JP7222856B2 - Tire and tire manufacturing method - Google Patents

Description

TECHNICAL FIELD The present invention relates to a tire in which electronic components are embedded.

Conventionally, a tire is known in which an electronic component such as an RFID is embedded in a rubber structure. In such tires, the RFID tag embedded in the tire communicates with a reader serving as an external device, whereby tire manufacturing management, usage history management, and the like can be performed.
For example, Patent Literature 1 discloses a tire in which electronic components are arranged on the interface between two different objects. The interface between the two bodies on which the electronic component is located is the plane extending from the free edge of the carcass ply.

JP 2008-265750 A

In the technique disclosed in Patent Document 1, the boundary surface between the two objects on which the electronic components are arranged is a surface extending from the free edge of the carcass ply. , stress and strain are likely to occur. Therefore, the electronic components arranged in this portion may be affected by stress and strain when the tire is deformed, and may not be able to maintain their functions as electronic components.

The present invention has been made in view of the above problems, and its object is to maintain the function of the embedded electronic components by arranging the electronic components at positions that are less susceptible to stress and strain within the tire structure. It is to provide a tire that can

(1) The tire (e.g., tire 1) of the present invention includes a bead core (e.g., bead core 21), a bead filler (e.g., bead filler 22) extending outward in the tire radial direction of the bead core, and the other from the bead core. a carcass ply (e.g., carcass ply 23) extending to and folded around the bead core, wherein a reinforcing ply (e.g., , steel chafer 31), and the tire width direction outside of the folded end (eg, folded end 25A) of the folded carcass ply at the tire radial direction outside of the end portion (eg, end portion 31A) of the reinforcing ply A covering first pad (for example, a first pad 35) and a second pad (for example, a second pad 36) covering the outer side of the first pad in the tire width direction, and the first pad An electronic component (eg, RFID tag 40) is provided between the pad and the second pad.

(2) In the tire of (1), the electronic component may be provided at a position separated by 5 mm or more from the folded end of the carcass ply.

(3) In the tire of (1) to (2), the electronic components are covered with a rubber sheet (for example, rubber sheets 431 and 432), and the rubber sheet covering the electronic components is covered with the first It may be arranged at the tire radial outer end of the pad (for example, the tire radial outer end 35A).

(4) In the tires of (1) to (3), the modulus of the first pad and the second pad may be higher than the modulus of the bead filler.

(5) In the manufacturing method for manufacturing a tire of (1), the electronic component is covered with the rubber sheet, and before the vulcanization step of vulcanizing the green tire, the tire diameter of the first pad The longitudinal direction of the rubber sheet covering the electronic component is aligned with the direction of the ridgeline of the outer end of the first pad in the tire radial direction, with the ridgeline of the outer end in the direction of the tire as a reference. It may be provided with an affixing step of affixing to the pad.

(6) The manufacturing method for manufacturing a tire of (5) further comprises a covering step of covering the electronic component attached in the attaching step with the rubber sheet, wherein the covering step comprises a spring of the electronic component. arranging rubber (for example, rubber 46) in an antenna (for example, spring antenna 421); and sandwiching the electronic component having the spring antenna in which the rubber is arranged between the rubber sheets. may be

ADVANTAGE OF THE INVENTION According to this invention, the tire which can maintain the function of the embedded electronic component can be provided by arrange|positioning an electronic component in the position which is hard to be affected by the stress and strain in a tire structure.

BRIEF DESCRIPTION OF THE DRAWINGS It is a figure which shows the half cross section of the tire width direction of the tire which concerns on 1st Embodiment of this invention. 1 is a partially enlarged sectional view of a tire according to a first embodiment of the invention; FIG. 4 is a graph showing the strain energy index when a load is applied to the tire of the first embodiment of the present invention; FIG. 10 is a diagram showing an RFID tag protected by a protective member in a tire according to a second embodiment of the invention; FIG. 4B is a view showing a bb cross section of FIG. 4A; FIG. 4B is a view showing a cc cross section of FIG. 4A; FIG. 4 is a partially enlarged cross-sectional view showing an example of an arrangement position of an RFID tag protected by a protective member; FIG. 10 is a cross-sectional view of the RFID tag before sandwiching the rubber sheet when the spring antenna is not filled with rubber; FIG. 10 is a view showing a cross section after the RFID tag is sandwiched between rubber sheets when the spring antenna is not filled with rubber; FIG. 10 is a view showing a cross section after the RFID tag is sandwiched between rubber sheets when the spring antenna is not filled with rubber; FIG. 10 is a diagram showing an RFID tag before rubber is filled in the spring antenna in the tire according to the third embodiment of the present invention; FIG. 10 is a diagram showing the RFID tag after the spring antenna is filled with rubber in the tire according to the third embodiment of the present invention; FIG. 10 is a diagram showing an RFID tag before being sandwiched between rubber sheets in a tire according to a third embodiment of the present invention; FIG. 10 is a diagram showing an RFID tag sandwiched between rubber sheets in a tire according to a third embodiment of the present invention;

