pneumatic tires
The tire design addresses durability issues in low-profile tires with different-colored sidewalls by employing a specific carcass ply configuration and reinforcement layer to distribute strain, enhancing durability and visibility.
Patent Information
- Authority / Receiving Office
- JP · JP
- Patent Type
- Applications
- Current Assignee / Owner
- TOYO TIRE CORP
- Filing Date
- 2024-12-26
- Publication Date
- 2026-07-08
AI Technical Summary
Pneumatic tires with different-colored rubber sidewalls experience reduced durability due to increased interfaces between different-colored and black rubber, leading to strain concentration and separation, especially in low-profile tires.
A pneumatic tire design with a specific configuration including a first and second carcass ply, folded portions, and a different-colored rubber portion with controlled radial lengths and positions, along with a side reinforcement layer, to enhance rigidity and distribute strain, thereby suppressing separation.
The tire design improves durability by reducing separation occurrences and maintaining tire integrity, especially in low-profile tires, while allowing for a visible different-colored rubber display.
Smart Images

Figure 2026114279000001_ABST
Abstract
Description
Technical Field
[0001] The present invention relates to pneumatic tires.
Background Art
[0002] For the purpose of improving the visibility and design of tires, sidewalls are known that are composed of a different-color rubber composition such as white rubber for pattern portions such as characters, symbols provided on the sidewall, and lines or figures provided continuously or discontinuously in the tire circumferential direction. This type of sidewall is formed, for example, by arranging a different-color rubber while radially dividing a predetermined portion of the unvulcanized black rubber forming the sidewall, providing a black cover rubber layer on the different-color rubber, and then vulcanizing the formed green tire in a predetermined mold, and then grinding a part of the cover rubber layer to expose the different-color rubber as a pattern portion.
[0003] As a technique related to a sidewall in which a different-color rubber is arranged, for example, Patent Document 1 discloses that in order to suppress the phenomenon of black residue in which black rubber is partially exposed in a pattern portion, the volume of the different-color rubber is set to be 60% or more and 70% or less of the volume of the black rubber.
Prior Art Documents
Patent Documents
[0004]
Patent Document 1
Summary of the Invention
Problems to be Solved by the Invention
[0005] A tire having a sidewall in which a different-color rubber is arranged as in Patent Document 1 has an interface between the different-color rubber and the black rubber, so the number of interfaces increases compared to a tire with only a black sidewall, and the durability is likely to decrease. In particular, when the sectional height of the tire is small, strain concentrates near the outer end in the tire radial direction of the different-color rubber, and separation is likely to occur.
[0006] In view of the above, an embodiment of the present invention aims to provide a pneumatic tire that can exhibit excellent durability while having a different colored rubber on the sidewall. [Means for solving the problem]
[0007] The present invention includes embodiments shown below.
[0008] [1] A first carcass ply having a pair of bead portions comprising a pair of bead cores spaced apart in the tire axial direction and a bead filler provided on the radially outer side of the bead cores, a pair of sidewalls provided radially outward from the pair of bead portions, a belt with a plurality of cords covered in rubber, and a tread rubber provided radially outward from the belt, a tread provided between the pair of sidewalls, a first main body portion extending from the tread through the sidewalls to the bead core, a first folded portion extending from the first main body portion and folded back around the bead core from the inside to the outside in the tire axial direction, a second main body portion positioned radially outward from the first main body portion in the tread and extending from the tread through the sidewalls to the bead core, and a second main body portion extending from the second main body portion and folded back around the bead core from the inside to the outside in the tire axial direction A pneumatic tire having a tire cross-sectional height of 150 mm or less, formed by a tire vulcanization mold having a second carcass ply having a second folded portion folded toward the side, a different colored rubber portion provided on the tire axial side of the first carcass ply in the sidewall and made of rubber with a lower carbon black content than the rubber constituting the sidewall, forming at least a part of the tread, a sector, and a side plate that abuts the sector and forms at least a part of the sidewall, wherein the tire radial length C from the radial outer end of the different colored rubber portion to an annular projection formed at the boundary between the sector and the side plate and continuous in the tire circumferential direction is 8% or more and 28% or less of the tire cross-sectional height H, and the radial outer ends of the first folded portion and the second folded portion are positioned radially outward from the different colored rubber portion.
[0009] [2] The pneumatic tire according to [1], wherein the radially outer end of the first folded portion is positioned radially outward from the radially outer end of the second folded portion.
[0010] [3] The pneumatic tire according to [1] or [2] above, comprising: a rim strip rubber provided on the tire axial side of the bead portion and including a portion in contact with the wheel rim; and a side reinforcing layer including a reinforcing cord provided between the bead filler and the second folded portion, wherein the sidewall comprises an upper sidewall rubber provided on the tire radial side of the discolored rubber portion and a lower sidewall rubber provided between the discolored rubber portion and the rim strip rubber, and the side reinforcing layer provided from a position radially inward of the tire from the tire axial side of the inner end of the interface between the rim strip rubber and the lower sidewall rubber to a position radially outward of the tire axial side of the inner end of the interface between the lower sidewall rubber and the discolored rubber portion.
