeds and the tire life is shortened.
- the circumferential end of a land block that receives adjacent sipe as close as possible in parallel with the tire width direction, which is the direction in which the edge effect appears, facing the tire circumferential direction, or receiving the tire circumferential direction input during braking The number of sipes is increased as the side walls and sipes are made parallel and the side walls and sipes are made as close as possible.
- the edge effect by the sipe edge has been improved by forming the sipe in the closest state to the land block by reducing the sipe interval as much as possible.
- the pitch length which is the dimension in the tire circumferential direction of the pitch of the land block, which is one basic unit of the tread pattern continuously repeated in the tire circumferential direction
- the circumferential dimension of the land block By increasing the rigidity of the land block (block rigidity) and suppressing the falling of the land block, the ground contact area was increased, and the performance on ice and the wear resistance were improved.
- the sipe density in the land block has already increased to the limit, and the sipe interval could not be further reduced. Even if the pitch length is increased and the circumferential dimension of the land block is increased, if the land block is excessively divided by sipe, the block rigidity is lowered.
- the pitch length and the circumferential dimension of the land block have increased, and the number of pitches and land blocks in the contact length has decreased, so if the number is further reduced, the circumference of the land block is reduced.
- the directional dimension becomes too large, the area of the lug groove portion decreases, the drainage performance cannot be secured, and the block edge component due to the lug groove cannot be exhibited.
- the conventional tire as described above cannot solve such a problem.
- An object of the present invention is to provide a tire capable of running on icy and snowy roads including icy road surfaces, such as studless tires, which can achieve both performance and wear resistance performance at a higher level.
- ABS anti-lock brake system
- the block rigidity can be improved by increasing the sipe interval.
- the contact area is improved by suppressing the falling of the land block, the force of pressing the block edge and the sipe edge against the road surface is improved, and the edge effect is improved.
- the wear resistance is improved.
- the block rigidity means the block rigidity in the tire circumferential direction required for braking on the road surface on ice unless otherwise specified.
- the sipe interval when the sipe interval is increased, the number of sipe formed in the land block is reduced, and the edge effect due to the sipe edge is reduced. Therefore, by further reducing the pitch length of the land block, the number of blocks per tire circumference is increased, and instead of the reduced sipe edge edge effect, the edge effect due to the block edge having a larger edge effect is improved. To improve the total edge effect.
- the block rigidity is improved, and the contact area is improved by suppressing the collapse of the land block. Further, the wear resistance performance is improved while improving the overall edge effect by improving the force pressing the block edge and the sipe edge against the road surface and improving the block edge.
- the braking performance on the ice road surface and the performance on the dry road surface, particularly the wear resistance performance can be achieved at a higher level.
- one aspect of the present invention is a tire including a block in which a circumferential groove extending in the tire circumferential direction and a lug groove extending in the tire width direction are formed and partitioned by the circumferential groove and the lug groove.
- the block is formed with a zigzag circumferential sipe extending in the tire circumferential direction and a zigzag width sipe extending in the tire width direction, the width direction being the amplitude of the circumferential sipe in the tire width direction
- the gist is that the amplitude is larger than the circumferential amplitude which is the amplitude of the width-direction sipe in the tire circumferential direction.
- the circumferential sipe zigzag repetition period is equal to or smaller than the interval between the widthwise sipes adjacent to each other in the tire circumferential direction.
- a total L1 of width direction edge components that become edge components in the tire width direction by the circumferential sipe, and a circumferential edge component that becomes edge components in the tire circumferential direction by the circumferential sipe may be 16.0% or more and 37.4% or less.
- the ratio (L1 + L2) / L3 of the total L1 and the total L2 to the average dimension L3 in the tire circumferential direction of the block may be 3.4 or more and 7.8 or less.
- the circumferential direction secondary sipe extended in a tire circumferential direction is formed in the said block, One end of the said circumferential direction secondary sipe is connected to the said width direction sipe, and the other end of the said circumferential direction secondary sipe May open in the side wall located on the tire circumferential direction end side of the block.
- the circumferential sipe includes a linear portion that extends linearly in parallel with the tire circumferential direction, and the linear portion is formed at an end of the block in the tire circumferential direction, You may form in the position offset from the center position of the amplitude in the tire width direction of a direction sipe.
- the block may be provided at a tread end including a contact end with a road surface in a tire width direction.
- FIG. 1 is an overall schematic perspective view of a pneumatic tire 10.
- FIG. 2 is a partially enlarged perspective view of the pneumatic tire 10.
- FIG. 3 is a partial plan development view of the tread 20.
- FIG. 4 is a partially enlarged plan view of the V-shaped land portion row 100.
- FIG. 5 is a partially enlarged plan view of the V-shaped land portion block 101 constituting the V-shaped land portion row 100.
- FIG. 6 is a partially enlarged plan view of the central land portion row 200.
- 7A and 7B are explanatory diagrams of the rotational moment generated in the land block 210 and the rotational moment generated in the conventional land block 210P.
- FIG. 8 is a partially enlarged plan view of the shoulder land portion row 300in.
- FIG. 9 is an enlarged perspective view of the land portion block 310 constituting the shoulder land portion row 300in.
- FIG. 10 is a diagram showing the definition of various dimensions of the V-shaped land portion row 100.
- FIG. 11 is a diagram showing the definition of various dimensions of the central land row 200.
- FIG. 12 is a diagram showing various dimensions of the shoulder land portion row 300in.
- FIG. 13 is a partial plan development view of a pneumatic tire 10A in which a pitch different from that of the pneumatic tire 10 shown in FIGS. 1 to 12 is set.
- FIG. 1 is an overall schematic perspective view of a pneumatic tire 10 according to the present embodiment.
- FIG. 2 is a partially enlarged perspective view of the pneumatic tire 10.
- FIGS. 1 and 2 a part of the pattern (tread pattern) formed on the tread 20 is not shown.
- FIG. 3 is a partial plan development view of the tread 20.
- the pneumatic tire 10 is a so-called studless tire that is suitable for running on icy and snowy roads, particularly on icy roads.
- the pneumatic tire 10 is not specified in the rotational direction, but has a shoulder land portion row that should be positioned inside (vehicle hub side) and outside when the vehicle is mounted (see FIG. 2).
- the tread 20 of the pneumatic tire 10 is provided with a plurality of land rows in contact with the road surface. Specifically, the tread 20 is provided with a V-shaped land portion row 100, a central land portion row 200, a shoulder land portion row 300in, and a saddle 300out.
- the V-shaped land portion row 100 is provided offset from the position of the tire equator line CL (not shown in FIGS. 1 and 2, see FIG. 3). Specifically, the V-shaped land portion row 100 is provided so as to be located on the tread end side from the tire equator line CL.
- the central land portion row 200 is adjacent to the V-shaped land portion row 100 and is provided at a position including the tire equator line CL.
- the shoulder land portion row 300out is adjacent to the central land portion row 200 and is located outside the central land portion row 200 when the vehicle is mounted.
- the shoulder land portion row 300in is adjacent to the V-shaped land portion row 100 and is located on the inner side of the V-shaped land portion row 100 when the vehicle is mounted.
- the tread 20 is formed with a plurality of circumferential grooves extending in the tire circumferential direction. Specifically, a circumferential groove 30 is formed between the V-shaped land portion row 100 and the central land portion row 200.
- a circumferential groove 40 is formed between the V-shaped land portion row 100 and the shoulder land portion row 300in, and a circumferential groove 50 is formed between the central land portion row 200 and the shoulder land portion row 300out.
- a circumferential groove 60 is formed between the land portion row 201 and the land portion row 202 constituting the central land portion row 200.
- a lug groove 70 extending in the tire width direction is formed in the shoulder land portion row 300out, and a lug groove 80 extending in the tire width direction is formed in the shoulder land portion row 300in.
- column which comprises the land part row
- the rubber (tread rubber) constituting such a tread 20 is preferably foamed rubber.
- the reason why the foamed rubber is preferable is the ease of compressive deformation due to the effect that the rubber solid phase part is replaced with the air phase part because the foamed rubber contains air holes.
- the tread rubber preferably has a two-layer structure of surface rubber and internal rubber, foamed rubber is used as the surface rubber, and the internal rubber is preferably non-foamed rubber or foamed rubber having a higher elastic modulus than the surface rubber.
- the surface rubber up to the radial depth position of the snow platform, which indicates the use limit due to wear, and to use the internal rubber at a radially inner position than the snow platform.
- foamed rubber contains air holes inside and has low elasticity, so that the rigidity of the entire land block (land block) is secured by the rigidity of the internal rubber.
- the foaming rate should be 3-40%.
- the elastic modulus of the foamed rubber is 60% of the elastic modulus of the non-foamed rubber. If the foaming rate is higher than this, the elastic modulus of the foamed rubber is too low and the entire land block is This is because the rigidity cannot be maintained even with the land block shape.
- the elastic modulus of the foamed rubber is 97% of the elastic modulus of the non-foamed rubber, and the block rigidity can be secured. This is because the property, removal of the water film, and the edge effect cannot be exhibited. Optimally, 12% to 32% is good. This is because the block rigidity is secured, the ground contact area due to flexibility, the water film removal, and the edge effect are compatible at a high level.
- the elastic modulus of the tread rubber in contact with the road surface is softened in order to improve the friction coefficient ⁇ on the ice road surface and improve the ground contact area due to flexibility, etc.
- reducing the amount of carbon added, making the polymer less elastic in the operating temperature range, or reducing the amount of vulcanizing agent added to suppress crosslinking will reduce wear performance. .
- the amount of carbon added can be increased, the elastic modulus in the polymer use temperature range can be increased, and the amount of vulcanizing agent added can be increased.
- the amount of oil added is not increased, and it can be made highly elastic with excellent wear performance. This is because even if the elasticity is high, if the foaming rate is 20%, it is replaced with air holes, and the elastic modulus of the foamed rubber can be reduced to 80% of the elastic modulus of the non-foamed rubber.
- the shape of the land block is greatly increased by utilizing the flexibility of foamed rubber and the ease of compression deformation, which can lower the modulus of elasticity compared to the elasticity of ordinary non-foamed rubber.
- the rigidity can be increased.
- the elastic modulus of rubber is 2.0 MPa to 5.0 MPa, preferably 2.3 MPa to 3.5 MPa.
- the rubber is preferably foamed rubber.
- the foaming rate is 3% to 40%, preferably 12% to 32%.
- the elastic modulus (unit: MPa) of rubber is a value measured at 23 ° C as defined in JIS standards.
- the elastic modulus was measured by using a spectrometer manufactured by Ueshima Seisakusho Co., Ltd., with dynamic tensile storage elastic modulus E ′ at 23 ° C. as elastic modulus under conditions of initial strain 2%, dynamic strain 1%, and frequency 52 Hz. .
- the measured elastic modulus is the dynamic tensile storage elastic modulus E ′ in the dynamic tensile viscoelasticity test.
- the results are similar to the results of the dynamic tensile viscoelasticity test. The larger the rate, the lower the tendency to become elastic.
- the configuration of the elastic modulus of the tire described in the present embodiment is all established in the dynamic viscoelasticity test under the measurement conditions described above or measurement conditions equivalent thereto.