<First embodiment>
A first embodiment of the present invention will be described below with reference to the drawings.
FIG. 1 is a diagram showing a half cross-section of a tire 1 according to this embodiment in the tire width direction. Since the basic structure of the tire is bilaterally symmetrical in the cross section in the tire width direction, the right half of the cross section is shown here. In the figure, symbol S1 is the tire equatorial plane. The tire equatorial plane S1 is a plane orthogonal to the tire rotation axis and located at the center in the tire width direction.
Here, the tire width direction is a direction parallel to the tire rotation axis, and is the horizontal direction of the paper surface in the cross-sectional view of FIG. 1 . In FIG. 1, it is illustrated as the tire width direction X.
The inner side in the tire width direction is the direction toward the tire equatorial plane S1, which is the left side of the paper surface in FIG. The outer side in the tire width direction is the direction away from the tire equatorial plane S1, and is the right side of the paper surface in FIG.
Moreover, the tire radial direction is a direction perpendicular to the tire rotation axis, which is the up-down direction on the paper surface of FIG. 1 . In FIG. 1, it is illustrated as the tire radial direction Y.
The outer side in the tire radial direction is the direction away from the tire rotation axis, and is the upper side of the paper surface in FIG. 1 . The inner side in the tire radial direction is the direction toward the tire rotation axis, and is the lower side of the paper surface in FIG. 1 .
The same applies to FIGS.

The tire 1 is, for example, a tire for trucks and buses, and includes a pair of beads 11 provided on both sides in the tire width direction, a tread 12 that forms a contact surface with the road surface, and a pair of beads 11 and the tread 12. and a pair of sidewalls 13 extending from the

The bead 11 includes an annular bead core 21 formed by winding a metal bead wire coated with rubber a plurality of times, and a tapered bead filler 22 extending outward in the tire radial direction of the bead core 21. - 特許庁The bead filler 22 is composed of a first bead filler 221 covering the outer periphery of the bead core 21 and a second bead filler 222 arranged outside the first bead filler 221 in the tire radial direction. The second bead filler 222 is made of rubber having a modulus higher than that of the inner liner 29 and sidewall rubber 30, which will be described later. The first bead filler 221 is made of rubber with a higher modulus than the second bead filler 222 . Note that the first bead filler 221 may not cover the outer periphery of the bead core 21 as long as at least a portion of the first bead filler 221 is arranged outside the bead core 21 in the tire radial direction. Also, the bead filler 22 may be formed from one type of rubber. That is, the first bead filler 221 and the second bead filler 222 do not have to be separated.
The bead core 21 is a member that serves to fix an inflated tire to a rim of a wheel (not shown). The bead filler 22 is a member provided to increase the rigidity of the bead periphery and ensure high maneuverability and stability.

A carcass ply 23 is embedded in the tire 1 to form a ply that serves as the frame of the tire. A carcass ply 23 extends from one bead core to the other bead core. That is, it is embedded in the tire 1 so as to pass through the pair of sidewalls 13 and the tread 12 between the pair of bead cores 21 .
As shown in FIG. 1 , the carcass ply 23 extends from one bead core to the other bead core and includes a ply body 24 extending between the tread 12 and the bead 11 and a ply folded around the bead core 21 . A folded portion 25 is provided. Here, the folded end 25A of the ply folded portion 25 is located inside the tire radial direction outer end 22A of the bead filler 22 in the tire radial direction.
The carcass ply 23 is composed of a plurality of ply cords extending in the tire width direction. Also, the plurality of ply cords are arranged side by side in the tire circumferential direction.
The ply cord is composed of a metal steel cord, an insulating organic fiber cord such as polyester or polyamide, or the like, and is covered with rubber.

In the tread 12, a plurality of layers of steel belts 26 are provided outside the carcass ply 23 in the tire radial direction. The steel belt 26 is composed of a plurality of rubber-coated steel cords. By providing the steel belt 26, the rigidity of the tire is ensured and the contact between the tread 12 and the road surface is improved. In this embodiment, four layers of steel belts 26 are provided, but the number of laminated steel belts 26 is not limited to this.

A tread rubber 28 is provided outside the steel belt 26 in the tire radial direction. A tread pattern (not shown) is provided on the outer surface of the tread rubber 28, and this outer surface serves as a contact surface that contacts the road surface.

A shoulder pad 38 is provided in a region between the carcass ply 23 and the steel belt 26 and the tread rubber 28 near the outer side of the tread 12 in the tire width direction. The shoulder pad 38 extends to the tire radial direction outer region of the sidewall 13, and a part of the shoulder pad 38 forms an interface with the sidewall rubber 30, which will be described later. That is, part of the shoulder pad 38 exists on the inner side of the sidewall rubber 30 in the tire width direction in the outer region of the sidewall 13 in the tire radial direction.
The shoulder pad 38 is made of a cushioning rubber member, and functions as a cushion between the carcass ply 23 and the steel belt 26 . Moreover, since the shoulder pads 38 are made of rubber having low heat generation properties, they can effectively suppress heat generation by extending to the sidewalls 13 .