[0011] [4] The pneumatic tire according to any one of [1] to [3] above, wherein the outer end of the bead filler in the radial direction of the tire is positioned to overlap with the discolored rubber portion in the axial direction of the tire. [Effects of the Invention]
[0012] According to an embodiment of the present invention, in a pneumatic tire with different colored rubber arranged on the sidewall, the occurrence of separation can be suppressed and durability can be improved. [Brief explanation of the drawing]
[0013] [Figure 1] Half cross-sectional view of a pneumatic tire according to the first embodiment of the present invention [Figure 2] Figure 1 is an unfolded diagram showing the tread pattern of a pneumatic tire. [Modes for carrying out the invention]
[0014] The embodiments will be described below with reference to the drawings.
[0015] In the diagram, the symbol CL represents the tire equatorial plane and corresponds to the center of the tire in the axial direction. Here, the tire radial direction is the direction perpendicular to the tire rotation axis and is indicated by the symbol RD in the diagram. The inner side of the tire radial direction is the direction approaching the tire rotation axis, and the outer side of the tire radial direction is the direction away from the tire rotation axis. The tire axial direction is the direction parallel to the tire rotation axis and is indicated by the symbol WD in the diagram. The inner side of the tire axial direction is the direction approaching the center of the tire in the axial direction CL, and the outer side of the tire axial direction is the direction away from the center of the tire in the axial direction CL. The tire circumferential direction is the direction along the circumference centered on the tire rotation axis and is indicated by the arrow CD in the diagram.
[0016] In the diagram, the symbol E indicates the tire's contact point. The contact point E is the outermost position in the tire's axial direction (WD) on the contact surface. The contact surface refers to the surface of the tread portion that contacts the road surface when the tire is mounted on a standard rim, filled with standard internal pressure, placed perpendicular to a flat road surface, and subjected to a standard load.
[0017] A standard rim is a rim specified for each tire within the standardization system that the tire is based on. For example, it is a standard rim for JATMA and a "Measuring Rim" for TRA and ETRTO.
[0018] The standard load is the load specified for each tire in the standards system, including the standard on which the tire is based. For example, it is the maximum load capacity for JATMA, the maximum value listed in the table above for TRA, and "LOAD CAPACITY" for ETRTO.
[0019] Standard internal pressure refers to the "maximum air pressure" in the JATMA standard, the "maximum value" listed in "TIRELOAD LIMITS AT VARIOUS COLD INFLATION PRESSURES" in the TRA standard, or the "INFLATION PRESSURE" in the ETRTO standard.
[0020] In addition, in this specification, "overlap" shall include not only the case where tire components such as bead fillers, carcass plies, belt plies, and tread rubber directly contact and overlap each other, but also the case where they overlap with another member interposed therebetween.
[0021] (1) Basic structure of pneumatic tire 1 The pneumatic tire 1 according to one embodiment shown in FIGS. 1 and 2 includes a pair of left and right bead portions 20, a pair of left and right sidewalls 30 extending radially outward in the tire diameter direction from the bead portions 20, and a tread 40 connecting the radially outer ends of the sidewalls 30 in the tire diameter direction to form a ground contact surface. The pneumatic tire 1 of this embodiment is a low-profile pneumatic tire with a tire cross-sectional height H of 85 mm or more and 150 mm or less. Note that the tire cross-sectional height H is the length in the tire diameter direction from the inner diameter surface to the outer diameter surface of the unloaded pneumatic tire 1 mounted on a regular rim and filled with a regular internal pressure.
[0022] A ring-shaped bead core 21 is embedded in each of the pair of bead portions 20. A bead filler 22 made of hard rubber and tapered outward in the tire diameter direction is provided on the outer side in the tire diameter direction of the bead core 21. A rim strip rubber 3 is provided on the outer side in the tire axial direction WD of the bead filler 22 in the bead portion 20. The rim strip rubber 3 is a rubber member forming the outer surface of the bead portion 20 and contacts a wheel rim (not shown) on which the pneumatic tire 1 is mounted.
[0023] The pneumatic tire 1 includes a carcass 50 provided in a toroidal shape across the pair of bead portions 20. The carcass 50 is locked by being folded back from the inner side to the outer side in the tire axial direction around the bead core 21 in the bead portion 20 through the sidewall 30 from the tread 40. An inner liner 2 is provided as an air permeation resistant rubber layer on the inner surface side of the carcass 50.
[0024] A side reinforcement layer 80 is provided on the outer side of the tire axial direction WD of the bead filler 22 in the bead portion 20, and a rim strip rubber 3 is provided on the outer side of the tire (i.e., the outer side of the tire axial direction WD) of the carcass 50 in the bead portion 20. A sidewall rubber 31 and a different colored rubber portion 32 are provided on the outer side of the tire of the carcass 50 in the sidewall 30. A belt 70 is provided on the outer side of the tire radial direction RD of the carcass 50 in the tread 40, and a belt reinforcement layer 73 and tread rubber 41 are laminated on the outer side of the tire radial direction RD of the belt 70.
[0025] As shown in Figure 1, an annular projection 47 extending in the tire circumferential direction CD is provided near the boundary between the sidewall 30 and the tread 40. The annular projection 47 is provided continuously around the entire circumference of the tire circumferential direction CD. The annular projection 47 is provided at the boundary position (parting line) PL between the sector, which is the mold for forming the tread 40, and the side plate, which is the mold for forming the sidewall 30.