- the reason is that the rubber used in the tread part of the tire has a Poisson's ratio close to 0.5, and even when deformed, the volume change is extremely small, so the tensile modulus, compression modulus, and shear elasticity This is because the rate is proportional.
- FIG. 4 is a partially enlarged plan view of the V-shaped land portion row 100.
- the V-shaped land portion row 100 includes a land portion block defined by the circumferential groove 30 and the circumferential groove 40, and a widthwise inclined groove 160 (lug groove).
- the V-shaped land portion row 100 includes a plurality of V-shaped land portion blocks 101 along the tire circumferential direction.
- the V-shaped land block 101 has a convex portion that is convex toward one side in the tire circumferential direction and a concave portion that is also concave toward one side in the tire circumferential direction, and is V-shaped in a tread surface view. .
- the V-shaped land block 101 is a V-shaped land block having a convex portion 110 and a concave portion 120.
- the V-shaped land portion block 101 means a block whose tread surface shape is V-shaped or arrow-shaped.
- the inclination angle ⁇ 1 (inclination direction) of the convex side wall 111 of the V-shaped land block 101 constituting the convex 110 with respect to the tire width direction is the tire width direction of the concave side wall 121 constituting the concave 120 Is the same (same direction) as the inclination angle ⁇ 2.
- the inclination angle ⁇ 3 (inclination direction) of the convex side wall portion 112 of the V-shaped land block 101 with respect to the tire width direction is the same as the inclination angle ⁇ 4 with respect to the tire width direction of the concave side wall portion 122 constituting the concave portion 120 (identical).
- the inclination angles are not necessarily the same, and “same” or “same direction” means that the difference between both inclination angles is within 20 degrees (hereinafter, description of the inclination angle). Is the same).
- the inclination angle of the convex side wall 111, the sipe 130, and the terminal inclined groove 150 on the tire equator line CL side, and the inclination angle of the convex side wall 112 on the tread end side, and the sipe 140 are on one side with respect to the tire width direction. Is preferably in the range of 15 ° to 35 ° and the other side in the range of 7 ° to 25 °.
- the angles ⁇ 1, 2, 5, 6 (one side) shown in FIG. 4 are the same, and the angles ⁇ 3,4,7,8,9 (the other side) are the same.
- the edge effect due to the block edge and the sipe edge in the tire circumferential direction is particularly enhanced. Because it can.
- a plurality of sipes that are inclined with respect to the tire width direction are formed. Specifically, sipe 130 and sipe 140 are formed. The sipe 130 and the sipe 140 are both inclined with respect to the tire width direction, but the sipe 130 is inclined in the opposite direction to the sipe 140 with respect to the tire width direction.
- the sipe 130 and the sipe 140 are zigzag-shaped. Specifically, the sipe 130 and the sipe 140 are formed to be bent (one or more) in the extending direction and to be linear in the tire radial direction in a tread surface view. Alternatively, the sipe 130 and the sipe 140 may be formed to bend in both the extending direction and the tire radial direction. Alternatively, the sipe 130 and the sipe 140 may be formed so as to be bent in the tire radial direction and linear in the extending direction. Alternatively, the sipe 130 and the sipe 140 may be formed so as to be linear in the tire radial direction and linear in the extending direction.
- the sipe is a narrow groove that closes within the ground contact surface of the land block, and the opening width of the sipe when not grounded is not particularly limited, but is preferably 0.1 mm to 1.5 mm.
- the V-shaped land block 101 is formed with a terminal inclined groove that is inclined with respect to the tire width direction. Specifically, a terminal inclined groove 150 is formed on the tire equator line CL side of the V-shaped land block 101.
- Inclining with respect to the tire width direction means not having a predetermined angle with respect to the tire width direction but parallel to the tire width direction, that is, being parallel to the tire circumferential direction (that is, Does not include the state where the angle with the tire width direction is 90 degrees.
- the inclination angle ⁇ 5 (inclination direction) of the terminal inclination groove 150 with respect to the tire width direction is the same as the inclination angle ⁇ 1 (inclination angle ⁇ 2) of the convex side wall portion 111 with respect to the tire width direction, that is, the inclination directions are the same direction.
- the inclination angle of the sipe 130 with respect to the tire width direction is the same (in the same direction) as the inclination angle ⁇ 1 (inclination angle ⁇ 2) with respect to the tire side wall portion 111 tire width direction.
- the relationship between the concave side wall 121 and the sipe 130, the convex side wall 112 and the sipe 140, and the concave side wall 122 and the sipe 140 are the same.
- One end of the sipe 130 opens to the side wall 100a of the V-shaped land block 101 in the tire width direction.
- the other end of the sipe 130 terminates in the V-shaped land block 101.
- the end 131 of the sipe 130 terminates in the V-shaped land block 101.
- one end of the end inclined groove 150 opens to the side wall 100a on the tire equator line CL side.
- the end portion 151 of the end inclined groove 150 ends in the V-shaped land portion block 101.
- the circumferential dimension of the V-shaped land block 101 along the tire circumferential direction is larger than the width dimension of the V-shaped land block 101 along the tire width direction.
- the circumferential dimension of the V-shaped land block 101 means the length of the longest portion of the V-shaped land block 101 in the tire circumferential direction. Specifically, the circumferential dimension shown in FIG. Is.
- the width-direction dimension of the V-shaped land block 101 means the length between the side wall 100a and the side wall 100b, and is the same as the “width-direction dimension” shown in FIG.
- a plurality of sipes 140 formed in the V-shaped land block 101 include communicating sipes that communicate with the terminal inclined groove 150.
- the sipe 140 includes a communication sipe 141.
- One end of the communication sipe 141 specifically, the end portion 141 a communicates with the end portion 151 that is the end portion of the end inclined groove 150.
- the other end of the communication sipe 141 opens in the side wall 100b in the tire width direction of the V-shaped land block 101.
- the sidewall 100b is a sidewall on the tread end side of the V-shaped land block 101 in the tire width direction.
- the side wall 100c of the V-shaped land block 101 constituting the terminal portion (end portion 151) of the terminal inclined groove 150 is connected to the extension line of the communication sipe 141.
- the position of the end portion of the end inclined groove 150 is different from the position of the most convex portion 110a of the convex portion 110 in the tire width direction.
- the terminal inclined groove 150 extends in the same direction as the sipe 130 formed on the opening end side of the terminal inclined groove 150 with respect to the most concave portion 120a of the concave portion 120.
- the sipe 130 is formed closer to the opening end of the terminal inclined groove 150 than the most concave portion 120a.
- the sipe 140 is formed closer to the terminal end (end portion 151) of the terminal inclined groove 150 than the most concave portion 120a.
- the most convex part of the convex part 110 and the most concave part of the concave part 120 mean the maximum convex point and the maximum concave point that are the bending points of the convex part 110 and the concave part 120. Bending points of the convex part 110 and the concave part 120 are two trapezoidal shapes, or a plurality of places, the convex part 110 and the concave part 120 are curved in a trapezoidal shape, and the maximum convex point and the maximum concave point are in the tire width direction. When it has a range, it means the center position of the range in the tire width direction.
- the most convex portion 110a is located closer to the tread end than the most concave portion 120a.
- the length of the terminal inclined groove 150 is the same as the length of the sipe 130 formed on the opening end side of the terminal inclined groove 150.
- the length of the end inclined groove 150 is a dimension of the end inclined groove 150 along the extending direction of the end inclined groove 150.
- the length of the sipe 130 is a dimension of the sipe 130 along the extending direction of the sipe 130.
- the end inclined groove 150 extends in the same direction as the sipe 130 formed on the tire equator line CL side from the center of the V-shaped land block 101 in the tire width direction.
- the V-shaped land block 101 includes a V-shaped land block 101A (first block) and a V-shaped land block 101B (second block) which are adjacent in the tire circumferential direction. Thus, a plurality of V-shaped land portion blocks 101 are provided along the tire circumferential direction.
- a width direction inclined groove that is inclined with respect to the tire width direction. Specifically, a width direction inclined groove 160 having one bent portion is formed between the V-shaped land portion block 101A and the V-shaped land portion block 101B.
- the width direction inclined groove 160 includes an inclined groove portion 161 (first inclined groove portion) positioned on one side in the tire width direction with respect to the bent portion 163 and a tire width direction on the basis of the bent portion 163. And an inclined groove portion 162 (second inclined groove portion) located on the other side.
- the inclined groove portion 161 is located on the opening end side of the terminal inclined groove 150 with respect to the bent portion 163, that is, on the tire equator line CL side.
- the inclined groove 162 is located closer to the end (end 151) of the end inclined groove 150 than the bent portion 163 is.
- the bent part 163 bends at the position of the convex part 110 of the V-shaped land part block 101A and the concave part 120 of the V-shaped land part block 101B. That is, the bent portion 163 bends at the position of the convex portion 110 and the concave portion 120 that are offset in the tire width direction. As a result, the circumferential dimension (groove length) along the tire circumferential direction of the widthwise inclined groove 160 is increased. ) Are different in the tire width direction. Specifically, the inclined groove part 161 and the inclined groove part 162 have different dimensions, and the dimension of the inclined groove part 161 is larger than the dimension of the inclined groove part 162.
- a straight line connecting the most convex part 110a and the most concave part 120a becomes a boundary between the inclined groove part 161 and the inclined groove part 162.
- a line segment connecting the center point in the tire circumferential direction on this boundary line and the center point in the tire circumferential direction at the end opposite to the boundary of the inclined groove 161, and the boundary opposite to the boundary between the boundary and the inclined groove 162 A line segment connecting the center point in the tire circumferential direction at the end is referred to as a width direction dimension.
- the end inclined groove 150 extends inclined in the same direction as the inclined groove 161.
- the sipe 130 also extends in the same direction as the inclined groove 161.
- the sipe 140 extends in the same direction as the inclined groove 162.
- the V-shaped land block 101 is provided in the center region including the tire equator line CL or the second region located outside the center region in the tire width direction.
- the one located at the ground contact end is the shoulder portion land block, and the one adjacent to the inside of the shoulder portion land block in the tire width direction.
- the second part land block, the one adjacent to the inner side in the tire width direction of the second part land block, and including the position of the tire equator line CL is referred to as a center part land block.
- the areas included in the center land block, the second land block, and the shoulder land block are referred to as a center area, a second area, and a shoulder area, respectively.
- the center region is 16 tires from the ground contact center in the tire width direction, which is half of the ground contact width (W) of the pneumatic tire 10.
- % Area (W / 2 ⁇ 0.16) the shoulder area means the 42% area (W / 2 ⁇ 0.42) from the ground contact edge, and the second area is located on the inner side of the shoulder area in the tire width direction. It is a 42% region (W / 2 ⁇ 0.42) of the width (W).
- the center region is the tire equator line CL, that is, the tire width direction that is half the ground contact width (W) of the pneumatic tire 10
- CL tire equator line
- the land block of the area having the larger area is used.
- the center portion land block is used.
- the land block present is the center land block
- the land block present in the second region is the second land block
- the land block present in the shoulder region is the shoulder land block.