In the bead 11 , sidewall 13 , and tread 12 , an inner liner 29 as a rubber layer forming the inner wall surface of the tire 1 is provided on the inner cavity side of the carcass ply 23 . The inner liner 29 is made of air permeable rubber and prevents the air inside the tire cavity from leaking to the outside.

A sidewall rubber 30 forming an outer wall surface of the tire 1 is provided outside the carcass ply 23 in the tire width direction in the sidewall 13 . The sidewall rubber 30 is the portion that flexes most when the tire acts as a cushion, and is generally made of flexible rubber having fatigue resistance.

A steel chaser 31 as a reinforcing ply is provided inside the carcass ply 23 provided around the bead core 21 of the bead 11 in the tire radial direction so as to cover the carcass ply 23 . The steel chafer 31 also extends outside the ply turn-up portion 25 of the carcass ply 23 in the tire width direction. direction inside.
The steel chainer 31 is a metal reinforcing layer composed of metal steel cords and covered with rubber.

A rim strip rubber 32 is provided inside the steel chaser 31 in the tire radial direction. This rim strip rubber 32 is arranged along the outer surface of the tire and is connected to the sidewall rubber 30 . The rim strip rubber 32 and the sidewall rubber 30 are rubber members forming the outer surface of the tire.

A first pad 35 is provided outside the end portion 31A of the steel chafer 31 in the tire radial direction and outside the folded portion 25 of the carcass ply 23 and the bead filler 22 in the tire width direction. The first pad 35 is provided so as to cover at least the tire width direction outer side of the folded end 25A of the ply folded portion 25 . The tire radial direction outer side of the first pad 35 is formed so as to taper toward the tire radial direction outer side.

Furthermore, a second pad 36 is provided so as to cover the outer side of the first pad 35 in the tire width direction. In more detail, the second pads 36 are provided.
In other words, the second pad 36 is provided between the first pad 35, etc., and the rim strip rubber 32 and sidewall rubber 30, which are members constituting the outer surface of the tire.

Here, the first pad 35 and the second pad 36 are made of rubber with a higher modulus than the modulus of the bead filler (second bead filler 222) with which these members are in contact.
More specifically, the second pad 36 is made of rubber with a modulus higher than that of the second bead filler 222, and the first pad 35 is made of rubber with a modulus even higher than that of the second pad 36. It is The first pad 35 and the second pad 36 have the function of relieving sharp strain caused by local stiffness change points at the folded end 25A of the carcass ply 23 and the end 31A of the steel chafer 31 .

A rubber sheet 37 is arranged on the inner side of the first pad 35 in the tire width direction near the folded end 25A of the ply folded portion 25 . The rubber sheet 37 is arranged so as to cover at least the folded end 25A of the ply folded portion 25 from the inside in the tire width direction.

In general, stress tends to concentrate on the folded end 25A of the ply folded portion 25 . However, by providing the first pad 35 and the second pad 36 described above and further disposing the rubber sheet 37, it is possible to effectively suppress the stress concentration.

An RFID tag 40 as an electronic component is embedded in the tire 1 of this embodiment.
The RFID tag 40 is a passive transponder having an RFID chip and an antenna for communicating with an external device, and performs wireless communication with a reader (not shown) as an external device. As the antenna, a coil-shaped spring antenna, a plate-shaped antenna, and various rod-shaped antennas are used. For example, it may be an antenna formed by printing a predetermined pattern on a flexible substrate. The antenna is set to have an optimized antenna length according to the frequency band to be used. A storage unit in the RFID chip stores identification information such as a manufacturing number and a part number.

FIG. 2 is an enlarged cross-sectional view showing the periphery of the embedded portion of the RFID tag 40 in the tire 1 of FIG.
As shown in FIGS. 1 and 2, RFID tag 40 is embedded between first pad 35 and second pad 36 .

Normally, when the boundary surface between two objects is a surface extending from the turn-up end 25A of the carcass ply 23, the surface is likely to be distorted. In consideration of communication quality, it is preferable to place the RFID tag 40 as close to the outer surface of the tire 1 as possible.

Therefore, in the present embodiment, an RFID is attached to the interface between the first pad 35 and the second pad 36 , which is closer to the outer surface of the tire 1 than the interface between the second bead filler 222 and the first pad 35 . Embed the tag 40 .

As a result, the RFID tag 40 can maintain its function without being affected by excessive strain. Additionally, the RFID tag 40 is sandwiched between the first pad 35 and the second pad 36 made of rubber having a modulus higher than that of the second bead filler 222, so that it is very strongly protected. Therefore, even if the tire is distorted, the RFID tag 40 is hardly damaged.