[0026] (2) Belt 70 The belt 70 consists of at least two intersecting belt plies, in which the belt cords are arranged at an inclination angle of 10 to 35 degrees, preferably 22 to 28 degrees, with respect to the tire circumferential direction CD. In this example, it has a two-layer structure with a first belt ply 71 located on the inside of the tire radial direction RD and a second belt ply 72 located on its outer circumference. Of these, the first belt ply 71 is the widest belt, and its outer end in the tire axial direction WD corresponds to the outer end 70A in the tire axial direction of the belt 70. Steel cords or high-tensile organic fiber cords can be used as the belt cords.
[0027] In this example, a belt reinforcing layer 73 is provided on the outer side of the belt 70 in the tire radial direction RD, i.e., between the belt 70 and the tread rubber 41. The belt reinforcing layer 73 is composed of cap plies having cords that extend substantially parallel to the tire circumferential direction CD.
[0028] Furthermore, a rubber layer 74 is provided between the tire axial WD end of the first belt ply 71 and the carcass 50, which does not contain cord reinforcing materials such as organic fibers or steel cords.
[0029] (3) Carcass 50 The carcass 50 comprises two carcass plies, namely a first carcass ply 51 and a second carcass ply 52, which are laminated so that the constituent cords extend inclined with respect to the tire circumferential direction CD and the constituent cords are facing in opposite directions. The carcass plies 51 and 52 are in the form of sheets made of multiple parallel cords covered with rubber. The multiple cords of the carcass plies 51 and 52 may be, for example, organic fiber cords such as polyester fibers, rayon fibers, aramid fibers, nylon fibers, or steel cords.
[0030] The first carcass ply 51 consists of a first main body portion 51A that extends from the tread 40 through the sidewall 30 to the bead core 21 of the bead portion 20, and a first folded portion 51B that extends from the first main body portion 51A and is folded back around the bead core 21 from the inside to the outside in the tire axial direction WD.
[0031] The first main body portion 51A passes through the inner side of the tire axial direction WD of the bead filler 22 and reaches the inner side of the tire radial direction RD of the bead core 21. The first folded portion 51B is wound up from the inner side of the tire radial direction RD of the bead core 21, passing through the outer side of the tire axial direction WD of the bead filler 22, and out to the outer side of the tire radial direction RD.
[0032] The second carcass ply 52 consists of a second main body portion 52A that extends from the tread 40 through the sidewall 30 to the bead core 21 of the bead portion 20, and a second folded portion 52B that extends from the second main body portion 52A and is folded back around the bead core 21 from the inside to the outside in the tire axial direction WD.
[0033] The second main body portion 52A is positioned on the tread 40 on the radial side of the first main body portion 51A, extends along the outer surface of the first main body portion 51A toward the bead portion 20, passes between the first main body portion 51A and the bead filler 22, and reaches the inner side of the bead core 21 in the radial direction RD. The second folded portion 52B is wound up from the inner side of the bead core 21 in the radial direction RD, passes between the bead filler 22 and the first folded portion 51B, and is wound outwards in the radial direction RD.
[0034] The first carcass ply 51 has a first folded portion 51B that extends inward in the tire axial direction WD from the outer end 70E of the belt 70. That is, the first folded end 51BE, which is the outer end of the first folded portion 51B in the tire radial direction RD, is located inward in the tire axial direction WD from the outer end 70E of the belt 70 and is positioned to overlap with the belt 70 in the direction normal to the first folded portion 51B. In this example, the first folded end 51BE is located inward in the tire axial direction WD from the outer end 72E of the second belt ply 72 and is positioned to overlap with the tire axial direction WD end of the second belt ply 72 in the direction normal to the first folded portion 51B.
[0035] In this example, a rubber layer 74 is provided between the first belt ply 71 of the belt 70 and the outer end RD in the tire radial direction of the first folded portion 51B, so that the first folded end 51BE of the first folded portion 51B does not directly contact the first belt ply 71 of the belt 70, but overlaps with it via the rubber layer 74.
[0036] The second carcass ply 52 has a second folded portion 52B that extends radially RD outward from the tip (i.e., outer end in the tire radial direction) 22A of the bead filler 22, and terminates before the outer end 70A of the belt 70. More specifically, the second folded end 52BE, which is the outer end in the tire radial RD of the second folded portion 52B, is positioned so as not to overlap with the belt 70 in the direction normal to the second folded portion 52B, but to overlap with the tread rubber 41. The second folded end 52BE of the second folded portion 52B is sandwiched between the second main body portion 52A of the second carcass ply 52 and the first folded portion 51B of the first carcass ply 51.
[0037] (4) Tread 40 The tread 40 is provided with tread rubber 41 on the outer circumference side (outer side in the tire radial direction) of the belt reinforcement layer 73. The tread rubber 41 has a two-layer structure consisting of a cap rubber layer 42 having a tread surface that contacts the road surface, and a base rubber layer 43 arranged on the inner side of the cap rubber layer 42 in the tire radial direction RD. The tread rubber 41 covers the outer end of the sidewall rubber 31 provided on the sidewall 30 in the tire radial direction RD. Alternatively, the tread rubber 41 and sidewall rubber 31 may be arranged such that the outer end of the sidewall rubber 31 in the tire radial direction RD covers the axial end WD of the tread rubber 41 from the outside.