- the contact width (W) is the dimension in the tire width direction of the tread 20 that contacts the road surface when a normal load is applied to the pneumatic tire 10 set to the normal internal pressure.
- the contact surface (contact area) means a portion of the tread 20 that contacts the road surface when a normal load is applied to the pneumatic tire 10 set to a normal internal pressure.
- the normal internal pressure is the air pressure corresponding to the maximum load capacity of the JATMA (Japan Automobile Tire Association) YearBook, and the normal load is the maximum load capacity (maximum load) corresponding to the maximum load capacity of the JATMA YearBook.
- the negative rate of V-shaped land block 101 is 2.5% or more and 30% or less.
- the negative rate is preferably 2.5% to 12.5%.
- the negative rate of the V-shaped land block 101 means that the area of the V-shaped land block 101 is an area including the terminal inclined groove 150 and the notch recess 170 existing in the V-shaped land block 101 (hereinafter the same).
- the negative rate of the V-shaped land part row 100 is 6% or more and 36 %% or less.
- the negative rate is preferably 8% to 23%.
- the negative rate of the V-shaped land portion row 100 is the area between the side walls (side wall 100a to side wall 100b) on both sides in the tire width direction of the V-shaped land portion row 100.
- the ratio of the widthwise dimension of the terminal inclined groove 150 to the widthwise dimension of the V-shaped land block 101 is 24% or more and 64% or less. Note that the ratio is preferably 34% to 54%. Further, the ratio of the dimension in the width direction of the V-shaped land block 101 to the tread width of the tire is 8% or more and 38% or less. Note that the ratio is preferably 10% to 25%.
- the ratio of the circumferential dimension of the terminal inclined groove 150 to the circumferential dimension of the V-shaped land block 101 is 7% or more and 37% or less. Note that the ratio is preferably 9% to 29%.
- the circumferential dimension of the end inclined groove 150 means the length of the end inclined groove 150 along the tire circumferential direction (see FIG. 10).
- the widthwise dimension of the terminal inclined groove 150 means the length of the terminal inclined groove 150 along the tire width direction (see FIG. 10).
- the ratio of the circumferential direction dimension of the terminal inclined groove 150 to the width direction dimension of the terminal inclined groove 150 is 2.5% or more and 20% or less.
- the ratio is preferably 3% to 10%.
- a notch recess that is recessed as if the V-shaped land block 101 was cut out is formed in the side wall 100b located at the end of the V-shaped land block 101 in the tire width direction. Specifically, a notch recess 170 is formed in the V-shaped land block 101.
- the sipe 140 formed in the V-shaped land block 101 includes a communication sipe (communication sipe 142) communicating with the notch recess 170.
- the circumferential dimension (see FIG. 10) of the notch recess 170 in the tire circumferential direction increases as it goes to the end of the V-shaped land block 101 in the tire width direction, specifically, to the side wall 100b.
- the notch recess 170 is a wedge-shaped wedge-shaped groove.
- the shape of the notch recess 170 is not limited to a wedge shape (triangle) that tapers toward the center in the tire width direction of the V-shaped land block 101 in the tread surface view.
- the notched recess 170 may have a shape in which the edge of the communication sipe 142 does not have an acute angle, such as a semicircular shape (fan shape) in a tread surface view or a square shape with chamfered corners.
- FIG. 5 is a partially enlarged plan view of the V-shaped land block 101 including the communication sipe 142.
- one side wall (side wall 100d) of the V-shaped land block 101 forming the communication sipe 142 is one side wall of the V-shaped land block 101 forming the notched recess 170 (wedge-shaped groove). (Sidewall 100e).
- the side wall 100d extends in the same direction as the communication sipe 142.
- the other side wall (side wall 100f) of the V-shaped land block 101 forming the communication sipe 142 is connected to the other side wall (side wall 100g) of the V-shaped land block 101 forming the wedge-shaped groove.
- the side wall 100g extends in the direction opposite to the communication sipe 142 with respect to the tire width direction, that is, with reference to the tire width direction.
- the ratio of the area of the notch recess 170 to the area of the V-shaped land block 101 including the area of the notch recess 170 is not less than 0.3% and not more than 15%. Note that the ratio is preferably 0.3% to 7%.
- the ratio of the width direction dimension of the notch recess 170 (see FIG. 10) to the width direction dimension of the V-shaped land block 101 is 9% or more and 38% or less. Note that the ratio is preferably 9,2% to 30%, and more preferably 11% to 26%. Further, the ratio of the circumferential dimension of the notch recess 170 to the circumferential dimension of the V-shaped land block 101 is 3% or more and 23% or less. The ratio is preferably 3% to 13%.
- the ratio of the width direction dimension of the notch recess 170 to the circumferential dimension of the notch recess 170 is 130% or more and 270% or less. The ratio should be between 150% and 230%.
- the notch recess 170 is formed in the side wall 100b on the tread end side of the V-shaped land block 101.
- the notch recess 170 is recessed toward the tire equator line CL, and the circumferential dimension of the notch recess 170 increases toward the tread end.
- the V-shaped land portion block 101 is formed on one side in the tire width direction with respect to the most convex portion 110a of the convex portion 110, and has a convex side wall portion 111 (convex portion first side wall portion) inclined with respect to the tire width direction. And a convex side wall portion 112 (a convex second side wall portion) that is formed on the other side in the tire width direction than the most convex portion 110a of the convex portion 110 and is inclined with respect to the tire width direction.
- the convex side wall 111 is longer than the convex side wall 112. Specifically, the length along the side wall surface of the convex portion side wall portion 111 in the tread surface view is longer than the length of the convex portion side wall portion 112 along the side wall surface in the tread surface view.
- the sipe 130 is shorter than the sipe 140. Specifically, the length along the extending direction of the sipe 130 (not including the amplitude due to the zigzag portion) is shorter than the length along the extending direction of the sipe 140 (not including the amplitude due to the zigzag portion). .
- the V-shaped land portion block 101 is formed on one side in the tire width direction, more specifically, on the tire equator line CL side with respect to the most concave portion 120a, and is a concave side wall portion 121 (recessed portion 1 side wall portion) and the other side in the tire width direction than the most concave portion 120a, specifically, the concave side wall portion 122 (the second side wall portion of the concave portion) that is formed on the tread end side and is inclined with respect to the tire width direction. ).
- the concave side wall 121 is longer than the concave side wall 122. Specifically, the length along the side wall surface in the tread surface view of the recess side wall portion 121 is longer than the length along the side wall surface in the tread surface view of the recess side wall portion 122. Further, the convex side wall 111 is longer than the concave side wall 121. Further, the recessed sidewall portion 122 is longer than the recessed sidewall portion 121. Specifically, the length along the side wall surface in the tread surface view of the recess side wall portion 122 is longer than the length along the side wall surface in the tread surface view of the recess side wall portion 121.
- the inclination angle (inclination direction) of the convex side wall 111 and the inclination angle (inclination direction) of the concave side wall 121 are the same (the same direction).
- the most convex part 110a of the V-shaped land block 101 is offset in the tire width direction from the center of the V-shaped land block 101 in the tire width direction.
- the offset amount is preferably 2.5% to 22.5% of the width-direction dimension of the V-shaped land block 101.
- the block rigidity of the V-shaped land block 101 can be configured in a well-balanced manner, contributing to both on-ice performance and wear resistance performance.
- the circumferential dimension W1 along the tire circumferential direction of the inclined groove portion 161 located on one side in the tire width direction from the bent portion 163 is the tire circumference of the inclined groove portion 162 located on the other side in the tire width direction from the bent portion 163. It is larger than the circumferential dimension W2 along the direction.
- the circumferential dimension W1 and the circumferential dimension W2 mean the lengths of the inclined groove part 161 and the inclined groove part 162 along the tire circumferential direction, like the circumferential dimension of the other groove portions.
- the sipe 140 includes a sipe that is wider in the tire width direction than the sipe 130. Specifically, the sipe 140 and the communication sipe 141 shown in FIG. 4 are wider in the tire width direction than the sipe 130.
- the width direction dimension which is the dimension of the inclined groove part 161 in the tire width direction is larger than the width direction dimension of the inclined groove part 162. Further, the end portion 131 of the sipe 130 terminates on the end portion side in the tire width direction, more specifically, on the side wall 100a side than the most convex portion 110a of the convex portion 110.
- the circumferential dimension W1 of the inclined groove 161 is not less than 1.32 times and not more than 2.17 times the circumferential dimension W2 of the inclined groove 162.
- W1 is preferably 1.64 times to 1.96 times W2.
- the ratio of the area of the width direction inclined groove 160 to the area of the V-shaped land block 101 is 10% or more and 40% or less. Note that the ratio is preferably 12% to 32%.
- the ratio of the area of the V-shaped land block 101 to the ground contact area of the pneumatic tire 10 is 10% or more and 31% or less. Note that the ratio is preferably 9% to 12%.
- the ratio of the dimension in the width direction of the inclined groove 161 to the width of the V-shaped land block 101 in the tire width direction (between the side wall 100a and the side wall 100b) is 50% or more and 78% or less.
- the ratio is preferably 52% to 68%.
- the circumferential dimension of the inclined groove 161 is preferably about 2.7 to 6.1 mm, for example, and the circumferential dimension of the inclined groove 162 is preferably about 1.4 to 3.9 mm, for example.
- FIG. 6 is a partially enlarged plan view of the central land portion row 200.
- the central land portion row 200 is a composite land portion row that is provided along the tire circumferential direction (a land portion row 201 (first land portion row) and a land portion row 202 (second land portion row)).
- the land portion row 201 and the land portion row 202 are adjacent to each other in the tire width direction.
- the land portion row 201 is provided closer to the tire equator line CL than the land portion row 202. Further, at least a part of the central land portion row 200 is provided in the center region including the tire equator line CL.
- the definition of the center area is as described above.
- the land portion row 201 is composed of a plurality of land portion blocks 210 (first land portion blocks) formed along the tire circumferential direction.
- the land portion row 202 is constituted by a plurality of land portion blocks 260 (second land portion blocks) formed along the tire circumferential direction.
- the land portion block 210 is formed with a terminal inclined groove 220 (first terminal inclined groove) that is inclined with respect to the tire width direction and opens in the side wall 210a on the land portion row 202 side.
- the land block 210 is also formed with a wedge-shaped notch groove 240 that opens in the side wall 210b opposite to the land row 202 side.
- the notch groove 240 is not limited to a wedge shape, and may be any shape that tapers toward the tip of the notch groove 240.
- One end of the end inclined groove 220, specifically, the end 221 ends in the land block 210. Further, the front end 241 of the notch groove 240 also ends in the land block 210.
- transverse inclined grooves that divide the adjacent land blocks 260 are formed between adjacent land blocks 260. Specifically, a transverse inclined groove 270 is formed between adjacent land blocks 260.
- the transverse inclined groove 270 is inclined in the same direction as the end inclined groove 220. That is, in the tread surface view, the extending direction of the transverse inclined groove 270 and the extending direction of the terminal inclined groove 220 are the same direction.
- a plurality of sipes 230 extending in a direction different from the extending direction of the transverse inclined groove 270 and inclined with respect to the tire width direction are formed.