Based on the modulus of the second bead filler 222, the modulus of the first pad 35 is 1.5 times or more that of the second bead filler 222, preferably 1.5 to 2 times, more preferably A modulus of 1.5 to 1.7 times is preferable. The second pad has a modulus of 1.1 times or more, preferably 1.1 to 1.5 times, more preferably 1.3 to 1.5 times the modulus of the second bead filler 222. preferably. With such a modulus, it is possible to maintain a balance between the flexibility of the tire and the rigidity in the vicinity of the bead 11, and to protect the RFID tag 40 strongly.
The modulus is the 100% elongation modulus (M100) in an atmosphere at 23°C, measured according to JIS K6251:2010 "3.7 given elongation tensile stress (stress at a given elongation), S". Point.

Here, considering the communication quality, it is preferable that the RFID tag 40 is arranged at a position 5 mm or more, more preferably 10 mm or more, away from the folded end 25A of the ply folded portion 25 . In general, electronic devices such as the RFID tag 40 having a communication function become unstable due to the influence of metal parts. However, by arranging the RFID tag 40 at the position described above, the communication quality of the RFID tag 40 can be maintained even when the carcass ply 23 is made of metal steel cord.

In terms of strain energy, the RFID tag 40 is preferably arranged at a position 5 mm or more, more preferably 10 mm or more, away from the folded end 25A of the ply folded portion 25 . This point will be described using the graph in FIG.

FIG. 3 is a graph showing the strain energy index when a load is applied to the tire of this embodiment. The X-axis of this graph is the distance along the tire width direction outer surface of the first pad 35 from the portion 35B near the turn-up end 25A of the ply turn-up portion 25, and the Y-axis is the strain energy index.
Here, as shown in FIG. 2 , a portion 35B near the folded end 25A of the carcass ply 23 extends perpendicularly to the extension direction of the folded ply portion 25 from the ply folded end 25A of the carcass ply 23 in a cross-sectional view in the tire width direction. 2) and a line indicating the outer surface of the first pad 35 in the tire width direction.
As is clear from this graph, the strain energy index is significantly reduced when the folded end 25A of the ply folded portion 25 is separated from the neighboring portion 35B by 5 mm or more. Furthermore, the strain energy exponent stabilizes at a low value at a distance of 10 mm or more.
That is, substantially, if the position is 5 mm or more away from the folded end 25A of the ply folded portion 25, the strain energy index is greatly reduced. , is found to be stable at low values.

From the above, it is preferable that the RFID tag 40 is arranged at a position separated from the folded end 25A of the ply folded portion 25 by 5 mm or more, more preferably at a position separated by 10 mm or more.

Here, the RFID tag 40 is attached before the vulcanization process in the tire manufacturing process. In this embodiment, the RFID tag 40 is attached to the first pad 35 or the second pad 36 before the covering rubber is vulcanized. At this time, since the first pad 35 and the second pad 36 are in the state of uncured rubber before vulcanization, the RFID tag 40 is attached to the first pad 35 or the second pad 36 by using the adhesiveness thereof. You can paste it. Alternatively, if the adhesiveness is low, it may be attached using an adhesive or the like. After attaching the RFID tag 40 , the RFID tag 40 is sandwiched between the first pad 35 or the second pad 36 . After that, the green tire to which each component including the RFID tag 40 is assembled is vulcanized in a vulcanization process to manufacture a tire.

As described above, in the present embodiment, the RFID tag 40 can be attached to the first pad 35 or the second pad 36 in the raw rubber state at the time of tire manufacturing. Easy to assemble. In particular, since the first pad and the second pad have a certain degree of rigidity even in the raw rubber state, the operation of attaching the RFID tag 40 is easy.

Note that the RFID tag 40 embedded in the tire often has a longitudinal direction, including the antenna, as indicated by the RFID tag 40 in FIG. 4, which will be described later. Such an RFID tag 40 can be embedded in the tire 1 so that its longitudinal direction is tangential to the circumferential direction of the tire, that is, the direction perpendicular to the plane of the paper in the cross-sectional views of FIGS. preferable. By embedding in this manner, stress is less likely to be applied to the RFID tag 40 even when the tire is deformed.

In the process of attaching the RFID tag 40 described above, the longitudinal direction of the RFID tag 40 and the ridgeline of the outer end of the first pad 35 in the tire radial direction (the ring shape when viewed from the outside in the tire width direction). The RFID tag 40 is attached after aligning the direction so that the tangential direction of the outer peripheral portion of the pad 35 of 1) matches.
In this way, by using the ridgeline of the tire radial direction outer end of the first pad 35 (the outer peripheral portion of the first pad 35) as a reference, the RFID tag 40 can be easily identified as described above without adding a special mark. Can be easily placed in any direction. Further, according to this method, the RFID tag 40 can be easily arranged at the tire radial direction outer end of the first pad 35, which has a low strain energy and is far from metal parts.

The RFID tag 40 may be sandwiched between the first pad 35 and the second pad 36 while being covered with a protective member such as rubber. It may be sandwiched between the second pad 35 and the second pad 36 . Even in this case, since the RFID tag 40 is sandwiched between the first pad 35 and the second pad 36 and protected, the durability of the RFID tag 40 is improved.