[0038] The cap rubber layer 42 has multiple main grooves 44A and 44B formed in it, extending along the tire circumferential direction CD and spaced apart in the tire axial direction WD. In this example, there is a pair of center main grooves 44A located on both sides of the tire axial center CL, and a pair of shoulder main grooves 44B located outside of them.
[0039] The cap rubber layer 42 is divided into multiple land sections 45A, 45B, and 45C in the tire axial direction WD by multiple main grooves 44A and 44B. Specifically, it is provided with a center land section 45A sandwiched between a pair of center main grooves 44A, 44A, a pair of left and right intermediate land sections 45B sandwiched between the center main groove 44A and the shoulder main groove 44B, and a pair of left and right shoulder land sections 45C formed between the shoulder main groove 44B and the contact end E. Each land section 45A, 45B, and 45C is provided with a lateral groove 46 extending in a direction intersecting the tire circumferential direction CD.
[0040] The base rubber layer 43 consists of a rubber layer with a substantially constant thickness, provided on the radially outer side of the belt reinforcement layer 73. The base rubber layer 43 may be made of a rubber composition having the same rubber hardness as the rubber composition that constitutes the cap rubber layer 42. Alternatively, the base rubber layer 43 may be made of a rubber composition with lower rubber hardness than the rubber composition that constitutes the cap rubber layer 42.
[0041] It is preferable to use a rubber composition with a rubber hardness in the range of 52 to 68 for the cap rubber layer 42 and base rubber layer 43 that constitute the tread rubber 41.
[0042] In this specification, rubber hardness is defined as JIS K6253-1-2012 3.2 durometer hardness, and is measured using a Type A durometer for general rubber (medium hardness) in an atmosphere of 23°C.
[0043] In the pneumatic tire 1 of this embodiment, when the tire is mounted on a regular rim and the internal pressure is not filled (regular rim mounting, internal pressure not filled), the tire thickness THc at the center of the tire axial WD cross section is smaller than the tire thickness THe at the contact end E.
[0044] Here, the tire thickness THc at the axial center CL of the tire is the tire thickness at the normal to the tire surface profile at the axial center CL, and the tire thickness THe at the contact end E is the tire thickness at the normal to the tire surface profile at the contact end E. The tire surface profile is the contour line of the outer surface of the tread 40 excluding the main grooves 44A and 44B, and is usually defined by a curve formed by smoothly connecting multiple arcs.
[0045] In other words, as shown in Figures 1 and 2, the tire thickness THc at the center CL in the tire axial direction is the length in the normal direction of the outer surface of the tread 40 from the outer surface of the cap rubber layer 42 that constitutes the outer surface of the tire to the inner surface of the inner liner 2 that constitutes the inner surface of the tire, when no grooves such as the main groove 44A or lateral groove 46 are provided at the center CL in the tire axial direction, and when a groove is provided at the center CL in the tire axial direction, it is the length in the normal direction of the outer surface of the tread 40 from the opening surface of the groove to the inner surface of the inner liner 2.
[0046] Furthermore, the tire thickness The at the contact end E is the length in the normal direction of the outer surface of the tread 40 from the outer surface of the cap rubber layer 42 to the inner surface of the inner liner 2 if there are no grooves such as lateral grooves 46 at the contact end E, and the length in the normal direction of the outer surface of the tread 40 from the opening of the groove to the inner surface of the inner liner 2 if there are grooves at the contact end E.
[0047] (5) Sidewall 30 The sidewall 30 is provided with sidewall rubber 31 and a different colored rubber portion 32. The sidewall rubber 31 is joined to the axial WD end of the tread rubber 41 at the outer end of the tire radial RD, and to the outer end of the radial RD of the rim strip rubber 3 at the inner end of the tire radial RD. The sidewall rubber 31, like the tread rubber 41 and rim strip rubber 3, is made of a black rubber composition (black rubber) that contains carbon black as a reinforcing filler.
[0048] In this embodiment, the discolored rubber portion 32 is made of white rubber, but it may be made of rubber colored in any color as long as it has a lower carbon black content than the sidewall rubber 31. The white rubber composition constituting the discolored rubber portion 32 can be any known white rubber composition commonly used for this application, and is not particularly limited.
[0049] For example, the discolored rubber portion 32 does not contain carbon black as a reinforcing filler, but is made of a rubber composition containing fillers other than carbon black, such as silica, talc, or clay (i.e., non-carbon black fillers).
[0050] The sidewall rubber 31 is made of a rubber composition that is softer (lower hardness) and less rigid than the rim strip rubber 3. The discolored rubber portion 32 can be made of a rubber composition that is harder and less rigid than the black rubber composition containing carbon black that makes up the rim strip rubber 3 and the sidewall rubber 31. For example, the rubber hardness of the rim strip rubber 3 can be set to 60-85, the rubber hardness of the sidewall rubber 31 to 50-70, and the rubber hardness of the discolored rubber portion 12 to 40-70.