- the land block 260 is also formed with a plurality of sipes 290 extending in a direction different from the extending direction of the transverse inclined grooves 270 and inclined with respect to the tire width direction.
- the sipe 230 and the sipe 290 are zigzag in a tread surface view.
- the terminal inclined groove 220 and the notched groove 240 are located on the extension line along the transverse inclined groove 270.
- the land block 260 is inclined in the same direction as the terminal inclined groove 220 and has an opening (terminal inclined groove 280 (second terminal inclined groove) formed on the side wall opposite to the first land portion row side.
- the sipe 230 includes a communication sipe 231 that communicates with the terminal inclined groove 220.
- One end of the communication sipe 231 communicates with the terminal portion (end portion 221) of the terminal inclined groove 220.
- the other end of the communication sipe 231 opens in the side wall 210b opposite to the land portion row 202 side.
- the end inclined groove 220 and the transverse inclined groove 270 are inclined in the opposite direction to the sipe 230 and the sipe 290 with respect to the tire width direction.
- the transverse inclined groove 270 has a first groove width portion 271 (first groove portion) having the same circumferential dimension (groove width) as the terminal inclined groove 220, and a circumferential direction dimension (groove width) more than the first groove width portion 271.
- first groove width portion 271 has a wide second groove width portion 272 (second groove portion).
- the first groove width portion 271 is formed on the land portion block 210 side.
- a saddle-like groove is formed at the end of the transverse inclined groove 270 opposite to the land part row 201 side.
- a hook-shaped groove 273 is formed at the end of the transverse inclined groove 270.
- the hook-shaped groove portion 273 is inclined in the same direction as the sipe 290, and is inclined in the opposite direction with respect to the terminal inclined groove 280 and the tire width direction.
- the bowl-shaped groove part 273 communicates with the second groove width part 272.
- a circumferential groove 60 (inner circumferential circumferential groove) extending in the tire circumferential direction is formed between the land portion row 201 and the land portion row 202.
- the circumferential groove 60 does not extend linearly in the tire circumferential direction.
- the circumferential groove 60 has a circumferential groove portion and an inclined lug groove portion.
- the circumferential groove 60 communicates with a circumferential groove 61 that extends in the tire circumferential direction and is inclined with respect to the tire circumferential direction, and a circumferential groove 61 that is adjacent in the tire circumferential direction, and extends in the tire width direction.
- a circumferential groove 61 that is adjacent in the tire circumferential direction, and extends in the tire width direction.
- these side walls are inclined in the direction opposite to the sipe 230 and sipe 290 with respect to the tire width direction, that is, with respect to the tire width direction. Further, the inclination angle of the sipe 230 and the sipe 290 with respect to the tire width direction is larger than the inclination angle of the side walls (side walls 210c, 210d, 220c, 220d) with respect to the tire width direction.
- the inclination angle of Sipe 230 and Sipe 290 is 9 degrees or more and 39 degrees or less.
- the tilt angle is preferably 12 degrees to 24 degrees.
- the inclination angle of the side walls is 6 degrees or more and 36 degrees or less.
- the inclination angle is preferably 11 degrees to 31 degrees.
- the extending direction of the transverse inclined groove 270 is inclined in a direction different from the sipe 230 and sipe 290 with respect to the tire width direction. Specifically, in the tread surface view, the extending direction of the extension line along the transverse inclined groove 270 is inclined upward. On the other hand, the extending direction of the sipe 230 and the sipe 290 is inclined upward to the left.
- the total area of the end inclined groove 220, the end inclined groove 280, and the transverse inclined groove 270 in the contact surface with the road surface of the pneumatic tire 10 is defined as a groove total area S1, and one end portion in the tire width direction of the central land portion row 200
- S1 / S2 is 0.05 or more and 0.25 or less.
- S1 / S2 is preferably 0.05 to 0.15.
- the interval in the circumferential direction between adjacent sipes 230 in the land block 210 is 3.3 mm or more and 10.0 mm or less.
- the sipe interval is preferably 3.7 mm to 5.6 mm.
- the interval in the circumferential direction between adjacent sipes 290 in the land block 260 is 4.4 mm or more and 10.0 mm or less.
- the sipe interval is preferably 5.5 mm to 8.3 mm.
- the interval in the circumferential direction of the sipe 230 is a “sipe interval” shown in FIG. 11, and is an interval (distance) between adjacent sipes 230 that intersects a straight line parallel to the tire circumferential direction.
- the negative rate of the land block 210 is 8.9% or more and 20.7% or less. Note that the negative rate is preferably 11.8% to 17.8%. Moreover, the negative rate of the land block 260 is 11.8% or more and 27.4% or less. The negative rate is preferably 15.7% to 23.5%.
- the average negative rate of the land block 210 and the land block 260 adjacent to the land block 210 is 13.2% or more and 30.8% or less.
- the negative rate is preferably 17.6% to 26.4%.
- the negative rate of the land block 210 is the total area of the land portion of the land block 210 (not including the closed sipes that are in contact with the ground) and the terminal inclined groove 220 and the notch groove 240 formed in the land block 210. Is the ratio (percentage) of the total area of the end inclined groove 220 and the notched groove 240 to.
- the negative rate of the land block 260 is the terminal slope with respect to the total area of the land part of the land block 260 (not including the closed sipes that are in contact with the ground) and the terminal slope groove 280 formed in the land block 260. The ratio of the area of the groove 280.
- the inclination angle of the sipe 290 with respect to the tire width direction, the inclination angle of the terminal inclination groove 220, the second terminal inclination groove, and the transverse inclination groove 270 with respect to the tire width direction are the sipe 230 with respect to the tire width direction in the land block 210.
- the inclination angle of the terminal inclined groove 220 are equal to or greater than the inclination angle of the terminal inclined groove 220.
- end inclined groove 220, the second end inclined groove and the transverse inclined groove 270 are inclined in the opposite direction to the sipe 230 and the saddle sipe 290 with respect to the tire width direction.
- FIGS. 7A and 7B are explanatory diagrams of the rotational moment generated in the land block 210 and the rotational moment generated in the conventional land block 210P.
- the force in the vector direction along the side wall at the tire circumferential end does not attempt to rotate the land block 210 and the land block 210P.
- the input in the vector direction perpendicular to the side wall generates a moment to rotate the land block (the left rotation direction in FIGS. 7A and 7B).
- FIG. 8 is a partially enlarged plan view of the shoulder land portion row 300in.
- FIG. 9 is an enlarged perspective view of the land portion block 310 constituting the shoulder land portion row 300in.
- the shoulder land portion row 300in and the shoulder land portion row 300out have symmetrical shapes with respect to the tire equator line CL.
- the shape of the shoulder land portion row 300in will be described.
- the land portion block 310 constituting the shoulder land portion row 300in is a land portion block defined by the circumferential groove 50 and the lug groove 70.
- the land block 310 is provided at a tread end including a contact end with the road surface in the tire width direction.
- the land block 310 includes a zigzag circumferential sipe 320 extending in the tire circumferential direction, a zigzag width sipe 330 (equator side width sipe) extending in the tire width direction, and a width sipe 340 (tread end side width).
- Direction sipe ).
- Width direction sipe 330 is located closer to tire equator line CL than circumferential direction sipe 320.
- the width direction sipe 340 is located closer to the tread end side in the tire width direction than the circumferential direction sipe 320.
- the zigzag circumferential sipe extending in the tire circumferential direction refers to a sipe that is bent in a zigzag manner in the extending direction in the tire circumferential direction in the tread surface.
- the zigzag widthwise sipe extending in the tire width direction is a sipe that is bent in a zigzag shape in the extending direction in the tire width direction in the tread surface.
- the total L1 of the width direction edge components that become edge components in the tire width direction by the circumferential sipe 320, and the circumferential edge component that becomes edge components in the tire circumferential direction by the width direction sipe 330 and the saddle width direction sipe 340 The ratio L1 / L2 to the total L2 is 16.0% or more and 37.4% or less. L1 / L2 is preferably 21.4% to 32.0%.
- the edge component is an edge effect that works in a direction perpendicular to the input direction from the road surface to the pneumatic tire 10 such as a groove or sipe when the pneumatic tire 10 scratches the road surface with a groove or sipe. This is the dimension (length) in which the sipe extends in the direction perpendicular to the input direction from the road surface.
- the edge component of one widthwise sipe in the land block may be a straight line on the tread surface, or even if the widthwise sipe has an amplitude such as a zigzag waveform. It is a dimension projected on a straight line inclined 90 degrees, that is, on a straight line parallel to the tire width direction.
- the edge component is a so-called circumferential edge component along the tire width direction of the land block where a force acts on the circumferential direction of the tire.
- the edge component includes a block edge component due to a block edge and a sipe edge component due to a sipe edge.
- the ratio (L1 + L2) / L3 of the total L1 and the total L2 to the average dimension L3 in the tire circumferential direction of the land block 310 is 3.4 or more and 7.8 or less.
- the ratio is preferably 3.9 to 5.9.
- the average dimension L3 means that when there are a plurality of variations in the circumferential dimension of the land block 310 formed along the tire circumferential direction, that is, when the shoulder land portion row 300in has a plurality of pitches, It means the average value of the circumferential dimension of the land block 310.
- the zigzag repetition period T of the circumferential sipe 320 is equal to the interval h between the widthwise sipes 340 adjacent to each other in the tire circumferential direction. Note that the period T may be smaller than the interval h.
- width direction amplitude (amplitude A1) that is the amplitude in the tire width direction of the circumferential sipe 320 is larger than the circumferential direction amplitude (amplitude A2, A3) that is the amplitude in the tire circumferential direction of the width direction sipe 340.
- the land block 310 is formed with a circumferential sub-sipe extending in the tire circumferential direction. Specifically, a linear circumferential linear sipe 351 and a circumferential linear sipe 352 are formed in the land block 310. Note that the circumferential sub-sipe does not have to be linear like the circumferential linear sipe 351 and the circumferential linear sipe 352, and may have a single bent portion having a shallow angle.
- One end of the circumferential linear sipe 351 and the circumferential linear sipe 352 communicates with the widthwise sipe 340.
- the other ends of the circumferential linear sipe 351 and the circumferential linear sipe 352 open to the side walls 310a and ridges 310b located on the tire circumferential direction end side of the land block 310.
- the circumferential sipe 320 includes a linear portion extending linearly in parallel with the tire circumferential direction. Specifically, the circumferential sipe 320 includes a straight portion 321 and a straight portion 322).
- the straight portion 321 and the straight portion 322 are formed at the end of the land block 310 in the tire circumferential direction. Specifically, the linear portion 321 is formed on the side wall 310a side of the end of the land block 310 in the tire circumferential direction, and the linear portion 322 is formed on the side wall 310b side.
- the linear portion 321 and the linear portion 322 are formed at positions offset from the center position CT of the amplitude A1 in the tire width direction of the circumferential sipe 320. That is, the linear part 321 and the linear part 322 are formed at positions shifted from the center position CT in the tire width direction.
- the end portion 332 on the tread end side of the width direction sipe 330 communicates with the circumferential direction sipe 320.