In this embodiment, the RFID tag 40 is embedded in the tire as an electronic component, but the electronic component embedded in the tire is not limited to the RFID tag. For example, various electronic components such as sensors that perform wireless communication may be used. In addition, since electronic components handle electrical information such as transmission and reception of electrical signals, the presence of metal components in the vicinity may degrade performance. Also, electronic components may break due to excessive stress. Therefore, the effects of the present invention can be obtained even when various electronic components are embedded in a tire. For example, the electronic component may be a piezoelectric element or a strain sensor.

According to the tire 1 of this embodiment, the following effects are obtained.

(1) The tire 1 according to this embodiment is provided with the RFID tag 40 between the first pad 35 and the second pad 36 .
As a result, the RFID tag 40 can maintain its function without being affected by excessive strain.

(2) In the tire 1 according to the present embodiment, the RFID tag 40 is provided at a position separated from the folded end 25A of the carcass ply 23 by 5 mm or more.
Thereby, even when the carcass ply 23 is formed of metal steel cord, the communication quality of the RFID tag 40 can be maintained.

(3) In the tire 1 according to this embodiment, the moduli of the first pad 35 and the second pad 36 are higher than the modulus of the second bead filler 222 .
As a result, the RFID tag 40 is sandwiched between the first pad 35 and the second pad 36 made of rubber having a modulus higher than that of the second bead filler 222, so that the RFID tag 40 is very strongly protected. Therefore, even if the tire is distorted, the RFID tag 40 is hardly damaged.

<Second embodiment>
Next, a tire according to a second embodiment will be described with reference to FIGS. 4A to 4C. In addition, in the following description, the same reference numerals are given to the same configurations as in the first embodiment, and detailed description thereof will be omitted.

FIG. 4A shows an RFID tag 40 covered with a protective member 43 made of a rubber sheet. In FIG. 4A, the RFID tag 40 is hidden by being covered with a rubber sheet 431, which will be described later. 4B is a cross-sectional view along bb in FIG. 4A, and FIG. 4C is a cross-sectional view along cc in FIG. 4A.
In this embodiment, the RFID tag 40 is covered with a protective member 43, as shown in FIGS. 4A-4C.

The RFID tag 40 includes an RFID chip 41 and an antenna 42 for communicating with external equipment. As the antenna 42, a coil-shaped spring antenna, a plate-shaped antenna, and various rod-shaped antennas are used. For example, it may be an antenna formed by printing a predetermined pattern on a flexible substrate. Coiled spring antennas are most preferred for communication and flexibility considerations. The antenna is set to have an optimized antenna length according to the frequency band to be used.

The protective member 43 is composed of two rubber sheets 431 and 432 that sandwich and protect the RFID tag 40 .

The protective member 43 is made of, for example, rubber with a predetermined modulus.
Here, the modulus is the 100% elongation modulus (M100) in an atmosphere at 23°C, measured in accordance with JIS K6251:2010 "3.7 Stress at a given elongation, S". point to

As the rubber employed for the protective member 43, a rubber having a modulus higher than at least that of the sidewall rubber 30 is used. For example, a rubber having a higher modulus than the sidewall rubber 30 and a lower modulus than the second pad 36 is used.

For example, as the rubber used for the protective member 43, it is more preferable to use rubber having a modulus 1.1 to 1.8 times the modulus of the sidewall rubber 30 as a reference. At this time, as the rubber of the second pad 36, a rubber having a modulus 1.6 to 3 times that of the sidewall rubber, for example, a rubber having a modulus approximately twice that of the sidewall rubber may be used.
Note that if the protection of the RFID tag 40 is emphasized, rubber having a higher modulus than that of the second pad 36 may be used as the rubber used for the protective member 43 .

Incidentally, as shown in FIGS. 1 and 2, the RFID tag 40 is arranged in the area between the first pad 35 and the second pad 36 . Therefore, by setting the modulus of the protective member 43 to a value higher than the modulus of the second pad 36 and lower than the modulus of the first pad 35, when the tire is deformed, the RFID tag 40 embedding portion It is possible to prevent excessive stress from occurring in the rubber structure. That is, generation of stress can be suppressed.

Alternatively, the protection member 43 may be made of short fiber filler mixed rubber. As the short fiber filler, for example, insulating short fibers such as organic short fibers such as aramid short fibers and cellulose short fibers, ceramic short fibers such as alumina short fibers, and inorganic short fibers such as glass short fibers can be used. . By mixing such a short fiber filler with rubber, the strength of the rubber can be increased.
Also, a rubber sheet in a state after vulcanization may be used as the protective member 43 . Since the rubber sheet in the state after vulcanization does not undergo plastic deformation like crude rubber, it can appropriately protect the RFID tag 40 .

As the protection member 43, an organic fiber layer made of polyester fiber, polyamide fiber, or the like may be provided. It is also possible to embed organic fiber layers in the two rubber sheets 431 and 432 .