[0051] The discolored rubber portion 32 is arranged in an annular shape along the circumferential direction in a portion of the radial direction of the sidewall 30. A portion of the outer surface of the discolored rubber portion 32 is covered by a cover rubber layer (not shown) made of black rubber of the same color as the sidewall rubber 31, and the exposed portion of the discolored rubber portion 32 that is not covered becomes the discolored indicator portion 33.
[0052] The contrasting color display section 33 displays predetermined patterns, characters, symbols, designs, or lines and figures that are continuously or discontinuously arranged in the circumferential direction of the tire, using a color different from that of the sidewall rubber on the outer surface of the tire. This contrasting color display section 33 may be provided protruding from the outer surface of the tire. Furthermore, the contrasting color display section 33 may be provided in an annular shape continuously along the circumferential direction CD of the tire, or it may be provided discontinuously along the circumferential direction depending on the shape of the display.
[0053] As shown in Figure 1, the different-colored rubber portion 32 is provided at a position where the length C of the radial RD of the tire, from the outer end 32E1 in the tire radial direction to the annular projection 47 provided near the boundary between the sidewall 30 and the tread 40, is 8% to 28% of the tire cross-sectional height H. Preferably, the length C is 17% to 26% of the tire cross-sectional height H.
[0054] By setting the ratio of the length C from the outer radial end 32E1 of the different-colored rubber portion 32 to the annular projection 47 to the tire section height H to 8% or more, the interface between the different-colored rubber portion 32 and the sidewall rubber 31 on the outer radial RD of the tire can be positioned away from the boundary between the tread 40 and the sidewall 30 where distortion is likely to occur, thereby suppressing the occurrence of separation. Furthermore, by setting the ratio of length C to tire section height H to 17% or more, durability can be further improved.
[0055] Furthermore, by setting this ratio to 28% or less, the different-colored rubber portion 32 can be positioned in a conspicuous location on the sidewall 30, allowing the different-colored rubber to be exposed without exposing the black sidewall rubber in areas displaying patterns, letters, etc., thus preventing deterioration of appearance quality. In addition, the interface 4 between the different-colored rubber portion 32 and the sidewall rubber 31 on the inner side of the tire radial direction RD can be positioned away from the rim strip rubber 3 that contacts the wheel rim when mounted on the vehicle, thereby suppressing the occurrence of separation. By setting this ratio to 26% or less, the different-colored rubber can be exposed without exposing the sidewall rubber over a wide area in the tire radial direction, and the occurrence of separation can be further suppressed.
[0056] Furthermore, in this embodiment, the different-colored rubber portion 32 is provided such that the length D in the tire radial direction from the inner end 6a in the tire axial direction of the interface 6 between the different-colored rubber portion 32 and the upper sidewall rubber 32A to the first folded end 51BE of the first folded portion 51B of the first carcass ply 51 is 3.0% or more and 30% or less of the tire cross-sectional height H.
[0057] The different-colored rubber portion 32 may be provided at a position that includes the tire's maximum width position P1, or the different-colored rubber portion 32 may be provided such that the different-colored indicator portion 33 is located at the tire's maximum width position P1. Here, the tire's maximum width position P1 is the position where the length of the tire axial direction WD of the pneumatic tire 1 is at its maximum when it is mounted on a regular rim, subjected to regular internal pressure, and loaded with a regular load.
[0058] As shown in Figure 1, the discolored rubber portion 32 is provided in the region of the sidewall 30 on the inner side of the tire radial direction RD, extending from the outer surface of the tire in the tire axial direction WD to the first folded portion 51B of the first carcass ply 51. By providing the discolored rubber portion 32 in this way, the discolored rubber portion 32 radially divides the black sidewall rubber 31 near the center of the tire radial direction RD, forming an upper sidewall rubber 31A located on the outer side of the discolored rubber portion 32 in the tire radial direction RD and a lower sidewall rubber 31B located on the inner side of the discolored rubber portion 32 in the tire radial direction RD.
[0059] In this embodiment, the sidewall rubber 31 is divided in the tire radial direction RD by the different colored rubber portion 32, but the sidewall rubber 31 may be provided between the different colored rubber portion 32 and the first folded portion 51B of the first carcass ply 51, and the upper sidewall rubber 31A and the lower sidewall rubber 31B may be connected.
[0060] Furthermore, the outer end 32E1 of the different-colored rubber portion 32 in the tire radial direction may be located radially outward from the outer end (tip) 22E of the bead filler 22 in the tire radial direction, and the inner end 32E2 of the different-colored rubber portion 32 in the tire radial direction may be located radially inward from the tip 22E of the bead filler 22. In other words, the tip 22E of the bead filler 22 may be positioned to overlap with the different-colored rubber portion 32 in the tire axial direction WD via the first folded portion 51B and the second folded portion 52B of the carcass 50. In this embodiment, the tip 22E of the bead filler 22 extends radially outward to a position where it overlaps with the different-colored indicator portion 33 in the tire axial direction WD.
[0061] By positioning the tip 22E of the bead filler 22 so as to overlap with the discolored rubber portion 32 in the tire axial direction WD, the rigidity of the sidewall 30 can be increased and distortion of the entire sidewall can be suppressed. In addition, since the discolored rubber portion 32 does not overlap with the bead filler 22 in the tire axial direction WD across the entire tire radial direction, ride comfort is less likely to deteriorate.