- the end 341 of the width direction sipe 340 on the tire equator line CL side does not communicate with the circumferential sipe 320 but ends in the land block 310 on the tread end side of the circumferential sipe 320.
- the end 331 of the width direction sipe 330 on the tire equator line CL side communicates with a circumferential groove adjacent to the land block 310, specifically, a circumferential groove 50 formed on the tire equator line CL side. To do.
- the end 341 on the tread end side of the width direction sipe 340 terminates in the land block 310.
- the end portion 332 on the tread end side of the width direction sipe 330 communicates with the top portion 323 of the zigzag circumferential sipe 320.
- the width sipe 340 is located on an extension line of the width sipe 330 that communicates with the top 323 of the zigzag circumferential sipe 320.
- the circumferential sipe 320 has a predetermined amplitude (amplitude A1) in the tire width direction.
- the end 341 of the width sipe 340 is located within the amplitude A1.
- a notch-shaped stepped portion such as the land block 310 is notched is formed on the side wall 310b located on the tire circumferential direction end side of the land block 310. Specifically, a stepped portion 360 is formed at the end of the land block 310 on the tread end side in the tire width direction.
- the stepped portion 360 is formed only on one side wall of the land block 310 on the tire circumferential direction end side, specifically, only on the side wall 310b.
- the stepped portion 360 has a raised bottom surface located on the outer side in the tire radial direction from the groove bottom 70 b of the lug groove 70. Specifically, the stepped portion 360 has a rectangular raised bottom surface 361 extending in the tire width direction.
- the raised bottom surface 361 is inclined with respect to the tire radial direction in the tire side view.
- the position of the raised bottom surface 361 in the tire radial direction is not particularly limited, but from the viewpoint of securing the block rigidity of the land block 310, 25% to 50% of the height of the land block 310 (length in the tire radial direction) It is preferable that
- One end portion of the circumferential straight sipe 352 specifically, the end portion 352a on the side wall 310b side, opens to the side wall 310b on the tire circumferential direction end on the stepped portion 360 side of the land block 310. That is, the end 352a opens to the end 362 of the stepped portion 360 on the tire equator line CL side.
- the other end portion of the circumferential straight sipe 352, specifically, the end portion 352b on the width direction sipe 340 side communicates with the width direction sipe 340.
- the raised bottom surface 361 is inclined such that the height in the tire radial direction decreases toward the tire circumferential direction end of the land block 310, that is, toward the side wall 310b.
- a zigzag surface having a predetermined amplitude in the tire circumferential direction is formed on the side wall on the tire circumferential direction end side of the land block 310.
- zigzag surfaces 380 are formed on the side wall 310a and the side wall 310b, respectively.
- the zigzag surface 380 is formed at the end of the side wall 310a and the side wall 310b on the tire equator line CL side.
- the zigzag surface 380 has the same shape as the widthwise sipe 340 in the tread surface view.
- FIG. 10 is a diagram showing the stipulations of various dimensions of the V-shaped land part row 100.
- FIG. 11 is a diagram showing the definition of various dimensions of the central land row 200.
- FIG. 12 is a diagram showing various dimensions of the shoulder land portion row 300in.
- FIG. 13 is a partial plan development view of a pneumatic tire 10A in which a pitch different from that of the pneumatic tire 10 shown in FIGS. 1 to 12 is set.
- the pneumatic tire 10 (and the pneumatic tire 10A, hereinafter the same) includes at least one sipe extending in the tire width direction in at least some of the land blocks. Is formed.
- the average sipe interval that is the average interval between adjacent sipes in the tire circumferential direction is h and the average pitch length that is the average dimension of the repeating unit of the land block in the tire circumferential direction is L, the following relationship is satisfied. preferable.
- 0.130 ⁇ (h / L) ⁇ 0.400 (H / L) is more preferably in the range of 0.137 to 0.197, and still more preferably in the range of 0.144 to 0.19.
- the average sipe interval h (unit: mm) is an average circumferential dimension between the sipe in the land block and the sipe adjacent in the tire circumferential direction.
- the circumferential dimension between the tire circumferential direction end of the land block and the sipe is used.
- the circumferential dimension between one tire circumferential end of the land block and the other tire circumferential end is obtained.
- the land block is divided by the sipe substantially evenly in the tire circumferential direction, but may not be even.
- the average sipe interval h is an average value in all land blocks provided on the circumference of the land block block.
- the pitch is one basic unit of a tread pattern composed of a pattern that is continuously repeated in the tire circumferential direction with one or more types of length.
- the average pitch length L (unit: mm) refers to the distance of the pitch in the tire circumferential direction. Unless otherwise specified, the average pitch length L refers to the circumferential dimension of the average pitch in the land block row.
- the average sipe interval h and the average pitch length L satisfy the following relationship.
- H * L 140 (mm) 2 ⁇ (h * L) ⁇ 350 (mm) 2 (Hereafter, unit (mm) 2 is omitted) (H * L) is more preferably in the range of 148 to 250, and further preferably in the range of 150 to 220.
- the average sipe interval h of the center land block preferably satisfies the relationship of 3.0 mm ⁇ h ⁇ 7.1 mm.
- the average sipe interval h of the center land block preferably satisfies the relationship of 3.5 mm ⁇ h ⁇ 6.6 mm, and more preferably satisfies the relationship of 3.7 mm ⁇ h ⁇ 5.6 mm.
- the average sipe interval h of the second land block preferably satisfies the relationship 3.3 mm ⁇ h ⁇ 7.7 mm.
- the average sipe interval h of the second land block preferably satisfies the relationship of 3.8 mm ⁇ h ⁇ 7.2 mm, and more preferably satisfies the relationship of 4.1 mm ⁇ h ⁇ 6.1 mm.
- the average sipe interval h of the shoulder portion land block satisfies a relationship of 3.7 mm ⁇ h ⁇ 8.5 mm.
- the average sipe interval h of the shoulder portion land block preferably satisfies the relationship of 4.2 mm ⁇ h ⁇ 8.0 mm, and more preferably satisfies the relationship of 4.5 mm ⁇ h ⁇ 6.8 mm.
- center part The definitions of the center part, the second part and the shoulder part are as described above.
- a plurality of sipes extending in the tire width direction are formed in the land block of the pneumatic tire 10 according to the present embodiment.
- the average sipe interval h preferably satisfies the relationship of 3.4 mm ⁇ h ⁇ 7.9 mm.
- the average sipe interval h preferably satisfies the relationship of 3.9 mm ⁇ h ⁇ 7.4 mm, and more preferably satisfies the relationship of 4.2 mm ⁇ h ⁇ 6.3 mm.
- the average pitch length L preferably satisfies the relationship 19.2 mm ⁇ L ⁇ 44.6 mm.
- the average pitch length L preferably satisfies the relationship 22.0 mm ⁇ L ⁇ 41.6 mm, and more preferably satisfies the relationship 23.6 mm ⁇ L ⁇ 35.4 mm.
- the average block edge component that is the average of the edge components in the tire circumferential direction of all land blocks is Dball
- the average sipe edge component that is the average of the edge components in the tire circumferential direction of all sipes is Dsall
- the average block stiffness, which is the average of the stiffness values of the partial blocks, is G, it is preferable to satisfy the following relationship.
- the edge component is as described above.
- the block stiffness that is the basis of the average block stiffness G is a value when shear deformation is applied in the tire circumferential direction.
- the block rigidity per unit area is calculated by the following equation.
- the average block edge component that is the average of the edge components in the tire circumferential direction of all land blocks is Dball
- the average sipe edge component that is the average of the edge components in the tire circumferential direction of all sipes is Dsall
- (Dballc / Dsallc) for the center land block is Pc
- (Dball 2 / Dsall 2 ) for the second land block is P 2
- the shoulder land block is targeted.
- an average sipe interval is the average interval between sipes adjacent in the tire circumferential direction and hc, if the average sipe interval in the second portion land portion blocks and h 2, to satisfy the following relation Is preferred.
- the average sipe interval in the shoulder portion land block is hs, it is preferable that the following relationship is satisfied.
- V-shaped land part row 100 The V-shaped land block 101 has a convex portion 110 on one side wall in the tire circumferential direction and a concave portion 120 on the other side wall, and the inclination angles of the side walls on both sides thereof are the same.
- the sipe 130, 140 or the end inclined groove 150 has the same inclination angle as the side wall. For this reason, by having a bent portion at the most convex portion 110a (central portion) where the vertex of the convex portion 110 is present, the rigidity of the central portion is higher than that of a rectangular land block having no bent portion, and a V-shaped The rigidity of the entire land block 101 is increased. Thereby, falling of the V-shaped land block 101 and lifting from the road surface are suppressed, and the ground contact area is improved.
- both ends of the V-shaped land block 101 in the tire width direction have lower block rigidity than the center, so that the edge effect is improved by greatly deforming in the tire circumferential direction with respect to the tire circumferential direction input during braking.
- the V-shaped land block has improved rigidity at the center, so by increasing the width dimension relative to the circumferential dimension of the V-shaped land block, a ground contact area is secured at the center and both ends
- the dimension of the width direction of the portion was increased to increase the length of the edge with respect to the tire circumferential direction.
- the V-shaped land block is appropriately deformed to the extent that a ground contact area can be secured. The edge effect by the block edge and the sipe edge was improved.
- the circumferential dimension of the V-shaped land block 101 is larger than the width dimension of the V-shaped land block 101. For this reason, the block rigidity in the tire circumferential direction of the V-shaped land portion block 101 is increased. Since the circumferential dimension of the V-shaped land block 101 is increased, the block rigidity in the tire circumferential direction at the center in the tire width direction is increased, and the block rigidity in the tire circumferential direction at both ends in the tire width direction is also increased. Further, the central portion maintains a high block rigidity with respect to both end portions.
- the ground contact area is further improved, and the block edge and the sipe edge are strongly pressed against the road surface due to the increase in block rigidity, thereby improving the edge effect.
- Both ends of the V-shaped land block 101 are also prevented from being greatly deformed and the contact area is improved, so that the edge effect that is strongly pressed against the road surface due to increased block rigidity is improved instead of the edge effect due to deformation.
- wear resistance performance is improved by increasing the block rigidity.
- the fall of the V-shaped land block 101 during braking of the vehicle equipped with the pneumatic tire 10 and particularly the fall in the tire circumferential direction can be suppressed, and the wear of the V-shaped land block 101 can be effectively suppressed.
- the circumferential dimension of the V-shaped land block 101 may be the same as the width dimension in consideration of the effects that can be exhibited. This is because, if the width direction dimension is not increased with respect to the circumferential direction dimension of the land block as in the prior art, there is an effect.
- the V-shaped land block 101 has high rigidity in the tire circumferential direction at both the center and both ends, the ground contact area of the V-shaped land block 101 during braking is greatly improved.
- the inclination angle ⁇ 1 of the convex side wall 111 (112) with respect to the tire width direction is the same as the inclination angle ⁇ 2 of the concave side wall 121 (122) with respect to the tire width direction.