If the protective member 43 is composed of two rubber sheets in this way, the RFID tag 40 including the protective member 43 can be formed thin, which is suitable for embedding in the tire 1 . Further, when the RFID tag 40 is attached to the constituent members of the tire 1 before vulcanization, the RFID tag 40 covered with the rubber sheet can be attached very easily.
For example, the RFID tag 40 covered with a rubber sheet can be appropriately attached to the desired position of the members such as the first pad 35 and the second pad 36 before vulcanization using the adhesiveness of raw rubber. can. In addition, by using raw rubber before vulcanization as the rubber sheet, it is possible to more easily attach the rubber sheet using the adhesiveness of the rubber sheet itself.

However, the protective member 43 is not limited to being composed of two rubber sheets, and various other forms can be adopted. For example, if the rubber sheet forming the protective member covers at least a portion of the RFID tag 40, effects such as improved workability and stress relief in the manufacturing process can be obtained.
Further, for example, a configuration in which one rubber sheet is wrapped around the entire circumference of the RFID tag 40, or a configuration in which a protective member in the form of a highly viscous potting agent is attached to the entire circumference of the RFID tag 40. may Even with such a configuration, the RFID tag 40 can be appropriately protected.

The RFID tag 40 covered with the protective member 43 is arranged so that its longitudinal direction is tangential to the circumferential direction of the tire, that is, the direction perpendicular to the plane of the paper in the cross-sectional views of FIGS. is buried in Also, the rubber sheets 431 and 432 are embedded in the tire so as to be aligned in the tire width direction. That is, in the manufacturing process, one surface of either one of the rubber sheets 431 and 432 is attached to a constituent member of the tire before vulcanization, such as the first pad 35 .
By adopting such a mode, stress is less likely to be applied to the RFID tag 40 even when the tire is deformed. Also, in the manufacturing process, the work of attaching the RFID tag 40 covered with the protective member 43 becomes simple.

In the process of attaching the RFID tag 40, the ridgeline of the outer end in the tire radial direction of the first pad 35, in other words, the outer peripheral portion of the first pad 35, which has a ring shape when viewed from the outer side in the tire width direction. By using it as a reference, the RFID tag 40 covered with the protective member 43 can be easily arranged in the direction described above. That is, with the outer periphery of the first pad 35 as a reference, the longitudinal direction of the rubber sheets 431 and 432 covering the RFID tag 40 is aligned with the tangential direction of the outer periphery of the first pad 35 .
By this method, the RFID tag 40 covered with the protective member 43 can be easily arranged in the above direction without providing a special mark. In addition, according to this method, as shown in FIG. 5 , the strain energy is small, and the protection member 43 is placed in the vicinity of the tire radial outer end 35A of the first pad 35, which is a position far from the metal parts. A coated RFID tag 40 can be easily placed.

According to the tire according to the present embodiment, the following effects are obtained in addition to the above (1) to (3).

(4) In the present embodiment, the RFID tag 40 is covered with the rubber sheets 431 and 432, and the rubber sheets 431 and 432 covering the RFID tag 40 are the tire radial direction outer ends 35A of the first pads 35. are placed in
As a result, the RFID tag 40 can be placed at a position that is protected by the rubber sheets 431 and 432, has a small strain energy, and is far from metal parts.

(5) In the present embodiment, the RFID tag 40 is covered with the rubber sheets 431 and 432, and is attached to the tire radial direction outer end of the first pad 35 before the vulcanization process of vulcanizing the raw tire. Rubber sheets 431 and 432 are attached to the first pad 35 using the ridgeline as a reference.
As a result, the RFID tag 40 can be easily arranged near the tire radial outer end 35A of the first pad 35, which has a small strain energy and is far from metal parts.

(6) In this embodiment, the protective member 43 is made of rubber having a modulus higher than that of the second pad 36 and lower than that of the first pad 35. A coated RFID tag 40 is embedded in the tire.
Therefore, since the modulus of the rubber in the tire changes step by step, it is possible to prevent excessive stress from being generated in the rubber structure at the embedded portion of the RFID tag 40 when the tire is deformed.

<Third Embodiment>
Next, a tire according to a third embodiment will be described with reference to FIGS. 6-12. In addition, in the following description, the same reference numerals are given to the same configurations as in the second embodiment, and detailed description thereof will be omitted.
This embodiment is particularly suitable when the antenna of the RFID tag 40 is a coiled spring antenna.

The RFID tag 40 of this embodiment uses a coil-shaped spring antenna 421 with high communicability and flexibility as an antenna. The spring antenna 421 is set to have an optimized antenna length according to the frequency band to be used.

In this embodiment, rubber is placed inside the spring antenna 421 before the RFID tag 40 is sandwiched between the two rubber sheets 431 and 432 that constitute the protective member 43 . More preferably, the inside of the spring antenna is filled with rubber so as to leave as little air as possible. 6 to 12, the process and the reason for adopting the process will be described.