[0062] In this embodiment, both ends of the different-colored rubber portion 32 in the tire radial direction are inclined to narrow as they move inward in the tire axial direction, and the radial length of the different-colored rubber portion 32 on the outer surface of the tire is set to be longer than the radial length on the inner surface of the tire.
[0063] Furthermore, the cross-sectional shape of the different-colored rubber portion 32 can be provided in various shapes. For example, both ends of the different-colored rubber portion 32 in the tire radial direction may be inclined to widen as they move inward in the tire axial direction, both ends of the different-colored rubber portion 32 in the tire radial direction may be provided substantially parallel to the tire axial direction, or one end of the different-colored rubber portion 32 in the tire radial direction may be inclined with respect to the tire axial direction, and the other end in the tire radial direction may be provided substantially parallel to the tire axial direction.
[0064] Furthermore, in this embodiment, the interface 5 between the lower sidewall rubber 31B and the rim strip rubber 3 is inclined so that it moves inward in the tire radial direction RD as it moves outward in the tire axial direction WD, and is inclined substantially parallel to the same direction as the interface 4 between the different colored rubber portion 32 and the lower sidewall rubber 31B.
[0065] In this embodiment, the inner end 32E2 of the differently colored rubber portion 32 in the tire radial direction is located further inward RD in the tire radial direction than the outer end of the rim strip rubber 3 in the tire radial direction, and overlaps with the outer end of the rim strip rubber 3 in the tire radial direction via the lower sidewall rubber 31B in the tire axial direction.
[0066] (6) Side reinforcement layer 80 The side reinforcement layer 80 is a rubber layer formed by arranging multiple reinforcing cords, each made of steel cords or organic fiber cords, in parallel at predetermined intervals and covering them with rubber. The side reinforcement layer 80 is provided between the bead filler 22 and the second folded portion 52B. The inner end 80E2 of the side reinforcement layer 80 in the tire radial direction is positioned to overlap with the bead core 21 in the tire axial direction WD, extends outward in the tire radial direction RD along the outer side of the bead filler 22 in the tire axial direction WD, and terminates at least further outward in the tire radial direction RD than the lower sidewall rubber 31B.
[0067] In other words, the side reinforcement layer 80 has its inner end 80E2 in the tire radial direction located further inward RD than the inner end 5E in the tire axial direction of the interface 5 between the rim strip rubber 3 and the lower sidewall rubber 31B, and its outer end 80E1 in the tire radial direction is located further outward RD than the inner end 4E in the tire axial direction of the interface 4 between the lower sidewall rubber 31B and the different colored rubber portion 32.
[0068] Furthermore, the outer end 80E1 of the side reinforcement layer 80 in the tire radial direction may be positioned to overlap with the different colored rubber portion 32 in the tire axial direction WD, or to overlap with the different colored display portion 33 of the different colored rubber portion 32 in the tire axial direction WD, or to overlap with the upper sidewall rubber 31A in the tire axial direction WD. In addition, the outer end 80E1 of the side reinforcement layer 80 in the tire radial direction RD may be positioned inside the tire radial direction RD of the tire maximum width position P1, or outside the tire radial direction RD of the tire maximum width position P1.
[0069] (7) Effects In the case of a low-profile pneumatic tire with a tire cross-sectional height H of 150 mm or less, if the different-colored display portion 33 is placed in a conspicuous position on the sidewall 30, the different-colored display portion 33 becomes susceptible to the effects of distortion that occurs near the boundary between the sidewall 30 and the tread 40. In the pneumatic tire 1 of this embodiment, the length C in the tire radial direction from the outer end 32E1 in the tire radial direction to the annular projection 47 of the different-colored rubber portion 32 is set to 8% or more and 28% or less of the tire cross-sectional height H, thereby ensuring distance from the boundary between the sidewall 30 and the tread 40. At the same time, the first folded portion 51B of the first carcass ply 51 and the second folded portion 52B of the second carcass ply 52 are placed radially outward from the different-colored rubber portion 32, thereby increasing the rigidity near the interface 6 between the upper sidewall rubber 31A and the different-colored rubber portion 32, and thus suppressing the occurrence of separation at the interface 6.
[0070] Furthermore, in this embodiment, the first folded end 51BE is positioned radially outward from the second folded end 52BE, and since both ends are spaced apart, air ingress between the first folded portion 51B and the second folded portion 52B can be suppressed, thereby improving durability.
[0071] Furthermore, in the pneumatic tire 1 of this embodiment, the tire thickness from the inner surface to the outer surface in the axial cross-section of the tire in the state of unfilled rim assembly is smaller at the axial center of the tire than at the contact edge, so the tread 40 is more prone to bending deformation. As a result, the bending of the entire tire is more easily distributed to the tread 40, which suppresses bending deformation that occurs in the sidewall 30, suppresses the occurrence of separation at the interface between the different colored rubber portion 32 and the sidewall rubber 31, and improves durability. In particular, in the case of low-profile pneumatic tires with a tire cross-sectional height H of 150 mm or less, if the different-colored display section 33 is placed in a conspicuous position on the sidewall 30, the different-colored rubber section 32 will be placed near the tire's maximum width position P1, which is prone to deformation when a load is applied. However, in this embodiment, since the tread 40 is configured to be easily flexed and deformed, deformation near the tire's maximum width position P1 is reduced, effectively suppressing the occurrence of separation at the interface between the different-colored rubber section 32 and the sidewall rubber 31, thereby improving durability.