- the inclination angle ⁇ 5 with respect to the tire width direction of the sipe 130 and the terminal inclined groove 150 is the same as the inclination angle ⁇ 1 (inclination angle ⁇ 2) with respect to the tire width direction of the convex side wall portion 111 (concave side wall portion 121).
- the end 131 of the sipe 130 and the end 151 of the terminal inclined groove 150 are terminated in the V-shaped land block 101. Further, on the extension line of the communication sipe 141, the side wall 100c of the V-shaped land block 101 constituting the end 151 of the terminal inclined groove 150 is continuous.
- the circumferential dimension of the V-shaped land block 101 can be made larger than the width dimension as compared to the case where the V-shaped land block 101 is divided by a sipe or an inclined groove from end to end. .
- the block rigidity of the V-shaped land portion block 101 is increased, the ground contact area is increased, and the block edge and the sipe edge due to the block rigidity are increased.
- the wear resistance can be improved while improving the performance on ice.
- the inclined groove (terminal inclined groove 150) is terminated and a part thereof is replaced by the communication sipe 141. Is. Although I want to divide with an inclined groove from end to end of the V-shaped land block 101, when divided, the circumferential dimension of the land block is smaller than the width dimension, so the block rigidity decreases, The ground contact area is reduced.
- the sipe is communicated with the terminal inclined groove 150 as the communication sipe 141.
- the part where the communication sipe 141 exists is originally a part where the block groove is generated by dividing by the inclined groove. This is because the edge is not reduced as much as possible by forming the sipe while preventing the block rigidity from being lowered.
- the V-shaped land block 101 is divided by the terminal inclined groove 150 and the communication sipe 141, the block rigidity is lower than the part connected without being divided, and the terminal inclined groove 150 If the sipe is separated without communicating the sipe, only the block rigidity of the V-shaped land block 101 of the separated portion is increased, and the distribution of the block rigidity in the tire width direction of the V-shaped land block 101 is gentle. Rigidity steps will occur without changing.
- the V-shaped land block 101 by connecting the communication sipe 141 and the terminal inclined groove 150, the V-shaped land block 101 is compared with the shape in which the inclined groove crosses the V-shaped land block 101. Block rigidity is greatly improved. As a result, the contact area and the edge effect can be improved, and the wear resistance can be improved while improving the performance on ice.
- a communication sipe 142 that communicates with the notch recess 170 is formed, and the width of the notch recess 170 in the tire circumferential direction increases toward the side wall 100b of the V-shaped land block 101. For this reason, the block edge component of the V-shaped land portion block 101 is increased by the notch recess 170.
- a notch recess 170 that is a wedge-shaped (triangular) wedge-shaped groove, compared to the case where the communication sipe 142 is simply opened in the side wall 100b, the vicinity of the opening end of the communication sipe 142
- the block rigidity of the portion where the block rigidity is originally low, where the angle between the sipe opening end of the V-shaped land block 101 and the side wall of the V-shaped land block 101 is an acute angle, is increased.
- the force for pressing the communication sipe 142 against the road surface is increased, and the edge effect of the sipe edge is improved. Further, since the block rigidity is increased in this way, it is possible to prevent the sipe forming portion from being lifted from the road surface so as to be turned up at the time of braking, and the wear resistance performance can be prevented from being lowered.
- winter tires have a long contact length near the tire equator line and a short contact length outside the tire width direction. Therefore, in the land block, sipe edges and blocks in the tire circumferential direction near the tire equator line with a long contact length. While increasing the edge positively to improve the edge effect, block rigidity is secured at the outer portion in the tire width direction.
- the side wall at the tire circumferential direction end of the V-shaped land block is lengthened near the tire equator and shortened at the outer side in the tire width direction.
- the block rigidity on the tire equator line side of the V-shaped land portion block is excessively lowered, and the rigidity balance in the tire width direction of the V-shaped land portion block is deteriorated.
- a short sipe 130 is formed on the long convex side wall 111 side, and a long sipe 140 is formed on the short convex side wall 112, but if this is reversed, the tire of the V-shaped land portion row 100 The rigidity balance in the width direction is greatly broken.
- the short sipe 130 near the tire equator line and the long sipe 140 outside the tire width direction balance the block rigidity in the tire width direction so that the block rigidity is also on the tire equator line CL side. Is secured.
- the sipe 140 on the outer side in the tire width direction not only the block rigidity due to the bent portions (the convex portion 110 and the concave portion 120) is increased, but also the sipe edge is increased. Furthermore, since the block rigidity on the outer side in the tire width direction is increased, the force for pressing the V-shaped land block 101 including the sipe 140 against the road surface is increased, and the sipe edge is increased. In addition to the high rigidity of the central block as in the conventional V-shaped land block, the central portion having a bent portion and the block on the tire equator line CL side and the tire width direction outside of the V-shaped land block 101 are also blocks. Since the rigidity is improved, the wear resistance performance of the V-shaped land block 101 is also improved.
- the circumferential dimension W1 of the inclined groove 161 located on one side (tire equator line side) in the tire width direction from the bent portion 163 is the other side in the tire width direction from the bent portion 163 ( It is wider than the circumferential dimension W2 of the inclined groove 162 located on the tread end side.
- the tire width between the V-shaped land blocks 101 adjacent in the circumferential direction is set so that the land block does not fall down, that is, the block rigidity is increased. Only in one direction, the circumferential dimension of the land block is increased, and the circumferential dimension of the inclined groove 162 is smaller than that of the inclined groove 161. For this reason, the most convex part 110a and the most concave part 120a are in different positions.
- the block rigidity as the central land portion row 200 is greatly improved.
- the block rigidity of the central land section row 200 as a whole is increased, so that the ground contact area is improved and the force that presses the land block 210 (and the land block 260) and the sipe 230 (and sipe 290) against the road surface. Will increase. Thereby, the wear resistance can be improved while improving the performance on ice by increasing the edge effect.
- the terminal inclined groove 220 and the notched groove 240 are located on the extended line along the transverse inclined groove 270. Further, a hook-shaped groove 273 is formed at the end of the transverse inclined groove 270. For this reason, the block edge component increases by acting like one lug groove crossing the central land portion row 200 while ensuring the block rigidity.
- the circumferential groove 60 includes a circumferential groove 61 that extends in the tire circumferential direction and is inclined with respect to the tire circumferential direction, and an inclined lug groove 62 that is inclined in the same direction as the terminal inclined groove 220 with respect to the tire width direction.
- a circumferential groove 60 that does not extend linearly in the tire circumferential direction further increases the block edge component.
- the side walls 210c, 210d, 220c, 220d located at the ends of the land block 210 and the land block 260 in the tire circumferential direction are inclined with respect to the tire width direction. Further, these side walls are inclined in the direction opposite to the sipe 230 and sipe 290 with respect to the tire width direction.
- the ratio S1 / S2 is a negative rate of the central land portion row 200, and indicates the ratio of the groove area in the central land portion row 200. If the negative rate is large, the area of the groove part increases and the edge effect due to the block edge component by the groove improves, but the area of the land block decreases, so the block rigidity decreases, the contact area decreases, Wear resistance is reduced.
- the block rigidity of the central land row 200 is optimally improved by the end inclined groove 220, the end inclined groove 280, and the transverse inclined groove 270.
- the block rigidity is increased and the ground contact area is improved.
- the force which presses the land part block 210 and the land part block 260, and the sipe 230 and the sipe 290 to a road surface increases. Thereby, the wear resistance can be improved while improving the performance on ice by increasing the edge effect.
- S1 / S2 is preferably 0.05 or more and 0.25 or less, and when S1 / S2 exceeds 0.25, the negative rate increases and the land block area is greatly reduced. Stiffness decreases too much. For this reason, the ground contact area is significantly reduced and the wear resistance performance is significantly reduced.
- the rigidity of the land block 310 is improved and the ground contact area is improved.
- the edge effect by the improvement of the block edge and the force which presses a block edge and a sipe edge to a road surface, and a block edge improves, and wear resistance performance improves.
- the edge effect should be larger. Therefore, the amplitude A1 of the zigzag portion is increased by forming in the land block 310 a circumferential sipe 320 that exhibits an edge effect in the tire width direction that hardly reduces the rigidity in the tire circumferential direction. Thereby, the sipe edge in the tire circumferential direction can be exhibited and the edge effect in the tire circumferential direction can be improved.
- a linear circumferential straight sipe 351 and a circumferential linear sipe 352 are formed in the land block 310.
- the circumferential sipe 320, the circumferential linear sipe 351, and the circumferential linear sipe 352 can also increase the edge effect in the tire width direction.
- the tire equator line CL side of the land part block 310 has high rigidity and is prevented from being deformed by the inclined side wall of the buttress part which is the side wall on the outer side of the tread, like the tread end side.
- the ground contact length is longer than the tread end side.
- the end portion 332 of the width direction sipe 330 on the tire equator line CL side communicates with the circumferential sipe 320. Further, the end portion 331 of the width direction sipe 330 also communicates with the circumferential groove 40. For this reason, the sipe edge component of the land block 310 can be increased.
- the end 341 of the width direction sipe 340 on the tire equator line CL side does not communicate with the circumferential sipe 320 but ends in the land block 310.
- the outer side wall of the tread end of the land block 310 is highly rigid and restrained from being deformed by the inclined side wall of the tobutless part, and because the ground contact length is shorter than the tire equator line CL side.
- the width sipe 340 on the outer side of the tread end is It ends in the land block 310 without communicating with 320. Further, the other end of the width-direction sipe 340 terminates without communicating with the main groove or the buttress portion.
- the block rigidity on the tire equator line CL side of the land block 310 decreases, the block rigidity on the outer side of the tread end is improved, so that the block rigidity of the shoulder land section row 300 in can be maintained. Further, by maintaining the block rigidity of the shoulder land portion row 300in, it is possible to maintain the wear resistance performance while improving the on-ice performance by improving the edge effect by the sipe edge component while securing the contact area.
- the end 341 of the width direction sipe 340 is located within the amplitude A1. Further, the width direction sipe 340 is located on an extension line of the width direction sipe 330 communicating with the top portion 323 of the zigzag circumferential sipe 320. With such a configuration, the edge effect by the sipe edge component can be further enhanced.
- a notch-shaped step portion 360 is formed on the side wall 310b.
- the stepped portion 360 is formed at the end of the land portion block 310 on the tread end side in the tire width direction and has a raised bottom surface 361.
- the raised bottom surface 361 has a rectangular shape extending in the tire width direction.
- the volume of the lug groove 70 formed between the adjacent land blocks 310 is increased, and so-called snow column shear force is improved. To do. Furthermore, drainage performance is also improved.
- the stepped portion 360 is formed at the end of the land block 310 on the tread end side, it is easy to take in ice and snow, and further, ice and snow solidified as a snow column are easily discharged.
- the stepped portion 360 is formed not at the deep groove bottom but at the end on the tread end side. Specifically, the raised bottom surface 361 facilitates the discharge of ice and snow solidified as a snow column.
- the side wall at the circumferential end of the land block 310 is bent at the position of the stepped portion 360, so that the land portion is more than the straight side wall where the stepped portion 360 is not formed.
- the block edge component due to the side wall 310b of the block 310 also increases.