First, referring to FIGS. 6 to 8, as a reference example, the state around the RFID tag 40 when the spring antenna 421 is not filled with rubber will be described. FIG. 6 is a cross-sectional view of the spring antenna 421 and the rubber sheets 431 and 432 before the RFID tag 40 is sandwiched between the rubber sheets 431 and 432. As shown in FIG. FIG. 7 is a diagram showing cross sections of the spring antenna 421 and the rubber sheets 431 and 432 after the RFID tag 40 is sandwiched between the rubber sheets 431 and 432. As shown in FIG.

As shown in FIG. 7, in this reference example, since the spring antenna 421 is not filled with rubber in advance, a certain amount of air 45 remains in the spring antenna 421 after the spring antenna 421 is sandwiched between the rubber sheets 431 and 432 . may be lost. If air remains in this way, the integrity between the rubber sheets 431 and 432 and the spring antenna 421 becomes insufficient, and when the tire is deformed, the spring antenna 421 does not follow the movement of the rubber, and the spring antenna 421 does not follow the movement of the rubber. , the RFID tag 40 may be damaged.

Note that raw rubber before vulcanization is used here as the rubber sheets 431 and 432 . Therefore, by pressing the rubber sheets 431 and 432 from both sides, the rubber sheets 431 and 432 are fitted into the spring antenna to some extent as shown in FIG. However, it takes a great deal of time and effort to insert the rubber sheets 431 and 432 until the inside of the spring antenna is completely buried.

Even if the spring antenna is filled with the rubber sheet over time, as shown in FIG. The distance L to the surface becomes very short. Moreover, it is difficult to stabilize the distance L, and thin portions may occur locally. Therefore, the protection of the RFID tag 40 by the rubber sheets 431 and 432 becomes insufficient, and the rubber sheets 431 and 432 may be damaged during vulcanization.

Therefore, in this embodiment, rubber is placed inside the spring antenna 421 before the RFID tag 40 is sandwiched between the rubber sheets 431 and 432, as shown in FIGS. More preferably, the inside of the spring antenna is filled with rubber so as to leave as little air as possible. 9 to 12 show cross sections of the spring antenna 421 and its surroundings.

9 is a diagram showing a state before the spring antenna 421 is filled with the rubber 46, and FIG. 10 is a diagram showing a state after the spring antenna 421 is filled with the rubber 46. FIG.
The rubber 46 is embedded so as to have substantially the same outer diameter as the outer peripheral surface of the spring antenna 421 . If the rubber 46 protrudes from the outer peripheral surface of the spring antenna 421, it is preferable to wipe off that portion. That is, it is preferable that the outer peripheral surface of the rubber 46 and the outer peripheral surface of the spring antenna 421 are formed to be substantially flush with each other.
The spring antenna 421 may be filled with the rubber 46 and the outer circumference of the spring antenna 421 may be thinly wrapped with the rubber 46 . On the other hand, if the spring antenna 421 is thickly wrapped with the rubber 46, the flexibility of the spring antenna 421 is impaired, and the widthwise dimension formed by the rubber sheets 431 and 432 after the RFID tag 40 is sandwiched becomes large. I don't like it because it becomes
It should be noted that the rubber 46 may be embedded so as to have substantially the same outer diameter as the inner peripheral surface of the spring antenna 421 . It is desirable that the outer peripheral portion of the rubber 46 be positioned within the range from the inner peripheral surface to the outer peripheral surface of the spring antenna 421 .

Here, in order to secure the flexibility of the spring antenna 421, a flexible rubber is used as the rubber 46. FIG. However, considering workability and the like, it is preferable to use rubber having a modulus higher than that of the rubber sheets 431 and 432 as the rubber 46 .
As the rubber 46 arranged inside the spring antenna 421, unvulcanized rubber is preferably used. By using unvulcanized rubber as the rubber 46 and the rubber sheets 431 and 432 and simultaneously vulcanizing them, the integrity of the rubber 46, the rubber sheets 431 and 432, and the spring antenna 421 is enhanced. Moreover, it is more preferable that the rubber 46 and the rubber sheets 431 and 432 are made of the same kind of rubber.
It should be noted that rubber having a modulus lower than that of the rubber sheets 431 and 432 may be used as the rubber 46 by emphasizing the flexibility of the spring antenna 421 . Also, rubbers with substantially the same modulus or rubbers of the same material may be used.
As the rubber 46 arranged in the spring antenna 421, vulcanized rubber may be used. It is also possible to use a rubber-based adhesive, a rubber-based filler, and the like. Various rubber-based materials can be used in consideration of minimizing air remaining in the spring antenna 421 while ensuring flexibility.
Various methods can be employed for the operation of arranging the rubber 46. For example, it is also possible to inject the rubber into the spring antenna 421 using a syringe. In this case, a syringe may be used to fill the appropriate set amount of rubber 46 . Also, after filling the rubber 46 with a large amount, the portion protruding from the outer circumference of the spring antenna 421 may be wiped off.