[0072] In this embodiment, by setting the angle of the belt cord provided on the belt 70 with respect to the tire circumferential direction CD to 22 degrees or more and 28 degrees or less, the tread 40 can be restrained in the tire radial direction while allowing a moderate deformation. This suppresses bending deformation in the sidewall 30 without impairing the tire's running performance, thereby suppressing the occurrence of separation at the interface of the different colored rubber portion 32 and improving durability.
[0073] Furthermore, by adjusting the belt angle of the belt cord with respect to the tire circumferential CD within the above range, the tire's contact pressure becomes uniform, and the strain is distributed throughout the tire, thereby suppressing deflection deformation in the sidewall 30 and bead portion 20.
[0074] In this embodiment, by positioning the tip 22E of the bead filler 22 to overlap with the discolored rubber portion 32 when viewed from the tire axial direction, the interface between the discolored rubber portion 32 and the sidewall rubber 31 can be reinforced, thereby suppressing the occurrence of separation at the interface of the discolored rubber portion 32 and improving durability.
[0075] Furthermore, in the pneumatic tire 1 of this embodiment, the first folded portion 51B of the first carcass ply 51 extends inward in the tire axial direction beyond the outer end 70E of the belt 70, and the first folded end 51BE is positioned to overlap with the belt 70 in the direction normal to the folded portion 51B. This increases rigidity near the boundary between the tread 40 and the sidewall 30, suppressing distortion and preventing separation at the interface 6 between the different colored rubber portion 32 and the upper sidewall rubber 31A, thereby improving durability.
[0076] As in this embodiment, by positioning the first folded end 51BE further inward in the tire axial direction WD than the tire axial outer end 72E of the second belt ply 72, and positioning the first folded end 51BE so as to overlap with the second belt ply 72 in the direction normal to the first folded portion 51B, the reinforcing effect near the boundary between the tread 40 and the sidewall 30 is enhanced, and the occurrence of separation at the interface 6 can be further suppressed.
[0077] Furthermore, the second folded portion 52B of the second carcass ply 52 extends radially outward RD beyond the interface 6 between the different-colored rubber portion 32 and the upper sidewall rubber 31A, and the second folded end 52BE is positioned to overlap with the tread rubber 41 via the upper sidewall rubber 31A. This increases the rigidity near the interface 6 between the different-colored rubber portion 32 and the upper sidewall rubber 31A, suppresses the occurrence of separation at the interface 6, and improves durability.
[0078] The second folded end 52BE does not overlap with the belt 70 in the direction normal to the second folded portion 52B, and a distance is maintained between them. As a result, the ends of the belt plies 71, 72 and carcass plies 51, 52, which are prone to strain concentration, are not positioned to overlap near the boundary between the tread rubber 41 and the sidewall rubber 31, thereby improving tire durability, and also making it less likely for air to remain between components during tire manufacturing.
[0079] In this embodiment, the length D in the radial direction of the tire from the inner end 6a of the interface 6 in the tire axial direction to the first folded end 51BE of the first folded portion 51B is set to 3.0% or more and 30% or less of the tire cross-sectional height H. When the length D is 3.0% or more of the tire cross-sectional height H, it is possible to increase the rigidity near the discolored rubber portion 32 while ensuring the distance between the interface 6 and the first folded portion 51B, thereby improving tire durability. Furthermore, when the length D is 30% or less of the tire cross-sectional height H, the weight does not increase excessively, and rolling resistance does not worsen, thus preventing a decrease in fuel efficiency.
[0080] As in this embodiment, by providing a side reinforcing layer 80 between the bead filler 22 and the second folded portion 52B, the overall rigidity of the sidewall 30 can be increased, the applied load can be reduced, and the strain on the interfaces 4 and 6 between the different colored rubber portion 32 and the sidewall rubber 31 can be suppressed.
[0081] (8) Example of change Next, examples of modifications will be described. Various modifications can be made to the above embodiments without departing from the spirit of the invention. In addition to the following examples of modifications, various omissions, substitutions, and changes can be made without departing from the gist of the invention.
[0082] In the above-described embodiment, the first folded end 51BE of the first carcass ply 51 is positioned to overlap with the belt 70 in the direction normal to the first folded portion 51B, and the second folded end 52BE of the second carcass ply 52 is positioned not to overlap with the belt 70 in the direction normal to the second folded portion 52B, but to overlap with the tread rubber 41. However, the first folded portion 51B and the second folded portion 52B can be positioned further outward in the tire radial direction than the different colored rubber portion 32, and the arrangement of the first folded end 51BE and the second folded end 52BE is not limited to the above embodiment.
[0083] (9) Examples The following are examples, but the present invention is not limited to these examples.
[0084] To demonstrate the effects of the above embodiments, pneumatic tires of Examples 1-3 and Comparative Examples 1 and 2 were prototyped.