- a land block formed by the stepped portion 360 is formed.
- the tread end side of the land block 310 is highly rigid and restrained from being deformed by the inclined side wall of the buttress portion, so that the block rigidity of the land block 310 can be maintained.
- the stepped portion 360 can maintain the wear resistance while improving the performance on ice. Moreover, on-snow performance and drainage performance can be improved.
- average sipe interval h / average pitch length L is preferably 0.130 ⁇ (h / L) ⁇ 0.400, and h / L is less than 0.130.
- the pitch length is relatively large, but the sipe interval is extremely small. As a result, the number of sipes becomes very large, and the block rigidity of the land block is remarkably lowered.
- the sipe interval becomes relatively large, but the pitch length becomes remarkably small.
- the number of sipes is very small, such as one or two, the pitch length is remarkably reduced, and the block rigidity of the land block is not improved even if the sipe interval is increased. Also, the sipe edge component is significantly reduced.
- the sipe interval is also The pitch length is too small.
- the sipe interval becomes small, the land block is divided into small pieces, and the block rigidity is lowered. Further, when the pitch length is reduced, the block rigidity of the land block is reduced. As a result, the block rigidity becomes too low.
- the ground contact length is higher in the order of the center area (center land block), the second area (second land block), and the shoulder area (shoulder land block).
- the longest ground contact length For this reason, it is effective to exhibit the sipe edge and the block edge in the tire circumferential direction during braking using a long contact length.
- the center portion land block it is preferable that 3.0 mm ⁇ h ⁇ 7.1 mm. If h is less than 3.0 mm, the land block is divided into small portions, and the block rigidity becomes too low. Because. On the other hand, if h exceeds 7.1 mm, the block rigidity increases, but the number of sipes becomes too small, so that the sipe edge cannot be exhibited, and the sipe edge effect becomes too small.
- the shoulder portion land block it is preferable that 3.7 mm ⁇ h ⁇ 8.5 mm, and if h is less than 3.7 mm, the block is divided into small pieces and the block rigidity becomes too low. Because. On the other hand, if h exceeds 8.5 mm, the sub-block stiffness increases, but the sipe edge effect becomes too small. The same can be said for the numerical range of the average sipe interval in the second region.
- the ground contact length is shorter than the center area and longer than the shoulder area. Therefore, the sipe interval is larger than the center region and smaller than the shoulder region in order to improve the sipe edge effect and block rigidity. Further, for the same reason as the center region and the shoulder region, it is preferable that the average sipe interval of the second region is in the above range.
- the average sipe interval h of the land block of the entire pneumatic tire 10 is set to 3.4 mm or more and 7.9 mm, but by increasing the sipe interval and reducing the number of sipe, The rigidity is increased, and one sipe edge and one block edge for one land block are increased to the maximum area that can be improved.
- h is less than 3.4 mm, the land block will be divided into small pieces, and the block stiffness will be too small. On the other hand, if h exceeds 7.9 mm, the block rigidity increases, but the sipe edge effect becomes too small.
- the average pitch length L of the land block of the entire pneumatic tire 10 is preferably 19.2 mm ⁇ L ⁇ 44.6 mm. If the pitch length is less than 19.2 mm, the pitch length decreases. If the pitch length exceeds 44.6 mm, the pitch length becomes too large and the block rigidity increases, but the number of pitches per tire circumference decreases. For this reason, the block edge effect is greatly reduced, and the block edge effect becomes too small.
- the sipe interval becomes too small and the block is divided into small blocks, thereby reducing the block rigidity. Pass. Also, if the pitch length becomes too large, the number of pitches decreases, so that the block edge effect becomes too small. Further, no matter how large the pitch length is, if the block is divided into small pieces by sipe, the block rigidity will not be improved.
- the sipe interval increases and the block rigidity increases, but the number of sipe is too small and the sipe edge can be demonstrated.
- the sipe edge effect becomes too small.
- the pitch length becomes small, and the rigidity of each block becomes too small. As a result, the total edge effect is reduced and the block rigidity is not improved.
- the sipe edge component will increase, but the sipe interval will be too small and the block will be divided into smaller parts, resulting in block rigidity. Since the pitch length is too small and the rigidity of each block becomes too small, the block edge effect becomes too small. Therefore, the block rigidity is too small, and the total edge is also lowered.
- the sipe interval will increase and the block rigidity will increase, but the number of sipe will be too small and the sipe edge will not be demonstrated.
- the sipe edge effect becomes too small.
- the pitch length becomes too large, the number of pitches decreases, so that the block edge effect becomes too small. Further, no matter how large the pitch length is, if the block is divided into small pieces by sipe, the block rigidity will not be improved.
- the tire width SEC (hereinafter the same) of passenger car tires in the JATAMA standards (or similar standards such as ETRTO, TRA, etc.) is 165, 175, 185, 195, 205, 215, 225,
- the average sipe spacing and average pitch length are: 4.2mm ⁇ h ⁇ 6.3mm 23.6mm ⁇ L ⁇ 35.4mm More preferably.
- the tire width SEC is 195 (mm) in the case of 195 / 65R15.
- the average sipe spacing and average pitch length of the center land block are: 3.7mm ⁇ h ⁇ 5.6mm 23.6mm ⁇ L ⁇ 35.4mm It is preferable that
- the average sipe interval and average pitch length of the shoulder land block are: 4.5mm ⁇ h ⁇ 6.8mm 23.6mm ⁇ L ⁇ 35.4mm It is preferable that
- the average sipe spacing and average pitch length of the second land block is: 4.1mm ⁇ h ⁇ 6.1mm 23.6mm ⁇ L ⁇ 35.4mm It is preferable that
- the sipe interval and the pitch length are optimized, and by appropriately reducing the number of sipes, the block rigidity is increased, and by reducing the pitch length appropriately, the number of pitches and the number of blocks are reduced.
- the total edge effect can be improved while improving the block rigidity.
- the average sipe interval and average pitch length are: 6.3mm ⁇ h ⁇ 7.9mm 35.4mm ⁇ L ⁇ 44.6mm More preferably.
- the average sipe interval and average pitch length of the center land block are: 5.6mm ⁇ h ⁇ 7.1mm 35.4mm ⁇ L ⁇ 44.6mm It is preferable that
- the average sipe interval and average pitch length of the shoulder land block are: 6.8mm ⁇ h ⁇ 8.5mm 35.4mm ⁇ L ⁇ 44.6mm It is preferable that
- the average sipe interval and average pitch length of the second land block are: 6.1mm ⁇ h ⁇ 7.7mm 35.4mm ⁇ L ⁇ 44.6mm It is preferable that
- the average sipe interval and average pitch length are: 3.4mm ⁇ h ⁇ 4.2mm 19.2mm ⁇ L ⁇ 23.6mm More preferably.
- the average sipe interval and average pitch length of the center land block are: 3.0mm ⁇ h ⁇ 3.7mm 19.2mm ⁇ L ⁇ 23.6mm It is preferable that
- the average sipe spacing and average pitch length of the shoulder land block is 3.7mm ⁇ h ⁇ 4.5mm 19.2mm ⁇ L ⁇ 23.6mm It is preferable that
- the average sipe spacing and average pitch length of the second land block are: 3.3mm ⁇ h ⁇ 4.1mm 19.2mm ⁇ L ⁇ 23.6mm It is preferable that
- (average block edge component Dball / average sipe edge component Dsall) / average block stiffness G is preferably 2.20 ⁇ (Dball / Dsall) /G ⁇ 4.00.
- (Dball / Dsall) / G is less than 2.20 (mm) 3 / N, the sipe edge component is very large with respect to the block rigidity of the average land block, but the block edge component is significantly reduced. This is because the number of sipes increases, the sipe interval decreases, and the block rigidity becomes too low.
- width direction sipe may be inclined with respect to the tire circumferential direction (tire equator line CL) as long as it extends in the tire width direction. This is because an edge component in the tire circumferential direction is generated.
- the average block edge component Dball / average sipe edge component Dsall is preferably 0.15 ⁇ (Dball / Dsall) ⁇ 0.48. If Dball / Dsall is less than 0.15, the sipe edge component will be very large, but the block edge component will be significantly reduced. This is because the number of sipes increases, the sipe interval decreases, and the block rigidity of the land block becomes too small.
- the average sipe interval hs of the shoulder portion land block / the average sipe interval hc of the center portion land block is preferably 1.05 ⁇ (hs / hc) ⁇ 4.00. If hs / hc is less than 1.05, the sipe interval of the shoulder land block becomes small, the number of sipes increases, and the block rigidity of the land block becomes too low. In addition, the sipe edge component increases, but the block edge component decreases too much.
- the other numerical ranges related to the pitch and sipe described above are also defined in order to achieve both the block rigidity of the land block and the edge component. A high level of wear performance.
- Table 1 shows the specifications and test results (ice braking performance and wear resistance performance) of the pneumatic tire (studless tire) according to the example.
- Table 2 shows specifications and test results (ice braking performance and wear resistance performance) of (studless tire) according to the conventional example, the comparative example, and the example.
- Tables 3 to 6 show additional test results of pneumatic tires (studless tires) according to comparative examples and examples.
- Tire size 195 / 65R15 ⁇ Use rim size: 6J ⁇ 15 ⁇
- Set air pressure 240kPa (front and rear wheels) -Wearing vehicle: Anti-lock brake (ABS) wearing vehicle
- “Ice braking performance” is the distance from braking at 20km / h (ABS operation) to stopping (braking distance) at the speed of 20km / h at the time of new tires and after running-in on the ice surface test course. Is a value obtained by averaging five data excluding the maximum value and the minimum value.
- the tire according to the conventional example (Comparative Example 1) is indexed as 100. The larger the value, the shorter the braking distance and the higher the braking performance on ice.
- the relationship between the sipe interval (hs / hc) between the shoulder portion land block (shoulder portion) and the center portion land portion block is set to the above-described range, thereby allowing the first embodiment.
- the tires according to 5 to 5 are improved in “brake performance on ice” and “wear resistance” compared to the tire according to the conventional example.
- Table 3 shows the test results regarding the average sipe interval and the average pitch length, as in Table 1.
- Table 4 shows the test results for the sipe edge component.
- Table 5 shows the test results for average block stiffness.
- Table 6 shows the test results regarding the sipe interval in the same manner as Table 2.
- the central land portion row 200 is provided at a position including the tire equator line CL, and the V-shaped land portion row 100 is provided on the outer side in the tire width direction of the central land portion row 200.
- the land portion row 200 may not necessarily be provided at such a position.
- the V-shaped land portion row 100 may be provided at a position including the tire equator line CL.
- the positions of the shoulder land portion row 300in and the shoulder land portion row 300out are not limited to the shoulder region, and may be provided in the second region or the like.
- both the sipe 130 and the ridge 140 and the terminal inclined groove 150 are formed in the V-shaped land block 101, but only one of the sipe 130, the ridge 140 or the terminal inclined groove 150 is formed. It may be formed.
- the circumferential dimension of the V-shaped land block 101 is larger than the width dimension of the V-shaped land block 101, but the circumferential dimension may be the same as the width dimension.