FIG. 11 shows a state before the RFID tag 40 with the spring antenna 421 filled with the rubber 46 is sandwiched between the rubber sheets 431 and 432, and FIG. 12 shows a state after the rubber sheets 431 and 432 sandwich it. It is a diagram.

As shown in FIG. 12, according to this embodiment, since the spring antenna 421 is filled with the rubber 46 in advance, there is no air pool between the rubber sheets 431 and 432 . Therefore, the step of sandwiching the RFID tag 40 between the rubber sheets 431 and 432 is also simplified because there is no need to worry about air pockets.
In addition, since the rubber 46 is arranged inside the spring antenna 421, the integration of the spring antenna 421, the rubber 46, and the rubber sheets 431 and 432 is enhanced. follow. Therefore, the durability of the RFID tag 40 having the spring antenna 421 is also improved.

Further, according to this embodiment, the distance L between the outer peripheral portion of the spring antenna 421 and the outer surfaces of the rubber sheets 431 and 432 is stabilized. That is, a distance close to the thickness of the rubber sheets 431 and 432 is generally secured as the distance L. Therefore, the RFID tag 40 is sufficiently protected by the rubber sheets 431 and 432 .
In this embodiment, the RFID tag 40 sandwiched between the rubber sheets 431 and 432 is placed inside the raw tire, and then the raw tire is vulcanized.

According to the tire according to the present embodiment, the following effects are obtained in addition to the above (1) to (6).

(7) In the present embodiment, a step of arranging the rubber 46 in the spring antenna 421 of the RFID tag 40 as an electronic component having a communication function; A step of sandwiching between the rubber sheets 431 and 432 and an arrangement step of arranging the RFID tag 40 sandwiched between the rubber sheets 431 and 432 on the tire 1 are provided.
As a result, the air 45 does not remain inside the spring antenna 421 . In addition, since there is no need to worry about air pockets, the operation of sandwiching the RFID tag 40 between the rubber sheets 431 and 432 is simplified.
Further, since the distance L between the outer circumference of the spring antenna 421 and the outer surfaces of the rubber sheets 431 and 432 is stable, the RFID tag 40 is sufficiently protected by the rubber sheets 431 and 432 .

The tire of the present invention can be used as various tires for passenger cars, light trucks, trucks, buses and the like, and is particularly suitable as tires for trucks, buses and the like.
Note that the present invention is not limited to the above-described embodiments, and modifications and improvements that can achieve the object of the present invention are also included in the scope of the present invention.

DESCRIPTION OF SYMBOLS 1... Tire 11... Bead 12... Tread 13... Side wall 21... Bead core 22... Bead filler 22A... Outer end of bead filler in tire radial direction 23... Carcass ply 24... Ply body 25... Ply folded part 26... Steel belt 27... Cap Ply 28... Tread rubber 29... Inner liner 30... Side wall rubber 31... Steel chaser 31A... End of steel chaser 32... Rim strip rubber 35... First pad 36... Second pad 37... Rubber sheet 40... RFID tag 41... RFID chip 42... Antenna 421... Spring antenna 43... Protective member 431, 432... Rubber sheet 46... Rubber

Claims (6)

A tire comprising a bead core, a bead filler extending outward in the tire radial direction of the bead core, and a carcass ply extending from the bead core to the other bead core and folded back around the bead core,
a reinforcing ply disposed to cover the carcass ply around the bead core;
a first pad covering the tire width direction outside of the folded end of the folded carcass ply on the tire radial direction outside of the end of the reinforcing ply;
a second pad covering the outer side in the tire width direction of the first pad;
a rubber member forming the outer surface of the tire covering the outer side of the second pad in the tire width direction;
with
The rubber member forming the outer surface of the tire covers the entire outer side of the second pad in the tire width direction,
A tire, wherein an electronic component is provided between the first pad and the second pad. The tire according to claim 1, wherein the electronic component is provided at a position separated by 5 mm or more from the turned-back end of the carcass ply. The tire according to claim 1 or 2, wherein the electronic component is covered with a rubber sheet, and the rubber sheet covering the electronic component is arranged at the tire radial direction outer end of the first pad. A tire according to any one of claims 1 to 3, wherein the modulus of said first pad and said second pad is higher than the modulus of said bead filler. A manufacturing method for manufacturing the tire according to claim 1,
The electronic component is covered with a rubber sheet,
Before the vulcanization step of vulcanizing the raw tire, the longitudinal direction of the rubber sheet coated with the electronic component is aligned with the outer periphery of the first pad as a reference, and the longitudinal direction of the rubber sheet is tangential to the outer periphery of the first pad. A method for manufacturing a tire, comprising an attaching step of attaching the rubber sheet to the first pad in accordance with the direction. Furthermore, a covering step of covering the electronic component attached in the attaching step with the rubber sheet,
The covering step includes placing rubber in the spring antenna of the electronic component;
6. The tire manufacturing method according to claim 5, further comprising the step of sandwiching the electronic component having the spring antenna on which the rubber is arranged between the rubber sheets.

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