[0085] The pneumatic tires of Examples 1-3 and Comparative Examples 1 and 2 are radial tires of size 165 / 60R15 with the cross-sectional shape shown in Figure 1 and the tread pattern shown in Figure 2, and the length C in the radial direction of the tire differs from the outer radial end 32E1 of the different colored rubber portion 32 to the annular projection 47. The length C, tire cross-sectional height H, and the ratio of length C to tire cross-sectional height H in the pneumatic tires of Examples 1-3 and Comparative Examples 1 and 2 are shown in Table 1.
[0086] In all examples, the cross-sectional height was 99 mm, and the configuration was the same except for length C.
[0087] The durability performance of each of these tires was evaluated. The evaluation methods are as follows:
[0088] • Durability Performance: Durability performance tests were conducted in accordance with the method specified in JIS D4230. If no failures such as separation were observed after completing test stage 3, the tire was subjected to continued load, and the distance traveled until failure was observed was measured and expressed as an index with the value of Example 1 set to 100. A higher index indicates better durability performance.
[0089] • Appearance Quality: The obtained pneumatic tires were visually inspected to see if black rubber had entered the discolored areas. If no black rubber had entered, it was marked with "○", and if black rubber had entered, it was marked with "×".
[0090] [Table 1] The results are shown in Table 1. In Examples 1 to 3, separation was less likely to occur at the interface between the different-colored rubber portion 32 and the upper sidewall rubber 31A, demonstrating excellent durability. Furthermore, in Examples 1 to 3, the black rubber did not penetrate the different-colored display portion, resulting in excellent appearance quality.
[0091] On the other hand, Comparative Example 1 showed inferior durability compared to Examples 1-3. Furthermore, in Comparative Example 2, black rubber had seeped into the areas with different colored markings. [Explanation of Symbols]
[0092] 1...Pneumatic tire, 2...Inner liner, 3...Rim strip rubber, 20...Bead section, 21...Bead core, 22...Bead filler, 30...Sidewall, 31...Sidewall rubber, 32...Different color rubber section, 33...Different color indicator section, 40...Tread, 41...Tread rubber, 42...Cap rubber layer, 43...Base rubber layer, 44A...Center main groove, 44B...Shoulder main groove, 45A...Center land section, 45B...Intermediate land section, 45C...Shoulder land section, 46...Lateral groove, 47...Annular projection, 50...Carcass, 51...First carcass ply, 51A...First main body section, 51B...First folded section, 52...Second carcass ply, 52A...Second main body section, 52B...Second folded section, 70...Belt, 71...First belt ply, 72...Second belt ply
Claims
1. A pair of bead portions comprising a pair of bead cores arranged at intervals in the tire axial direction, and a bead filler provided on the radially outer side of the bead cores in the tire direction, A pair of sidewalls provided radially outward from the pair of bead portions of the tire, A belt having multiple cords covered with rubber, a tread rubber provided on the radially outer side of the belt, and a tread provided between a pair of sidewalls, A first carcass ply having a first main body portion extending from the tread through the sidewall to the bead core, and a first folded portion extending from the first main body portion and folded back around the bead core from the inner side in the tire axial direction to the outer side, A second carcass ply having, in the tread, a second main body portion arranged radially outward of the first main body portion and extending from the tread through the sidewall to the bead core, and a second folded portion extending from the second main body portion and folded back around the bead core from the inner side in the tire axial direction to the outer side, A different colored rubber portion is provided on the tire axial side of the first carcass ply in the sidewall, and is made of rubber with a lower carbon black content than the rubber constituting the sidewall. Equipped with, In a pneumatic tire having a tire cross-sectional height of 150 mm or less, formed by a tire vulcanization mold having a sector that forms at least a portion of the tread and a side plate that abuts against the sector and forms at least a portion of the sidewall, The length C in the tire's radial direction from the outer end of the discolored rubber portion in the tire's radial direction to the annular projection formed at the boundary between the sector and the side plate, which is continuous in the tire's circumferential direction, is 8% or more and 28% or less of the tire's cross-sectional height H. A pneumatic tire in which the radially outer ends of the first and second folded portions are positioned radially outward from the different colored rubber portion.
2. The pneumatic tire according to claim 1, wherein the radially outer end of the first folded portion is positioned radially outward of the second folded portion than the radially outer end of the second folded portion.
3. The bead portion includes a rim strip rubber provided on the outer side of the tire axial direction and including a portion that contacts the wheel rim, and a side reinforcing layer including a reinforcing cord provided between the bead filler and the second folded portion, The sidewall comprises an upper sidewall rubber provided on the outer side of the different-colored rubber portion in the tire radial direction, and a lower sidewall rubber provided between the different-colored rubber portion and the rim strip rubber. The pneumatic tire according to claim 1, wherein the side reinforcement layer is provided at a position from a position radially inside the inner end of the interface between the rim strip rubber and the lower sidewall rubber in the tire axial direction to a position radially outside the inner end of the interface between the lower sidewall rubber and the discolored rubber portion in the tire axial direction.
4. The pneumatic tire according to claim 1, wherein the outer end of the bead filler in the radial direction of the tire is arranged to overlap with the discolored rubber portion in the axial direction of the tire.