- the performance on the road surface on ice and the performance on the dry road surface, in particular, the wear resistance performance are higher in dimension. Can be compatible.
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Abstract
Description
図1は、本実施形態に係る空気入りタイヤ10の全体概略斜視図である。図2は、空気入りタイヤ10の一部拡大斜視図である。なお、図1及び図2では、トレッド20に形成されるパターン(トレッドパターン)の一部の図示は省略されている。図3は、トレッド20の一部平面展開図である。
次に、トレッド20の構成ついて説明する。具体的には、トレッド20に設けられるV形陸部列100、中央陸部列200及びショルダー陸部列300outの形状について説明する。
図4は、V形陸部列100の一部拡大平面図である。V形陸部列100は、周方向溝30及び周方向溝40と、幅方向傾斜溝160(ラグ溝)とによって区画された陸部ブロックを備える。具体的には、V形陸部列100は、タイヤ周方向に沿った複数のV形陸部ブロック101によって構成される。
図6は、中央陸部列200の一部拡大平面図である。中央陸部列200は、タイヤ周方向に沿って設けられる(陸部列201(第1陸部列)及び陸部列202(第2陸部列)によって構成される複合陸部列である。陸部列201と陸部列202とは、タイヤ幅方向において隣接する。
なお、切欠き溝240は、楔形に限定されず、切欠き溝240の先端に行くに連れて先細状になるような形状であればよい。
図8は、ショルダー陸部列300inの一部拡大平面図である。図9は、ショルダー陸部列300inを構成する陸部ブロック310の拡大斜視図である。
次に、図10~図13も参照しつつ、空気入りタイヤ10におけるピッチとサイプの関係についてさらに説明する。
なお、(h/L)は、0.137~0.197の範囲がより好ましく、0.144~0.19の範囲がさらに好ましい。
なお(h*L)は、148~250の範囲がより好ましく、150~220の範囲がさらに好ましい。
なお、エッジ成分の定義については、上述したとおりである。また、平均ブロック剛性Gの元となるブロック剛性とは、タイヤ周方向におけるせん断変形を与えたときの値である。具体的には、単位面積当たりのブロック剛性は、以下の式によって算出される。
実際には、特許4615983号明細書に記載されているようなアムスラー試験機を用いた測定をFEMによって算出したものである。
1.10≦(R2/Rc)≦5.88
なお、1.10≦(R2/Rc)≦3.55を満たすことがより好ましく、1.20≦(R2/Rc)≦1.80を満たすことがさらに好ましい。
なお、1.10≦(Rs/R2)≦2.35を満たすことがより好ましく、1.20≦(Rs/R2)≦1.80を満たすことがさらに好ましい。
なお、0.21≦(Dball/Dsall)≦0.31を満足することがより好ましく、0.23≦(Dball/Dsall)≦0.29を満足することがさらに好ましい。
なお、1.15≦(P2/Pc)≦4.00を満足することがより好ましく、1.17≦(P2/Pc)≦2.50を満足することがさらに好ましい。
なお、0.94≦{(Ps/P2)/(P2/Pc)}≦3.00を満足することがより好ましく、0.96≦{(Ps/P2)/(P2/Pc)}≦2.80を満足することがさらに好ましい。
なお、1.05≦(h2/hc)≦4.00を満足することがより好ましく、1.09≦(h2/hc)≦2.00を満足することがさらに好ましい。
なお、1.05≦(hs/hc)≦3.00を満足することがより好ましく、1.10≦(hs/hc)≦1.79を満足することがさらに好ましい。
なお、0.97≦(hs/h2)≦1.71を満足することがより好ましく、1.05≦(hs/h2)≦1.27を満足することがさらに好ましい。
次に、上述した空気入りタイヤ10の作用・効果について説明する。具体的には、空気入りタイヤ10全体としての作用・効果、及びV形陸部列100、中央陸部列200、ショルダー陸部列300in, ショルダー陸部列300outの作用・効果について説明する。
V形陸部ブロック101は、タイヤ周方向の一方の側壁に凸部110を、他方の側壁に凹部120を有し、その両側の側壁の傾斜角度が同じであり、V形陸部ブロック101内部のサイプ130, 140または終端傾斜溝150を側壁と同じ傾斜角度である。このため、凸部110の頂点がある最凸部分110a(中央部)で屈曲部を有することで、屈曲部のない長方形状の陸部ブロックに比べて、中央部の剛性が高くなり、V形陸部ブロック101全体の剛性が高くなる。これにより、V形陸部ブロック101の倒れ込みや、路面からの浮き上がりが抑制され、接地面積が向上する。
V形陸部ブロック101の端から端まで傾斜溝で分断したいけれども、分断した場合には、陸部ブロックの周方向寸法が、幅方向寸法に対して小さくなるため、ブロック剛性が低下して、接地面積が減少する。
中央陸部列200に形成されている陸部ブロック210及び陸部ブロック260のようなタイヤ幅方向に対して傾斜する傾斜陸部ブロックの周方向の側壁が、タイヤ周方向の入力を受けると、図7(a)及び(b)に示したように、タイヤ周方向端の側壁に沿ったベクトル方向の力は、陸部ブロック210(及び陸部ブロック210P)を回転させようとしないが、タイヤ周方向端の側壁に垂直なベクトル方向に沿った陸部ブロック210への入力は、陸部ブロック210を回転させようとするモーメントを発生させる(図7(a)及び(b)では、左回転方向)。
ショルダー陸部列300in(ショルダー陸部列300outも同様、以下同)では、周方向サイプ320の振幅A1は、互いに隣接する幅方向サイプ340の振幅A2の寸法よりも大きい。
上述したように、平均サイプ間隔h/平均ピッチ長Lは、0.130≦(h/L)≦0.400であることが好ましく、h/Lが0.130未満だと、ピッチ長は相対的に大きくなるが、サイプ間隔は著しく小さくなってしまう。これにより、サイプ枚数が非常に多くなるので、陸部ブロックのブロック剛性が著しく低くなってしまう。
4.2mm≦h≦6.3mm
23.6mm≦L≦35.4mm
とすることがより好ましい。なお、タイヤ幅SECとは、195/65R15であれば、195(mm)のことである。
3.7mm≦h≦5.6mm
23.6mm≦L≦35.4mm
とすることが好ましい。
4.5mm≦h≦6.8mm
23.6mm≦L≦35.4mm
とすることが好ましい。
4.1mm≦h≦6.1mm
23.6mm≦L≦35.4mm
とすることが好ましい。
6.3mm<h≦7.9mm
35.4mm<L≦44.6mm
とすることがより好ましい。
5.6mm<h≦7.1mm
35.4mm<L≦44.6mm
とすることが好ましい。
6.8mm<h≦8.5mm
35.4mm<L≦44.6mm
とすることが好ましい。
6.1mm<h≦7.7mm
35.4mm<L≦44.6mm
とすることが好ましい。
3.4mm≦h<4.2mm
19.2mm≦L<23.6mm
とすることがより好ましい。
3.0mm≦h<3.7mm
19.2mm≦L<23.6mm
とすることが好ましい。
3.7mm≦h<4.5mm
19.2mm≦L<23.6mm
とすることが好ましい。
3.3mm≦h<4.1mm
19.2mm≦L<23.6mm
とすることが好ましい。
次に、平均サイプ間隔及び平均ピッチ長の関係を確認するために実施した評価試験の方法及び結果について、さらに説明する。
評価試験に用いた空気入りタイヤのサイズ及び試験条件は、以下のとおりである。
・使用リムサイズ: 6J×15
・設定空気圧: 240kPa(前輪・後輪)
・装着車両: アンチロックブレーキ(ABS)装着車両
なお、トレッドパターンは、図3に示した形状を用いた。「氷上ブレーキ性能」については、氷上路面テストコースにおいて、タイヤ新品時及び慣らし走行後のそれぞれの段階において、速度20km/hから急ブレーキを掛け(ABS作動)、停止するまでの距離(制動距離)を7回計測し、その最大値と最小値とを除外した5つのデータを平均した値である。さらに、従来例(比較例1)に係るタイヤを100として指数化したものである。数値が大きいほど、制動距離が短く、氷上ブレーキ性能が高いことを示す。
表1に示すように、実施例に係るタイヤ(No.2~No.8)では、「氷上ブレーキ性能」及び「耐摩耗性能」とも向上している。特に、No.4~No.6では、両性能ともバランス良く、大幅に向上している。
以上、実施例に沿って本発明の内容を説明したが、本発明はこれらの記載に限定されるものではなく、種々の変形及び改良が可能であることは、当業者には自明である。
Claims (7)
- タイヤ周方向に延びる周方向溝と、タイヤ幅方向に延びるラグ溝とが形成され、
前記周方向溝と前記ラグ溝とによって区画されたブロックを備えるタイヤであって、
前記ブロックには、タイヤ周方向に延びるジグザグ状の周方向サイプと、タイヤ幅方向に延びるジグザグ状の幅方向サイプとが形成され、
前記周方向サイプのタイヤ幅方向における振幅である幅方向振幅は、前記幅方向サイプのタイヤ周方向における振幅である周方向振幅よりも大きいタイヤ。 - 前記周方向サイプのジグザグ状の繰り返し周期は、互いにタイヤ周方向に隣接する前記幅方向サイプの間隔と等しいまたは小さい請求項1に記載のタイヤ。
- 前記ブロックにおいて、前記周方向サイプによってタイヤ幅方向におけるエッジ成分となる幅方向エッジ成分の合計L1と、前記周方向サイプによってタイヤ周方向におけるエッジ成分となる周方向エッジ成分の合計L2との比L1/L2は、16.0%以上、37.4%以下である請求項1または2に記載のタイヤ。
- 前記ブロックのタイヤ周方向における平均寸法L3に対する、前記合計L1及び前記合計L2の合計の比(L1+L2)/L3は、3.4以上、7.8以下である請求項3に記載のタイヤ。
- 前記ブロックには、タイヤ周方向に延びる周方向副サイプが形成され、
前記周方向副サイプの一端は、前記幅方向サイプに連通し、
前記周方向副サイプの他端は、前記ブロックのタイヤ周方向端側に位置する側壁に開口する請求項1乃至4の何れか一項に記載のタイヤ。 - 前記周方向サイプは、タイヤ周方向と平行に直線状に延びる直線状部を含み、
前記直線状部は、
前記ブロックのタイヤ周方向における端部に形成され、
前記周方向サイプのタイヤ幅方向における振幅の中心位置からオフセットした位置に形成される請求項1乃至5の何れか一項に記載のタイヤ。 - 前記ブロックは、タイヤ幅方向における路面との接地端を含むトレッド端部に設けられる請求項1乃至6の何れか一項に記載のタイヤ。
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JP7115248B2 (ja) * | 2018-11-26 | 2022-08-09 | 横浜ゴム株式会社 | 空気入りタイヤ |
US20220379666A1 (en) * | 2019-11-06 | 2022-12-01 | Compagnie Generale Des Etablissements Michelin | Tire comprising a tread |
JP7346277B2 (ja) * | 2019-12-19 | 2023-09-19 | 株式会社ブリヂストン | タイヤ |
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